analysis of building
TRANSCRIPT
INTRODUCTION
1.1 THE DESIGN PROCESS:
The entire process of structural planning and design requires not only
imagination and conceptual thinking but also sound knowledge of practical
aspects, such as recent design codes and bye-laws, backed up by ample
experience, institution and judgment.
It is emphasized that any structure to be constructed must satisfy the need
efficiency for which it is intended and shall be durable for its desired life span.
Thus, the design of any structure is categorizes into following two main types:-
1. Functional design
2. Structural design
1.1.1 FUNCTIONAL DESIGN:
The structure to be constructed should primarily serve the basic purpose for
which it is to be used and must have a pleasing look.
The building should provide happy environment inside as well as outside.
Therefore, the functional planning of a building must take into account the
proper arrangements of room/halls to satisfy the need of the client, good
ventilation, lighting, acoustics, unobstructed view in the case of community
halls, cinema theatres, etc.
1.1.2 STRUCTURAL DESIGN:
Once the form of the structure is selected, the structural design process starts.
Structural design is an art and science of understanding the behavior of
structural members subjected to loads and designing them with economy and
elegance to give a safe, serviceable and durable structure.
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1.2 STAGES IN STRUCTURAL DESIGN:
The process of structural design involves the following stages.
1) Structural planning.
2) Action of forces and computation of loads.
3) Methods of analysis.
4) Member design.
5) Detailing, Drawing and Preparation of schedules.
1.2.1 STRUCTURAL PLANNING:
After getting an architectural plan of the buildings, the structural planning of the
building frame is done. This involves determination of the following.
a. Position and orientation of columns.
b. Positioning of beams.
c. Spanning of slabs.
d. Layouts of stairs.
e. Selecting proper type of footing.
1.2.1.1 Positioning and orientation of columns:
Following are some of the building principles, which help in deciding the
columns positions.
1. Columns should preferably be located at (or) near the corners of a building,
and at the intersection of beams/walls.
2. Select the position of columns so as to reduce bending moments in beams.
3. Avoid larger spans of beams.
4. Avoid larger centre-to-centre distance between columns.
5. Columns on property line.
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Orientation of columns:
1. Avoid projection of columns:
The projection of columns outside the wall in the room should be avoided as
they not only give bad appearance but also obstruct the use of floor space,
creating problems in placing furniture flush with the wall. The width of the
column is required to be kept not less than 200mm to prevent the column from
being slender. The spacing of the column should be considerably reduced so
that the load on column on each floor is less and the necessity of large sections
for columns does not arise.
2. Orient the column so that the depth of the column is contained in the
major plane of bending or is perpendicular to the major axis of bending.
This is provided to increase moment of inertia and hence greater moment
resisting capacity. It will also reduce Leff/d ratio resulting in increase in the load
carrying capacity of the column.
1.2.1.2 POSITIONING OF BEAMS:
1. Beams shall normally be provided under the walls or below a heavy
concentrated load to avoid these loads directly coming on slabs.
2. Avoid larger spacing of beams from deflection and cracking criteria. (The
deflection varies directly with the cube of the span and inversely with the cube
of the depth i.e. L3/D3. Consequently, increase in span L which results in greater
deflection for larger span).
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1.2.1.3 SPANNING OF SLABS:
This is decided by supporting arrangements. When the supports are only on
opposite edges or only in one direction, then the slab acts as a one way
supported slab. When the rectangular slab is supported along its four edges it
acts as a one way slab when Ly/Lx < 2.
The two way action of slab not only depends on the aspect ratio but also on the
ratio of reinforcement on the directions. In one way slab, main steel is provided
along with short span only and the load is transferred to two opposite supports.
The steel along the long span just acts as the distribution steel and is not
designed for transferring the load but to distribute the load and to resist
shrinkage and temperature stresses.
A slab is made to act as a one way slab spanning across the short span by
providing main steel along the short span and only distribution steel along the
long span. The provision of more steel in one direction increases the stiffness of
the slab in that direction.
According to elastic theory, the distribution of load being proportional to
stiffness in two orthogonal directions, major load is transferred along the stiffer
short span and the slab behaves as one way. Since, the slab is also supported
over the short edge there is a tendency of the load on the slab by the side of
support to get transferred to the nearer support causing tension at top across
this short supporting edge. Since, there does not exist any steel at top across
this short edge in a one way slab interconnecting the slab and the side beam,
cracks develop at the top along that edge. The cracks may run through the
depth of the slab due to differential deflection between the slab and the
supporting short edge beam/wall. Therefore, care should be taken to provide
minimum steel at top across the short edge support to avoid this cracking.
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A two way slab is generally economical compare to one way slab because
steel along both the spans acts as main steel and transfers the load to all
its four supports. The two way action is advantageous essentially for large
spans (>3m) and for live loads (>3kN/m2). For short spans and light loads, steel
required for two way slabs does not differ appreciably as compared to steel for
two way slab because of the requirements of minimum steel.
FOOTING:
The type of footing depends upon the load carried by the column and the
bearing capacity of the supporting soil. The soil under the foundation is more
susceptible to large variations. Even under one small building the soil may vary
from soft clay to a hard murum. The nature and properties of soil may change
with season and weather, like swelling in wet weather. Increase in moisture
content results in substantial loss of bearing capacity in case of certain soils
which may lead to differential settlements. It is necessary to conduct the survey
in the areas for soil properties. For framed structure, isolated column footings
are normally preferred except in case of exists for great depths, pile foundations
can be an appropriate choice. If columns are very closely spaced and bearing
capacity of the soil is low, raft foundation can be an alternative solution. For a
column on the boundary line, a combined footing or a raft footing may be
provided.
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1.3 ASSUMPTIONS
The following are the assumptions made in the earthquake resistant design of structures:• Earthquake causes impulsive ground motions, which are complex and
irregular in character, changing in period and amplitude each lasting for small duration. Therefore resonance of the type as visualized under steady-state sinusoidal excitations, will not occur as it would need time to build up such amplitudes.
• Earthquake is not likely to occur simultaneously with wind or max. Flood or max. sea waves.
• The value of elastic modulus of materials, wherever required, maybe taken as per static analysis.
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2.1 DESIGN PHILOSOPHIES
Working stress method (WSM)
Ultimate load method (ULM)
Limit state method (LSM)
2.1.1. Working stress method (WSM):-
This was the traditional method of design not only for reinforced concrete, but
also for structural steel and timber design. The method basically assumes that
the structural material behaves as a linear elastic manner, and that adequate
safety can be ensured by suitably restricting the stresses in the material
induced by the expected “working loads” on the structure. As the specified
permissible stresses are kept well below the material strength, the assumption
of linear elastic behavior is considered justifiable. The ratio of the strength of the
material to the permissible stress is often referred to as the factor of safety.
However, the main assumption linear elastic behavior and the tacit assumption
that the stresses under working loads can be kept within the ‘permissible
stresses’ are not found to be realistic. Many factors are responsible for this such
as a long term effort of creep and shrinkage, the effects of stress
concentrations, and other secondary effects. All such effects resulting
significant local increases in a redistribution of the calculated stresses. The
design usually results in relatively large sections of structural members, thereby
resulting in better serviceability performance under the usual working loads.
2.1.2. Ultimate load method (ULM):-
With the growing realization of the short comings of WSM in reinforced concrete
design, and with increased understanding of the behavior of reinforced concrete
at ultimate loads, the ultimate load of design is evolved and became an
alternative to WSM. This method is sometimes also referred to as the load
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factor methods are the ultimate strength. In this method, the stress condition at
the site of impending collapse of the structure is analyzed, and the non linear
stress-strain curves of concrete and steel are made use of.
The concept of ‘modular ratio’ and its associated problems are avoided entirely
in this method. The safety measure design is introduced by an appropriate
choice of the load factor, defined as the ratio of the ultimate load to the working
load. The ultimate load method males it possible for different types of loads to
be assigned different load factors under combined loading conditions, thereby
overcoming the related shortcoming of WSM.
This method generally results in more slender sections, and often economical
designs of beams and columns, particularly when high strength reinforcing steel
and concrete are used. However, the satisfactory ‘strength’ performance at
ultimate loads does not guarantee satisfactory ‘serviceability’ performance at
the normal service loads.
The designs sometimes result in excessive deflections and crack-widths under
service loads, owing to the slender sections resulting from the use of high
strength reinforcing steel and concrete. The distribution of stress resultants at
ultimate load is taken as the distribution at the service loads, magnified by the
load factor(s); in other words, analysis is still based on linear elastic theory.
2.1.3. Limit state method (LSM):-
The philosophy of the limit state method of design represents a definite
advancement over the traditional design philosophies. Unlike WSM
which based calculations on service load conditions alone, and unlike ULM,
which based calculations on ultimate load conditions alone, LSM aims for a
comprehensive and rational solution to the design problem, by considering
safety at ultimate loads and serviceability at working loads.
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The LSM philosophy uses a multiple safety factor format which attempts to
provide adequate safety at ultimate loads as well as adequate serviceability at
service loads, by considering all possible ‘Limit State’.
Limits States:-
A limit state is a state of impending failure, beyond which a structure ceases to
perform its intended function satisfactorily, in terms of either safety of
serviceability i.e. it either collapses or becomes unserviceable.There are two
types of limit states:
Ultimate limit states (limit states of collapse):- which deal with strength,
overturning, sliding, buckling, fatigue fracture etc.
Serviceability limit states: - which deals with discomfort to occupancy and/ or
malfunction, caused by excessive deflection, crack width, vibration leakage etc.,
and also loss of durability etc.
2.2 PROPERTIES OF CONCRETE:
Grades of concrete:
Concrete is known by its grade which is designated as M15, M20 etc. in which
letter M refers to concrete mix and number 15, 20 denotes the specified
compressive strength (fck) of 150mm cube at 28 days, expressed in N/mm2.
Thus, concrete is known by its compressive strength. M20 and M25 are the
most common grades of concrete, and higher grades of concrete should be
used for severe, very severe and extreme environments.
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Compressive strength
Like load, the strength of the concrete is also a quality which varies
considerably for the same concrete mix. Therefore, a single representative
value, known as characteristic strength is used.
Characteristic strength
It is defined as the value of the strength below which not more then 5% of the
test results are expected to fall (i.e. there is 95% probability of achieving this
value only 5% of not achieving the same)
Characteristic strength of concrete in flexural member
The characteristic strength of concrete in flexural member is taken as 0.67
times the strength of concrete cube.
Design strength (fd) and partial safety factor for material strength
The strength to be taken for the purpose of design is known is known as design
strength and is given by
Design strength (fd) = characteristic strength/ partial safety factor for material
strength
The value of partial safety factor depends upon the type of material and upon
the type of limit state. According to IS code, partial safety factor is taken as 1.5
for concrete and 1.15 for steel.
Design strength of concrete in member = 0.45fck
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Tensile strength
The estimate of flexural tensile strength or the modulus of rupture or the
cracking strength of concrete from cube compressive strength is obtained by
the relations
fcr = 0.7 fck N/mm2
The tensile strength of concrete in direct tension is obtained experimentally by
split cylinder. It varies between 1/8 to 1/12 of cube compressive strength.
Creep
Creep is defined as the plastic deformation under sustain load. Creep strain
depends primarily on the duration of sustained loading. According to the code,
the value of the ultimate creep coefficient is taken as 1.6 at 28 days of loading.
Shrinkage
The property of diminishing in volume during the process of drying and
hardening is termed Shrinkage. It depends mainly on the duration of exposure.
If this strain is prevented, it produces tensile stress in the concrete and hence
concrete develops cracks.
Modular ratio
Short term modular ratio is the modulus of elasticity of steel to the modulus of
elasticity of concrete.
Short term modular ratio = Es / Ec
Es = modulus of elasticity of steel (2x10 5 N/mm2)
Ec = modulus of elasticity of concrete (5000√fck N/mm2)
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As the modulus of elasticity of concrete changes with time, age at loading etc
the modular ratio also changes accordingly. Taking into account the effects of
creep and shrinkage partially IS code gives the following expression for the long
term modular ratio.
Long term modular ratio (m) = 280/ (3fcbc)
Where, fcbc = permissible compressive stress due to bending in concrete in
N/mm2.
Poisson’s ratio:
Poisson’s ratio varies between 0.1 for high strength concrete and 0.2 for weak
mixes. It is normally taken as 0.15 for strength design and 0.2 for serviceability
criteria.
Durability:
Durability of concrete is its ability to resist its disintegration and decay. One of
the chief characteristics influencing durability of concrete is its permeability to
increase of water and other potentially deleterious materials.
The desired low permeability in concrete is achieved by having adequate
cement, sufficient low water/cement ratio, by ensuring full compaction of
concrete and by adequate curing.
Unit weight of concrete:
The unit weight of concrete depends on percentage of reinforcement, type of
aggregate, amount of voids and varies from 23 to 26KN/m2. The unit weight of
plain and reinforced concrete as specified by IS:456 are 24 and 25KN/m3
respectively.
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2.3 TYPES OF LOADS:
The loads are broadly classified as vertical loads, horizontal loads and
longitudinal loads. The vertical loads consist of dead load, live load and impact
load. The horizontal loads comprises of wind load and earthquake load. The
longitudinal loads i.e. tractive and braking forces are considered in special case
of design of bridges, gantry girders etc.
2.3.1 Dead load:
Dead loads are permanent or stationary loads which are transferred to structure
throughout the life span. Dead load is primarily due to self weight of structural
members, permanent partition walls, fixed permanent equipments and weight of
different materials.
2.3.2 Imposed loads or live loads:
Live loads are either movable or moving loads with out any acceleration or
impact. There are assumed to be produced by the intended use or occupancy
of the building including weights of movable partitions or furniture etc. The floor
slabs have to be designed to carry either uniformly distributed loads or
concentrated loads whichever produce greater stresses in the part under
consideration. Since it is unlikely that any one particular time all floors will not
be simultaneously carrying maximum loading, the code permits some reduction
in imposed loads in designing columns, load bearing walls, piers supports and
foundations.
2.3.3 Impact loads:
Impact load is caused by vibration or impact or acceleration. Thus, impact load
is equal to imposed load incremented by some percentage called impact factor
or impact allowance depending upon the intensity of impact.
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2.3.4 Wind loads:
Wind load is primarily horizontal load caused by the movement of air relative to
earth. Wind load is required to be considered in design especially when the
heath of the building exceeds two times the dimensions transverse to the
exposed wind surface.
For low rise building say up to four to five storeys, the wind load is not critical
because the moment of resistance provided by the continuity of floor system to
column connection and walls provided between columns are sufficient to
accommodate the effect of these forces. Further in limit state method the factor
for design load is reduced to 1.2 (DL+LL+WL) when wind is considered as
against the factor of 1.5(DL+LL) when wind is not considered. IS 1893 (part 3)
code book is to be used for design purpose.
2.3.5 Earthquake load:
Earthquake loads are horizontal loads caused by the earthquake and shall be
computed in accordance with S 1893. For monolithic reinforced concrete
structures located in the seismic zone 2, and 3 without more than 5 storey high
and importance factor less than 1, the seismic forces are not critical.
2.4 METHODS OF ANALYSIS OF FRAMES:
Elastic analysis deals with the study of strength and behavior of the members
and structure at working loads. Frames can be analyzed by various methods.
However, the method of analysis adopted depends upon the types of frame, its
configuration (portal bay or multibay) multistoried frame and Degree of
indeterminacy.
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It is based on the following assumptions:
1. Relation between force and displacement is linear. (i.e. Hook’s law is
applicable).
2. Displacements are extremely small compared to the geometry of the
structure in the sense that they do not affect the analysis.
The methods used for analysis of frame are:
1. Flexibility coefficient method.
2. Slope displacement method.
3. Iterative methods like
a. Moment distribution method(By Hardy Cross in 1930’s)
b. Kani’s method (by Gasper Kani in 1940’s)
4. Approximate methods like
a. Substitute frame method
b. Portal method
c. Cantilever method
2.4.1 FLEXIBILITY COEFFICIENT METHOD:
This method is called as force method or compatibility method. In this
Redundant forces are chosen as unknowns. Additional equations are obtained
by considering the geometrical conditions imposed on the formation of
structures. This method is used for analyzing frames of lower D.O.R.
Limitations:
1. This method involves long computations even for simple problems with
small D.O.R.
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2. This method becomes intractable for large D.O.R. (>3), when computed
manually especially because of simultaneous equations involved.
This method is not ideal for computerizing, since a structure can be reduced to
a statically determinate form in more than one way.
2.4.2 SLOPE DISPLACEMENT METHOD:
It is displacement or equilibrium or stiffness method. It consists of series of
simultaneous equations, each expressing the relation between the moments
acting at the ends of the members is written in terns of slope & deflection. The
solution of slope deflection equations along with equilibrium equations gives the
values of unknown rotations of the joints. Knowing these rotations, the end
moments are calculated using slope deflection equations.
Limitations:
1. This method is advantageous only for the structures with small Kinematic
indeterminacy.
2. The solution of simultaneous equation makes the method tedious for annual
computations.
The formulation of equilibrium conditions tends to be a major constraint in
adopting this method.
Hence flexibility coefficients & slope displacement methods have limited
applications in the analysis of frames. While other methods like iterative
or approximate methods are used for analyzing frames containing larger
indeterminacy.
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2.4.3 APPROXIMATE METHODS:
Approximate analysis of hyper static structures provides a simple means of
obtaining quick solutions for preliminary designs. It is a very useful process that
helps to develop a suitable configuration for final (rigorous) analysis of a
structure, compare alternative designs & provide a quick check on the
adequacy of structural designs. These methods make use of simplifying
assumptions regarding structural behavior so as to obtain a rapid solution to
complex structures. However, these techniques should be applied with caution
& not relied upon for final designs, especially complex structures.
The usual process comprises reducing the given indeterminate configuration to
a structural system by introducing adequate number of hinges. It is possible to
check the deflected profile of a structure for the given loading & there by locate
the points of inflection.
Since each point of inflection corresponds to the location of zero moment in the
structure, the inflection points can be visualized as hinges for purpose of
analysis. The solution of the structure is rendered simple once the inflection
points are located. In multistoried frames, two loading cases arise namely
horizontal & vertical loading.
The analysis is carried out separately for these two cases:
VERTICAL LOADS:
The stress in the structure subjected to vertical loads depends upon the relative
stiffness of the beam & columns. Approximate methods either assumes
adequate number of hinges to render the structure determinate or adopt
simplified moment distribution methods.
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HORIZONTAL LOADS:
The behavior of a structure subjected to horizontal forces depends on its height
to width ratio. The deformation in low-rise structures, where the height is
smaller than its width, is characterized predominantly by shear deformations. In
high rise building, where height is several times greater than its lateral
dimensions, is dominated by bending action. There are two methods to analyze
the structures subjected to horizontal loading.
2.4.3.1 PORTAL METHOD:
Since shear deformations are dominant in low rise structures, the method
makes simplifying assumptions regarding horizontal shear in columns. Each
bay of a structure is treated as a portal frame, & horizontal force is distributed
equally among them.
The assumptions of the method can be listed as follows:
1. The points of inflection are located at the mid-height of each column above
the first floor. If the base of the column is fixed, the point of inflection is
assumed at mid height of the ground floor columns as well; otherwise it is
assumed at the hinged column base.
2. Points of inflection occur at mid span of beams.
3. Total horizontal shear at any floor is distributed among the columns of that
floor such that the exterior columns carry half the force carried by the inner
columns.
2.4.3.2 CANTILEVER METHOD:
This method is applicable to high rise structures. This is based on the
simplifying assumptions regarding the Axial Force in columns.
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1. The basic assumption of the method can be stated as “the axial force in the
column at any floor is linearly proportional to its distance from the centroid of all
the columns at that level.
Assumptions 1&2 of the portal are also applicable to the cantilever method.
2.4.3.3 POINTS OF INFLECTION METHOD:
The frame is reduced to a statically determinate form by introducing adequate
number of points of inflection. The loading on the frames usually comprises
uniformly distributed dead loads & live loads.
The following are assumptions made:-
1. The beams of each floor act as continuous beams, with the points of
inflection at a distance of one-tenth of the span from the joints.
2. The unbalanced beam moment at each joint is distributed equally among the
columns at the joint.
3. Axial forces & deformations in beams are negligible.
2.4.3.4 SUBSTITUTE FRAME METHOD:
The method assumes that the moments in the beams of any floor are
influenced by loading on that floor alone. The influence of loading on the lower
or upper floors is ignored altogether. The process involves the division of multi-
storied structure into smaller frames. These sub frames are known as
equivalent frames or substitute frames.
The sub frames are usually analyzed by the moment distribution method, using
only one cycle of distribution. The substitute frames are formed by the beams at
the floor level under consideration, together with the columns above & below
with their far ends fixed. The distributed B.M are not carried over far ends of the
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columns in this process; the moments in the columns are computed at each
floor level independently & retained at that floor irrespective of further analysis.
2.4.4 ITERATIVE METHOD:
Iterative procedures form a powerful class of methods for analysis of
indeterminate structures. These methods after elegant & simple procedure of
analysis, that are adequate for usual structures.
These methods are based on the distribution of joint moments among members
connected to a joint. The accuracy of the solution depends upon the number of
iterations performed; usually three or five iterations are adequate for most of the
structures.
The moment distribution methods were developed by Hardy Cross in 1930’s &
by Gasper Kani in 1940’s. These methods involve distributing the known fixed
moments of the structural members to the adjacent members at the joints, in
order to satisfy the conditions of the continuity of slopes & displacements.
Though these methods are iterative in nature, they converge in a few iterations
to give correct solution.
2.4.4.1 MOMENT DISTRIBUTION METHOD:
This method was first introduced by Prof. Hardy Cross is widely used for the
analysis of intermediate structures. In this method first the structural system is
reduced to its kinematically determinate form, this is accomplished by assuming
all the joints to be fully restrained. The fixed end moments are calculated for this
condition of structure. The joints are allowed to deflect rotate one after the other
by releasing them successively. The unbalanced moment at the joint shared by
the members connected at the joint when it is released.
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LIMITATIONS:
1. This method is eminently suited to analyze continuous beams including non-
prismatic members but it presents some difficulties when applied to rigid
frames, especially when frames are subjected to side sway.
2. Unsymmetrical frames have to be analyzed more than once to obtain FM
(fixed moments) in the structures.
3. This method can not be applied to structures with intermediate hinges.
2.4.4.2 KANI’S METHOD:
This method was introduced by Gasper Kani in 1940’s. It involves distributing
the unknown fixed end moments of structural members to adjacent joints, in
order to satisfy the conditions of continuity of slopes and displacements.
ADVANTAGES:
1. Hardy Cross method distributed only the unbalanced moments at joints,
whereas Kani’s method distributes the total joint moment at any stage of
iteration.
2. The more significant feature of Kani’s method is that the process is self
corrective. Any error at any stage of iteration is corrected in subsequent steps.
Framed structures are rarely symmetric and subjected to side sway, hence
Kani’s method is best and much simpler than pther methods like moment
distribution method and slope displacement method.
PROCEDURE:
1. Rotation stiffness at each end of all members of a structure is determined
depending upon the end conditions.
a. Both ends fixed
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Kij= Kji= EI/L
b. Near end fixed, far end simply supported
Kij= ¾ EI/L; Kji= 0
2. Rotational factors are computed for all the members at each joint it is given
by
Uij= -0.5 (Kij/ ΣKji)
{THE SUM OF ROTATIONAL FACTORS AT A JOINT IS -0.5}
(Fixed end moments including transitional moments, moment releases and
carry over moments are computed for members and entered. The sum of the
FEM at a joint is entered in the central square drawn at the joint).
3. Iterations can be commenced at any joint however the iterations commence
from the left end of the structure generally given by the equation
Mיij = Uij [(Mfi + Mּיּיi) + Σ Mיji)]
4. Initially the rotational components Σ Mji (sum of the rotational moments at
the far ends of the joint) can be assumed to be zero. Further iterations take into
account the rotational moments of the previous joints.
5. Rotational moments are computed at each joint successively till all the joints
are processed. This process completes one cycle of iteration.
6. Steps 4 and 5 are repeated till the difference in the values of rotation
moments from successive cycles is neglected.
7. Final moments in the members at each joint are computed from the
rotational members of the final iterations step.
Mij = (Mfij + Mּיּיij) + 2 Mיij + Mּיjii
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The lateral translation of joints (side sway) is taken into consideration by
including column shear in the iterative procedure.
8. Displacement factors are calculated for each storey given by
Uij = -1.5 (Kij/ΣKij)
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3.1 EARTHQUAKE:
An earthquake is vibration of earth surface by waves emerging from the source
of disturbance in the earth by virtue of release of energy in the earth’s crust. It is
essentially a sudden and transient motion or series of motions of the earth
surface originating in a limited under ground motion due to disturbance of the
elastic equilibrium of the earth mass and spreading from there in all directions.
REASONS FOR HIGH CASUALITY:
1) Urbanization is rapidly increasing and due to increase in land cost, many
multi storied buildings are being constructed.
2) Code is not mandatory.
3) Construction as such is governed by municipal bye-laws.
4) Seismic provisions are not incorporated.
5) Non enforceation of elaborated checks proper ways.
6) No checks even for simple ordinary design.
GENERAL GUIDE LINES:
Drift:
It is the maximum lateral displacement of the structure with respect to total
height or relative inter-storey displacement. The overall drifts index is the ratio
of maximum roof displacement to the height of the structure and inter-storey
drift is the ratio of maximum difference of lateral displacement at top and bottom
of the storey divided by the storey height.
Non structural elements and structural non seismic members primarily get
damaged due to drift. Higher the lateral stiffness lesser is the likely damage.
The storey drift in any storey due to minimum specified design lateral force with
partial safety factor of unity shall not exceed 0.004 times the storey height.
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Separation between adjacent units or buildings:
Two adjacent buildings or two adjacent units of the same building with
separation joint in between shall be separated by distance equal to the amount
R times the sum of the calculated storey displacements as specified above of
each of them to avoid damaging contact when the two units deflect towards
each other.
Soft storey:
Soft storey or flexible storey is one in which the lateral stiffness is less than 70%
of that in the storey above or less than 80% of the average lateral stiffness of
the three storeys above. In case of buildings with a flexible storey such as
ground storey consisting of open spaces for parking i.e. stilt buildings, special
arrangements are need to be made to increase the lateral strength and stiffness
of the soft storey.
For such buildings, dynamic analysis is carried out including the strength and
stiffness effects of infills and inelastic deformations in the members particularly
those in the soft storey and members designed accordingly. Alternatively, the
following design criteria are to be adopted after carrying the earthquake
analysis neglecting the effect of infill walls in other storeys.
When the floor levels of two similar adjacent buildings are at the same elevation
levels, factor R can be taken as R/2.
a) The columns and beams of the soft storey are to be designed for 2.5 times
the storey shear and moments calculated under seismic loads specified.
b) Besides the columns designed and detailed for calculated storey shears and
moments, shear walls placed symmetrically in both directions of the building as
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far away from the centre of the building as feasible to be designed exclusively
for 1.25 times the lateral storey shear calculated.
Foundation:
The use of foundations vulnerable to significant differential settlement due to
ground shaping shall be avoided for structures in seismic zones-III, IV & V.
individual spread footings or pile caps shall be interconnected with ties except
when individual spread footings are directly supported on rock. All ties shall be
capable of carrying in tension and in compression an axial force equal to Ah/A
times the larger of the column or pile cap load in addition to the otherwise
computed forces where Ah is the design horizontal spectrum value.
Projections:
a) vertical projections:
Tanks, towers parapets, chimneys and other vertical cantilever projections
attached to buildings and projecting the above roof shall be designed and
checked for stability for 5 times the design horizontal seismic co-efficient Ah. In
the analysis of the building, the weight of these projecting elements will be
lumped with the roof weight.
b) horizontal projections:
All horizontal projections like cornices and balconies shall be
designed and checked for stability for 5 times the design vertical co- efficient
equal to 10/3 Ah. These increased design forces either for vertical projection or
horizontal projection are only for designing the projecting parts and their
connection with the main structures.
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This means that for the design of main structure such increase need not to be
considered.
Shape of the building:
Very slender buildings should be avoided. Large overhangs and projections
attract large earthquake forces. Heavy masses like large water tanks, etc., at
the top shall be avoided. Small water tanks, if provided, should be properly
connected with the framing system. Building should be sufficiently be away from
steep slopes. It should be built on filled up soil.
Asymmetry should be avoided as they undergo torsion and extreme corners are
subjected to very large earthquake forces.
Damping:
Damping is the removal of kinetic energy and potential energy from a vibrating
structure and by virtue of which the amplitude of vibration diminishes steadily.
Some vibrations are due to initial displacement or initial velocity. Due to
damping, these vibrations decay in amplitude.
1. When there is harmonic applied force and its period is nearly equal to the
natural period of the structure. The vibration will grow from zero displacement
and velocity. Damping limits the vibration maximum amplitude.
2. More damping less is the amplitude.
3. Negative damping may arise while the vibration is small, followed by positive
damping at large amplitude vibrations. The code adopted for design of
multistoried buildings considering seismic forces is IS 1893 (part I) – 2002.
more than 60% area of India is earthquake prone. According to IS 1893 (part I)
– 2002, India is divided into several zones to their magnitude of intensities.
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3.2 NEED FOR SEISMIZ ZONATION:
a) There can not be entirely scientific basis for zonation in view of the scanty
data available.
b) Though the magnitudes are known there is little instrumental evidence for
comparing damage.
c) Hence, magnitudes and epicenters are used.
3.3 REVISION OF PAST CODES:
It is very difficult to predict the occurrence time and exact location of next
earthquake. More than 60% area is earthquake prone. Various problems are
generated after an earthquake. The magnitudes of these problems are very
severe. In order to reduce this effective counter measures are to be taken.
Enough steps should be taken by the concerned authorities for code
compliance so that the structures being constructed are earthquake resistant.
Especially during the past 15 years there were severe earthquakes with a less
time gap and high intensity. Based on the technology advancement and
knowledge gained after earthquake occurrences, the seismic code is usually
revised. The fifth revision of IS 1893 with seven zones, was done in 2002 after
along gap of 18 years. According to the present revision, the latest map has
only 4 zones.
Fifth Revision in 2002:
Code has been split into 5 parts:-
Part 1: General provisions and buildings.
Part 2: Liquid retaining tanks-elevated and ground supported.
Part 3: Bridges and retaining walls.
Part 4: Industrial structures including stack like structures.
Part 5: Dams and embankment.
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Part 1: General provisions and buildings:
Zone map is revised and zone factors changed
Response spectra for three types of founding strata
Empirical expression for fundamental natural period
Concept of response reduction factor
Lower bound for design base shear
Model combination rule is revised
Other clauses revised and redrafted
Design philosophy:
The design approach in IS 1893 is…
To ensure that the structure at least a minimum strength to with hand a minor
earthquake (< DBE) without damage,
To resist moderate earthquake (DBE) without significant structural damage
through some non structural damage may occur, and
To withstand a major earthquake (MCE) without collapse.
3.4 TERMINOLOGY:
Critical Damping:
The damping beyond which the free vibration motion will not be oscillatory.
Damping:
The effect of internal friction, imperfect elasticity of material, slipping, sliding
etc., in reducing the amplitude of vibration and is expressed as a percentage of
critical damping.
Design Acceleration Spectrum:
Design acceleration spectrum refers to an average smoothened plot of
maximum acceleration as a function of frequency or time period of vibration for
29
a specified damping ratio for earthquake excitations at the base of a single
degree of freedom system.
Design Basis Earthquake (DBE):
It is the earthquake which can reasonably be expected to occur at least once
during design life of the structure.
Design Horizontal Acceleration Co-efficient (Ah):
It is a horizontal acceleration coefficient that shall be used for design of
structures.
Design Lateral Force:
It is a horizontal seismic force prescribed by this standard that shall be used to
design a structure.
Ductility:
Ductility of a structure or its members is the capacity to undergo large inelastic
deformations without significant loss of strength or stiffness.
Importance Factor:
It is a factor used to obtain the design seismic force depending on the functional
use of the structure characterized by hazardous consequences of its failure, its
post earthquake functional need, historical value or economic importance.
Intensity of Earthquake:
The intensity of an earthquake at a place is a measure of the strength of
shaking during the earthquake and is indicated by number according to the
modified MERCALLIS SCALE or MSK scale of seismic intensities.
Natural Period (T):
Natural period of a structure is its time period of undamped free vibration.
Response Reduction Factor:
It is the factor by which the actual base shear force that would be generated if
the structure were to remain elastic during its response design basis
earthquake (DBE) shaking, shall be reduced to obtain the design lateral force.
Seismic Mass:
It is the seismic weight divided by acceleration due to gravity.
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Seismic Weight:
It is a total dead load plus appropriate amounts of specified impose load.
3.5 EARTHQUAKE AND VIBRATION EFFECT ON STRUCTURES:
BASIC ELEMENTS OF EARTHQUAKE RESISTANT DESIGN:
Introduction:
Structures on the earth are generally subjected to load of two types static and
dynamic. Static loads are constant with time while dynamic loads are time
varying. The majority of civil engineering structures are designed with
assumptions that all applied loads are static. The effect of dynamic loads is not
considered because the structure is rarely subjected to dynamic loads; more so,
its consideration in analysis makes the solution more complicated and time
consuming. This feature of neglecting the dynamic forces may some times
become the cause of disaster, particularly in the case of earthquake. There is a
growing interest in the process of designing civil engineering structures capable
to withstand dynamic loads, particularly, earthquake induced load.
The dynamic force may be an earthquake force resulting from rapid movement
along the plane of faults within earth’s crust. This sudden movement of fault
releases great energy in the form of seismic waves, which are transmitted to the
structures through their foundations, and cause to set the structure in motion.
These motions are complex in nature and induce abrupt horizontal and vertical
oscillations in structures, which result accelerations, velocities and
displacements in the structure. The induced accelerations generate inertial
forces in the structure, which are proportional to the acceleration of the mass
and acting opposite to the ground motion.
The energy produced in the structure by the ground motion is dissipated
through internal friction within the structural and non-structural members. This
dissipation if energy is called damping. The structures always posses some
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intrinsic damping, which diminishes with time once the seismic excitation stops.
These dissipative or damping forces are represented by viscous damping
forces, which are proportional to the velocity induced in the structure. The
constant of proportionality is called as linear viscous damping. The resisting
force in the structures is proportional to the deformation induced in the structure
during the seismic excitation. The constant of proportionality is referred to as
stiffness of structure. Stiffness greatly affects the structure’s uptake of
earthquake generated forces. On the basis of stiffness the structure may be
classified as brittle or ductile.
Brittle structure having greater stiffness proves to be less durable during
earthquake while ductile structure performs well in earthquakes.This behavior of
structure evokes an additional desirable characteristic called ductility. Ductility is
the ability of structure to undergo distortion or deformation without damage or
failure.
The basic equation of static equilibrium under displacement method of analysis
is given by
F(ext) = ky
Where, F(ext) is the external applied static force, k is the stiffness resistance,
and y is the resulting displacement. The restoring force (ky) resists the applied
force, F(ext).
Now, if the applied static force changes to dynamic force or time varying force
the equation of static equilibrium becomes one of the dynamic equilibrium and
has the form
F(t) = my(t) + cy(t) + k(t)y(t)
Where,
my(t) = inertia forces acting in a direction opposite to that of seismic
motion applied to the base of the structure, whose magnitude is the mass of the
32
structure times its acceleration, m is the mass (kg) and y(t) is the acceleration
(m/sec2). Inertia forces are the most significant which depend upon the
characteristic of the ground motion and the structural characteristics of
structure. The basis characteristic of the structure and ground is its fundamental
or natural period.
The fundamental periods of structures may range from 0.05 sec for a well
anchored piece of equipment, 0.1 for a one storey frame, and 0.5 for a low
structure up to 4 storeys and between 1 to 2 seconds for a tall building of 20
storeys.
Natural periods of ground are usually in the range of 0.5 to 1 sec so that it is
possible for the building and ground to have the same fundamental period and
therefore, there is high probability for the structure to approach a state of partial
resonance called as quasi resonance. Hence, in developing a design strategy
for a building, it is desirable to estimate the fundamental periods both of the
structure and of the site so that a comparison can be made to see the existence
of the probability of quasi resonance.
Cy(t) = damping force acting in a direction opposite to that of the seismic
motion, c is the damping co-efficient (N sec/m) and y(t) the velocity (m/sec).
The value of damping in a structure depends on its components. The damping
effect is expressed as a percentage of the critical damping which is the greatest
damping value that allows vibratory moment to develop. The degrees of
damping in common types of structures are reinforced concrete 5 to 10%, metal
frame 1 to 5%, and masonry 8 to 15%
k(t)y(t) = restoring force k(t) is the stiffness (N/m) or resistance is a function of
the yield condition in the structure which is in turn a function of time. y(t) is the
displacement in meters. F(t) is the externally applied force (N).
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The equation above is a second order differential equation that needs to be
solved for the displacement y(t). The number of displacement components
required specifying the position of mass points is called the number of degrees
of freedom to obtain an adequate solution. For some structures, single degree
of freedom may be sufficient where as for others several hundred degrees of
freedom may be required.
3.6 LATERAL LOAD DISTRIBUTION OF FRAME BUILDING:
In a two dimensional moment resisting frame each joint can have at the
most three degrees of freedom (displacement in horizontal and vertical
directions and rotation).
Total number of degree of freedom is 3Nj where Nj is the number of
joints in the frame.
In practice, beams carry very small axial force and undergo negligible
axial deformation. This means horizontal displacement at all joints located at
the beam level s same.
In most buildings uptown moderate height, the axial deformation of
columns is negligible.
Numbers of degrees of freedom are reduced to one rotation and one
horizontal displacement.
As the rotational inertia associated with the rotational degree of freedom
is insignificant, it is further possible to reduce, through static condensation,
the number of degrees to one per storey for carrying out dynamic analysis.
In similar way, each joint of three dimensional frames can have at most
six degrees of freedom.
Finally, there are three degrees of freedom per floor.
Free vibration analysis of the building can thus be carried out by solving
(3N*3N) Eigen value problem, where N is the number of storeys in the
building.
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Once natural frequency and more shape is known it is possible to obtain
the maximum seismic force to be applied at each storey level due to given
earthquake ground motion.
3.7 LATERAL LOAD ANALYSIS OF MOMENT RESISTING FRAME:
Once the design lateral loads are known on the two-dimensional frames,
one could analyze the frame for the member forces.
One could carry out an accurate computer analysis or an approximate
analysis as per requirement.
Approximate analysis is usually performed at preliminary design stage and
to assess the computer analysis.
Two commonly used methods:-
A. Portal frame method: Consider the 2-D frame with m-base and n-storeys.
The degree of indeterminacy of the frame is 3mn. To analyze the frame, 3mn
assumptions are made;
The point of contra-flexure in the column is at mid-height of the columns:
(m+1)n assumptions.
The point of contra-flexure in the beams is at the mid span of the beams: mn
assumptions.
Axial force in the internal columns is zero (m+1)n assumptions.
With the above assumptions, the frame becomes statically determinate and
member forces are obtained simply by considering equilibrium.
B. Cantilever method: In this method also, 3mn assumptions are to be made
to make the frame statically determinate; the point of contra-flexure in the
column is at mid-height of the columns: (m+1)n assumptions.
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The point of contra-flexure in the beams is at mod span of the beams: mn
assumptions.
Axial force in the columns is approximated by assuming that the frame
behaves as a cantilever beam. Neutral axis of the frame is obtained using
the column area of cross section and the column location, axial stress in the
column is assumed to vary linearly from this neutral axis: (m-1)n
assumptions.
3.8 SEISMIC METHOD OF FRAMES:
Once the structural model has been selected, it is possible to perform analysis
to determine the seismically induced forces in the structures. There are different
methods of analysis, which provide different degrees of accuracy. The analysis
process can be categorized on the basis of three factors: the type of the
external applied loads, the behavior of structure and the type pf structural model
selected.
Depending upon the nature of the considered variables, the method of analysis
can be classified. Based on the type of external action and behavior of structure
the analysis can be further classified as linear static analysis, dynamic analysis,
non linear analysis, or non linear dynamic analysis.
Linear static analysis or equivalent static analysis:
Linear static analysis or equivalent static analysis can only be used for regular
structure with limited height. Linear dynamic analysis can be performed in two
ways either by mode superposition method or response spectrum method and
elastic time history method.
This analysis will produce the effect of the higher modes of vibration and the
actual distribution of forces in the elastic range in a better way. They represent
36
an improvement over linear static analysis. The significant difference between
static and dynamic analysis is the level of force and their distribution along the
height of the structure.
Non-linear static analysis:
Non-linear static analysis is an improvement over the linear static or dynamic
analysis in the sense that it allows the inelastic behavior of structure. The
methods still assume a set of static incremental lateral load over the height of
the structure. The method is relatively simple to be implemented, and provides
information on the strength, deformation and ductility of the structure and the
distribution of demands.
This permits to identifying of critical members likely to reach limit stated during
the earthquake, for which attention should be given during the design and
detailing process. But this method contains many limited assumptions, which
neglect the variation of loading patterns, the influence of higher modes, ad the
effect of resonance.
This method, under the name of push over analysis has acquired a great deal
of popularity now-a-days and in spite of these deficiencies this method provides
reasonable estimation of the global deformation capacity, especially for
structures, which primarily respond according to the first mode.
A non-linear dynamic analysis or inelastic time history analysis is the only
method to describe the actual behavior of structure during an earthquake. The
method is based on the direct numerical integration of the motion differential
equations by considering the elastic-plastic deformation of the structure
element.
37
This method captures the effect of amplification due to resonance, the vibration
of displacements at diverse levels of a frame, an increasing of motion duration
and a tendency of regularization of movements as far as the level increases
from bottom to top.
Equivalent lateral force: Seismic analysis of most of the structures art still
carried out on the basis of lateral force assumed to be equivalent to the actual
loading. The base shear, which is the total horizontal force on the structure, is
calculated on the basis of structure mass and fundamental period of vibration
and corresponding mode shape. The base shear is distributed along the height
of structured in terms of lateral forces according to code formula. This method is
usually conservative for low to medium height buildings with a regular
conformation.
Response spectrum: This method is applicable for those structures where
modes other than the fundamental one affect significantly the response of the
structure. In this method the response of analysis multi-degree-of-freedom
system (MDOF) is expressed as the superposition of model response, each
modal response being determined from the spectral analysis of single degree-
of-freedom system, which are then combined to compute the total response.
Modal analysis leads to the history of the structure to a specified ground motion;
however, the method is usually used in conjunction with a response spectrum.
Elastic time theory: A linear time history analysis overcomes all the
disadvantages of modal response spectrum analysis, provided non-linear
behavior is not involved. This method requires greater computational efforts for
calculating the response at discrete times. One interesting advantage of such
procedure is that the relative signs of response quantities are preserved in the
response histories. This is important when interaction effects are considered in
design among stress resultants.
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3.9 Seismic Design Methods:
Conventional civil engineering structures are designed on the basis of two main
criteria that are strength and rigidity. The strength is related to damageability or
ultimate limit state, assuring that the level developed in structures remains in
the elastic range, or some limited plastic deformation. The rigidity is related to
serviceability limit state, for which the structural displacements must remain in
some limits, which assures that no damage occurs in non-structural elements.
In case of earthquake resistant design, a new demand must be added to the
two above-mentioned ones, that is the ductility method.
Ductility is an essential attribute of a structure that must respond to strong
ground motions. Ductility serves as the shock absorbers in a building, for it
reduces the transmitted force to one that is sustainable. The resultant
sustainable force has traditionally been used to design a hypothetically elastic
representation of the building.
Therefore, the survivability of a structure under strong, seismic actions relies on
the capacity to deform beyond the elastic range, and to dissipate seismic
energy through plastic deformations, so the ductility check is related to the
control of whether the structure is able to dissipate the given quantity of seismic
energy considered in structural analysis or not. Based on three criteria rigidity,
strength and ductility the methods of seismic design are classified.
RESPONSE CONTROL CONCEPT:
Structural response control for seismic loads is a rapidly expanding field of
control systems, known as earthquake protection system. The aim of this
control system is the modification of the dynamic interaction between structure
and earthquake ground motion, in the order to minimize the structure damage
39
and to control the structural response. The family of earthquake protective
systems has grown to include passive, active and hybrid systems.
The control is based on two different approaches, either the modification of the
dynamic characteristics of the energy absorption capacity of the structure. In
the first case, the structural period is shifted away from the predominant periods
of the seismic input, thus avoiding the risk of resonance occurrence. It is clear
here that the isolation is effective only for a limited range of frequencies of
structures. The acceleration responses in the structure for some earthquakes
can be reduced at the same time,; for the other type of earthquake the
responses have proved to be much worse. Thus the effectiveness of isolation
depends upon the effectiveness of knowing in advance the kind of frequency
content that the earthquake will have. In the second case, the capacity of the
structure to absorb energy is enhanced through appropriate devices, which
reduces damage to the structure. Both the approaches are used in the
earthquake protection system.
IS 1893 (part I) 2002 suggests the following methods for seismic analysis:
Equivalent static analysis (ESA)
Dynamic
a) Response spectrum analysis
b) Time history analysis
3.9.1 EQUIVALENT STATIC ANALYSIS (ESA) :
Equivalent static analysis (ESA) is good enough for most of the buildings. It is
generally adopted for
Regular buildings of height less than 90m irregular buildings of height less
than 40m.
3.9.1.1 DETERMINATION OF DESIGN LATERAL FORCES:
40
The determination of lateral force in the code is based on the approximation
that effects of yielding can be accounted for by linear analysis of the building
using the design spectrum. This analysis is carried out by either modal analysis
procedure or dynamic analysis procedure (clause 7.8 of IS 1893 [part I]: 2002).
Lateral force procedure (clause 7.5 of IS 1893 [part I]: 2002) is also recognized
as equivalent lateral force procedures or equivalent static procedure. The main
difference between the equivalent lateral force and dynamic analysis procedure
lies in the magnitude and distribution of lateral forces over the height of the
buildings. In the dynamic analysis procedure, the lateral forces are based on
the properties of the natural vibration modes of the building which are
determined by distribution of mass and stiffness over height. In the equivalent
lateral force procedures the magnitude of forces is based on an estimation of
the fundamental period and on the distribution of forces given by simple
formulae.
EQUIVALENT LATERAL FORCE PROCEDURES:
The equivalent lateral force is the simplest method of analysis and requires less
computational effort because the forces depend on the code based
fundamental period of structures with some empirical modifier. The design base
shear shall first be computed as a whole, than be distributed along height of
buildings based on simple formulae appropriate for buildings with regular
distribution of mass and stiffness. The design lateral force obtained at each
floor level shall then be distributed to individual lateral load resisting elements
depending upon diaphragm action. The following are the major steps for
determining the forces by equivalent lateral force procedures.
3.9.2 DYNAMIC ANALYSIS:
41
IS 1893 (part I): 2002 has recommended the method of dynamic analysis of
buildings in the case of
(a) Regular building:
These are greater than 40m in height in zones IV and V and those greater than
90m in height in zones II and III.
(b) Irregular building:
(c) All framed buildings higher than 12m in zones IV and V and those greater
than 40m in height in zones II and III.
The purpose of dynamic analysis is to obtain the design seismic forces, with its
distribution to different levels along the height of the building and to the various
lateral load-resisting elements similar to equivalent lateral force method. The
procedure of dynamic analysis described in the code is valid only for regular
type of buildings, which are almost symmetrical in plan and elevation about the
axes having uniform distribution of lateral load resisting elements. It is further
assumed that all the masses are lumped at the storey level and only sway
displacement is permitted at each storey. The procedure of dynamic analysis of
irregular type of buildings should be based on 3D modeling of building that will
adequately represent its stiffness and mass distribution along the height of the
building so that its response to earthquake could be predicted with sufficient
accuracy.
3.10 DETERMINATION OF BASE SHEAR:
42
The total design force or design base shear along any principal direction shall
be determined by the following expression:
Vb = Ah * W
Where Vb = design base shear
Ah = design horizontal seismic co-efficient for a structure
W = seismic weight of building
Ah shall be determined by the following expression:
Ah = (Z/2)* (I/R) * (Sa/g)
Where, Z= zone factor
I= importance factor
R= response reduction factor
Sa/g= average response acceleration co-efficient
3.10.1 ZONE FACTOR (Z):
In factor z/2, Z is given in table-2 of IS 1893 [part 1]: 2002 for the Maximum
Considered Earthquake (MCE) and service life of structure in a zone. The factor
2 in the denominator of Z is used so as to reduce the Maximum Considered
Earthquake zone factor to the factor for Design Basis Earthquake (DBE). Z can
also be determined from the seismic zone map of India which segregates the
country in various areas of similar probable maximum intensity ground motion.
The maximum intensity is fixed in such a way that the lifeline/ critical structure
will remain functional and there is low probability of collapse for structures
designed with the provisions provided in the code even for an event of
occurrence of earthquake with higher intensity. The value of Z ranges from
0.102 to 0.36 corresponding to Zone II to Zone V. This map has divided the
whole country into 4 Zones starting from Zone II to V.
The intensity as per comprehensive intensity scale (MSK64) broadly associated
with the various zones is VI (or less), VII, VIII & IX (and above) for Zones II, III,
43
IV & V respectively. In Zone II, low seismic intensity zone where minor damage
could occur has a Z value 0.10.
Zone III (Z= 0.16), moderate intensity zone where moderate damage could
occur. Zone IV (Z= 0.24), severe intensity zone where major property damage
could occur and Zone V (Z= 0.36), where severe intensity zone that lie in close
proximity to certain prescribed major fault systems.
3.10.2 Importance factor (I):
It depends upon the fundamental use of the structure characterized by
hazardous consequences of its failure, post earthquake functional needs,
historic value or economic importance. The minimum values of importance
factor are given in table 6 of IS 1893 (part I) 2002. According to table 6
buildings are classified into two categories:
1) Importance service and community buildings
2) All other buildings
Importance service buildings have an I value of 1.5 and all other buildings are
assigned a value of 1.0. The value of I may be more than the assigned value
depending upon economy, strategy considerations like multi storied buildings,
hazardous consequences etc., essential facilities referred to those buildings of
structures that must be safe and usable for emergency purpose after a major
earthquake has occurred in order to preserve the peace, health and safety of
general public.
3.10.3 Response reduction factor (R):
It depends upon the perceived seismic damage performance of the structure,
characterized by ductile or brittle deformations. This characteristic represents
the structures ductility, damping as well as the past seismic performance of
structure with various structural framing structure. The need for incorporation of
factor R in base shear formulae is an attempt to consider the structures in
44
elastic characteristics in linear analysis method since it is undesirable as well as
uneconomical that a structure will be designed on the basis that it will remain in
elastic range for all major earthquakes. The base shear equation produces
force levels that probably or more representative of those occurring in an actual
structure. It is achieved by applying those base shears for linear design that are
reduced by a factor I/R from those that would be obtained from fully elastic
response.
The value of R increases with the increase of structural ductility and its energy
dissipation capacity and degree of redundancy. The value of R is prescribed in
table 7 of IS 1893 (part I) 2002 for different types of building system. A low
value of R approaching 1.5 is assigned to an extremely brittle building i.e.,
unreinforced masonry wall buildings and a high value of 1.5 is assigned to a
more ductile structure like special moment resisting frame reinforced concrete
or shear wall building.
3.10.4 Average response acceleration co-efficient (Sa/g):
Sa/g for rock or soil sites for different soil conditions based on appropriate
natural periods of the structure is given by fig 2 of IS 1893 (part I) 2002.
These values are given for 5% of damping of the structure; for other value of
damping it is modified according to table 3 of IS 1893 (part I) 2002. These
curves represent free field ground motion.
The fundamental natural period for buildings are given in clause 7.6 of IS 1893
(part I) 2002 and is summarized below
Ta = 0.075* ho.75
Moment resisting RC frame buildings without brick in fill walls.
Ta = 0.085* ho.75
Moment resisting steel frame buildings without brick in fill walls.
45
Ta = 0.09/d0.5
All other buildings including moment resisting RC frame building without brick in
fill walls. (h is the height of building in meters and d is the base dimension of
building at plinth level in meter, along the considered direction of lateral force).
W = seismic weight of building which is the sum of the seismic weight of
floors. The seismic weight at any floor level would be equal to dead weight of
the floor system plus weight of column and walls in inverse proportion to its
distance from the floors plus appropriate amount of imposed load as specified
in clause 7.3 of IS 1893 (part I) 2002. Imposed load on roof level need not to be
considered. The basic reasons for considering the percentage of live load are
1. Only a part of the maximum live load will probably be existing at the time of
earthquake.
2. Non rigid mounting of the live load absorbs part of the earthquake energy.
3.11 Lateral Distribution of Base shear:
The computer base shear is now distributed along the height of the building.
The shear force, at any level, depends on the mass at that level and deforms
shape of the structure. Generally, a structure has a continuous system with
infinite degree-of-freedom. From structural idealization we convert an infinite
degree-of-freedom to finite degree of freedom system. Multi storied building has
been idealized into lumped mass model by assuming the mass of the building
lumped at each floor levels (called node); with one degree of freedom in the
direction of lateral displacement in which the structure is being analyzed per
floor, resulting in as many degree of freedom as of freedom system with many
possible patterns of deformations.
The magnitude of the lateral force at a particular floor (node) depends on the
mass of that node, the distribution of stiffness over the height of structure, and
the nodal displacement in a given node. The actual distribution of base shear
46
over the height of the building is obtained as the superposition of all the nodes
of vibration of the multiple degree of freedom system.
In equivalent force procedure, the magnitude of lateral forces is based on
fundamental period of vibration, the other periods and shapes of natural nodes
are not required. IS 1893 (part I): 2002 uses a parabolic distribution (Paz, 1994)
of lateral force along the height of building as per the following expression.
n
Q= VB* (W1-h12) / Σ Wig* h1
2
j=1
Where, Q= Design lateral force at floor i,
W= Seismic weight of floor i,
h1= Height of floor I measured from base, and
n= Number of storeys in the building is the number of levels at which
masses are located.
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4.1 PRESENT PROBLEM:
We have considered a proposed multi storied building in HYDERABAD. The structure is designed for (G+4) as per requirements. The complete building has been idealized using STAAD software. The structure is designed as per requirements and specifications.
Why only STAAD Pro.?
STAAD Pro is widely used software for structural analysis and integral steel, concrete, timber, aluminum, design from research engineering international. STAAD Pro consists of a core package and an extension component. The STAAD Pro core package consists of the following component THE STAAD PRO GRAPHICAL USER INTERFACE. It is used to generate the model, which can then be analyzed using the STAAD Pro.
STAAD ENGINEERING:
It is general purpose calculation engineering structural analysis and integrated steel, concrete, timber and aluminum design. The STAAD Pro extension program consists of the following. This package consists of several modules for very specific structures engineering tasks such as analysis and design of base plate, footings, cantilever retaining wall, bolt group, pile group, one way and two way slabs etc.
48
4.2 DESIGN CONSIDERATIONS
The design of reinforced concrete members have been carried out in accordance with IS 456-2000 using limit state.
Live load on floors and roofs have been considered as per IS 875 part 2 1987 as 2kN/m2 and 1.5kN/m2.
Floor finishes on floors and roofs have been considered as per IS 875 part 1 1987 as 1.5kN/m2 and 1.75kN/m2.
Concrete of M20 grade is considered for all concrete members. High yield strength deformed bars confirming to IS 1786 is considered for all
R.C.C members. As per soil reports, the safe bearing capacity is considered as 250kN/m2 for
design of footings. IS 1893 part 1 2002 has been used for calculation of base shear. Zone factor is taken as 0.1(zone 2) Importance factor is taken as 3 Average response acceleration coefficient is taken as 2.5 (from curves)
49
5.1 LOAD CALCULATIONS
5.1.1 DEAD LOADS:
WALL LOADS:
EXTERNAL WALLS : Thickness*height * unit wt
=0.23*(3.05-0.3)*19
= 12.018 KN/m
INTERNAL WALLS : Thickness * height *unit wt
= 0.115*(3.05-0.3)*19
=6.009 KN/m
FLOOR LOADS:
self weight of the slab = 0.125*25 = 3.125 KN/Sq.m
weight of the floor finish = 0.75 KN/Sq.m
weight of unknown partitions = 0.5 KN/Sq.m
total floor load 4.375 KN/Sq.m
LOADS ON CANTILEVER:
cantilever load = floor load*length
= 4.375 * 1.56
= 6.825 KN/m
PARAPET WALL:
Parapet wall load = thickness*height*unit wt
= 0.23*0.75*19
= 3.2775 KN/m
(height of parapet wall taken as 0.75m)
50
5.1.2 LIVE LOADS:
for first 5 floors live load = 2 KN/Sq.m
for terrace live load = 1.5 KN/Sq.m
5.2 SEISMIC EQUIVALENT METHOD
Seismic equivalent method involves
Converting the dynamic seismic loads into equivalent static loads. The base shear, which is total horizontal force on the structure is calculated
on the basis of structure mass and fundamental period of vibration. The base shear is distributed along the height of structure in terms of lateral
forces according to IS:1893-2002
Design seismic base shear
Seismic base shear = VB =Ah *W
Ah = (Z*I*Sa/g)/(2*R)
where W = seismic weight of the buildingZ = zone factorR = response reduction factor
Sa/g = Avg. response acceleration coefficient.
Values according to IS:1893 :2002
Zone Factor Z= 0.10 (Zone 2) Importance factor I =1.0 Response reduction factor R = 3.0 Avg. response acceleration coefficient 1+15T 0.00<T<0.1 Sa/g = 2.50 0.10<T<0.40
1.00/T 0.40<T<4.00 (from graphs of Rocky/hard soil sites)
51
DISTRIBUTION OF BASE SHEAR TO DIFFERENT FLOOR LEVELS:
Qi = VB * Wi*hi^2 SUM(Wj*hj^2)
Qi = design lateral force at floor i Wi = seismic weight of floor i
hi = height of floor i measured from base
52
5.3 RESPONSE SPECTRUM METHOD
Response spectrum method involves
In this method the response of analysis of multi degree of freedom system is expressed as the superposition of modal response, each model response being determined from the spectral analysis of single degree of freedom system, which are then combined to compute the total response.
In this method peak ground accelerations are given as input (from the response spectrum, a graph between acceleration and time period).
RESPONSE SPECTRA
INPUT:
LOAD 1 SEISMIC LOADINGSELFWEIGHT X 1.0SELFWEIGHT Y 1.0MEMBER LOADSSPECTRUM SRSS X 1.0 ACC DAMP 0.05 SCALE 32.20.25 2.5; 0.5 2; 0.75 1.3; 1.00 1.0; 1.25 0.8; 1.5 0.7; 2.00 0.6; 2.25 0.45; 2.5 0.4; 2.75 0.4; 3.00 0.35; 3.25 0.3; 3.5 0.3; 3.75 0.25; 4.00 0.25
53
Results
EIGEN VALUES
CALCULATED FREQUENCIES FOR LOAD CASE 1 MODE FREQUENCY PERIOD(SEC) ACCURACY
(CYCLES/SEC) 1 1.838 0.54404 2.131E-16 2 2.273 0.43990 4.179E- 3 2.296 0.43556 4.097E-16 4 2.441 0.40967 3.262E- 5 2.977 0.33593 3.622E- 6 4.445 0.22499 2.106E-09 7 4.727 0.21154 1.250E-07 8 4.813 0.20776 1.408E-08 9 5.232 0.19115 2.102E-07 10 5.369 0.18625 6.780E-07
MASS PARTICIPATION FCTORS
MASS PARTICIPATION FACTORS IN PERCENT BASE SHEAR IN KN -------------------------------------- ------------------ MODE X Y Z SUMM-X SUMM-Y SUMM-Z X Y Z 1 74.0 0.00 0.00 74.012 0.000 0.000 31871.14 0.00 0.00 2 0.13 0.00 0.00 74.144 0.000 0.000 64.28 0.00 0.00 3 8.03 0.00 0.00 82.178 0.000 0.000 3924.31 0.00 0.00 4 0.00 0.00 0.00 82.179 0.000 0.000 0.60 0.00 0.00 5 0.43 0.00 0.00 82.611 0.000 0.000 230.50 0.00 0.00 6 0.02 0.00 0.00 82.634 0.000 0.000 13.59 0.00 0.00 7 0.00 0.00 0.00 82.634 0.000 0.000 0.00 0.00 0.00 8 0.00 0.00 0.00 82.634 0.000 0.000 0.00 0.00 0.00 9 0.16 0.00 0.00 82.789 0.000 0.000 93.30 0.00 0.00 10 5.07 0.00 0.00 87.856 0.000 0.000 3054.52 0.00 0.00 --------------------------- TOTAL SRSS SHEAR 32257.81 0.00 0.00 TOTAL 10PCT SHEAR 32274.53 0.00 0.00 TOTAL ABS SHEAR 39252.24 0.00 0.00
54
DESIGN OF STRUCTURAL ELEMENTS
6.1 DESIGN OF FOOTINGS
Axial load = 1310kNSelf weight = 0.1*1310 = 131kNTotal load = 1441kN SBC = 250kN/m2 Area required = 1441/250 = 5.764m2
Column size = 0.23*0.6m2
ratio a/b = 0.23/0.3 = 0.383 Area = B*L = 0.383*L2 5.764 = o.383*L2 L = 3.88m B = 1.5m Therefore, provide 2*3m2 Area provided = 2*3 = 6m2 Net factored soil pressure = (1.5*1310)/6 = 327.5kN/m2 ONE WAY SHEAR :Critical section is at ‘d’ from the face,
Vu1 = qu*B*[((B-b)/2)-d] = 327.5*2*[((2-0.23)/2)-d] = 579.675-655d
Along shorter direction, Vc1 = Tc *B*d = 360*2*d = 720d
Vu1 = Vc1
579.675-655d = 720d
Therefore d = 421.6mm
Along longer direction, Vu1= qu *L*((L-a)/2)-d) = 327.5*3*((3-0.6)/2)-d) = 1179-982.5d Vc1= 360*3*d = 1080d
55
Vu1= Vc1
1179= 2062.5d d= 571.64mm Therefore, provide d= 600mm Overall depth, D= 600+75+(16/2) = 683mm TWO-WAY SHEAR: The critical section is at ‘d/2’ from face, Shear force, Vu2= qu*((L*B) - (a+d)*(b+d)) = 327.5*((6) – (0.23+0.6)*(0.6+0.6) = 1638.81kN Shear stress, Tv= Vu2/(perimeter*d) = 1638.81/((0.23+0.6+(2*0.6))*2*600) = 672.75Mpa Shear strength of concrete, Tc= 0.25*(fck)1/2
ks= 0.5+βc< 1 βc= 0.23/0.6= 0.383 ks= 0.5+0.383 = 0.883< 1 Shear strength= Tc* ks = 0.25*(20)1/2* 0.883 = 0.987> Tv Hence safe Overall depth, D= 683mm dx= 600mm dy= 600-16= 584mm Vu1= 327.5*L*[((B-b)/2)-dy] = 315.4*3*[((2-0.23)/2)-0.584] = 295.73kN Tv= Vu1/(L*d) = 295.73/(3*0.584) = 168.8kN/m2 Tv < Tc Hence safe
FLEXURAL REINFORCEMENT: Mux= (q/8)*L*(B-b)2 = (327.5/8)*2*(3-0.60)2 = 471.6kN-m
R= Mu/(B*d2) = 471.6*106/(2000*6002) = 0.6355 (Ptreq/100)= (0.5*fck)/fy* 1- [1-((4.58*R)/fck)]1/2
= 1.88*10-3 < 0.25
56
Astrequired = 0.25*2000*(600/100) = 3000mm2 Using 16mm bars, Aø= 201mm2
N= 3000/201= 14.93= 15 no’s
Astprovided= 15*201 = 3015mm2
Spacing, s= [2000-((75*2*)-16)]/(15-1) = 133.3mm Therefore, provide 15 # 16mm ø @ 130mm c/c Muy = 534.3kN-m R= 0.376 (Pt/100)= 1.6*10-3 < 0.25 Hence ok
Astrequired= 4380mm2
Aø= 201mm2 N= 22 no’s Astprovided = 19*201 = 3819mm2
Spacing, s=137.23mm Therefore, provide 22 # 16mm ø @ 130mm c/c
DEPTH OF FOUNDATION: Df= (q/r)* [(1-sinθ)/(1+sinθ)]2 = (327.5/18)*[(1-sin30)/(1+sin30)]2 = 2.0m
57
FOOTING 2:
Axial load = 942KnSelf weight = 0.1*942 = 94.2kN
Total load = 1036.2kN
SBC = 250kN/m2
Area required = 1036.2/250
= 4.15m2
Column size = 0.23*0.6m2
ratio a/b = 0.23/0.3 = 0.383
Area = B*L = 0.383*L2
4.15 = o.383*L2
L = 3.29m
B = 1.26m
Therefore, provide 1.6*2.8m2
Area provided = 1.6*2.8
= 4.48m2
Net factored soil pressure = (1.5*942)/4.48
= 315.4kN/m2
ONE WAY SHEAR :
Critical section is at ‘d’ from the face,
Vu1 = qu*B*[((B-b)/2)-d]
= 315.4*1.6*[((1.6-0.23)/2)-d]
= 345.68-504.64d
Along shorter direction,
Vc1 = Tc *B*d
= 360*1.6*d
58
= 576d
Vu1 = Vc1
345.68-504.64d = 576d
Therefore d = 319.88mm
Along longer direction,
Vu1= qu *L*((L-a)/2)-d)
= 315.4*2.8*((2.8-0.6)/2)-d)
= 971.432-883.12d
Vc1= 360*2.8*d
= 1008d
Vu1= Vc1
971.432= 1891.12d
d= 513.68mm
Therefore, provide d= 550mm
Overall depth, D= 550+75+(16/2)
= 633mm
TWO-WAY SHEAR:
The critical section is at ‘d/2’ from face,
Shear force, Vu2= qu*((L*B) - (a+d)*(b+d))
= 327.5*((1.6*2.8) – (0.23+0.6)*(0.6+0.6)
= 1141.01kN
Shear stress, Tv= Vu2/(perimeter*d)
= 1141.01/((0.23+0.6+(2*0.6))*2*550)
= 0.511Mpa
59
Shear strength of concrete, Tc= 0.25*(fck)1/2
ks= 0.5+βc< 1
βc= 0.23/0.6= 0.383
ks= 0.5+0.383 = 0.883< 1
Shear strength= Tc* ks
= 0.25*(20)1/2* 0.883
= 0.987> Tv
Hence safe
Overall depth, D= 633mm
dx= 550mm
dy= 550-16= 534mm
Vu1= 315.4*L*[((B-b)/2)-dy]
= 315.4*2.8*[((1.6-0.23)/2)-0.534]
= 133.35kN
Tv= Vu1/(L*d)
= 133.35/(2.8*0.534)
= 89.185kN/m2
Tv < Tc
Hence safe
FLEXURAL REINFORCEMENT:
Mux= (q/8)*L*(B-b)2
= (315.4/8)*1.6*(1.6-0.23)2
= 305.30kN-m
R= Mu/(B*d2)
= 305.30/(1.6*0.552)
= 0.63
60
(Ptreq/100)= (0.5*fck)/fy* 1- [1-((4.58*R)/fck)]1/2
= 1.875*10-3 < 0.25
Hence ok
Astrequired = 0.25*1600*(550/100)
= 2200mm2
Using 16mm bars, Aø= 201mm2
N= 2200/201= 10.94= 11 no’s
Astprovided= 11*201
= 2211mm2
Spacing, s= [1600-((75*2*)-16)]/(11-1)
= 146.6mm
Therefore, provide 11 # 16mm ø @ 140mm c/c
Muy = [(315.4*2.8)/8]*(2.8-0.6)2
= 534.3kN-m
R= 0.67
(Pt/100)= 1.925*10-3 < 0.25
Hence ok
Astrequired= 0.25*2800*(534/100)
= 3738mm2
Aø= 201mm2
N= 18.6= 19 no’s
Astprovided = 19*201
= 3819mm2
Spacing, s= [2800-((75*2)-(16*2))]/(19-1)
= 149mm
61
Therefore, provide 19 # 16mm ø @ 140mm c/c
DEPTH OF FOUNDATION:
Df= (q/r)* [(1-sinθ)/(1+sinθ)]2
= (315.4/18)*[(1-sin30)/(1+sin30)]2
= 1.95m
62
FOOTING 3:
Axial load = 797kNSelf weight = 0.1*797 = 79.7kN
Total load = 876.7kN
SBC = 250kN/m2 Area required = 876.7/250
= 3.5m2
Column size = 0.23*0.6m2
ratio a/b = 0.23/0.3 = 0.383
Area = B*L = 0.383*L2
3.5 = o.383*L2
L = 3.0m
B = 1.16m
Therefore, provide 1.5*2.5m2
Area provided = 1.5*2.5
= 3.75m2 Net factored soil pressure = (1.5*797)/3.75
= 318.8kN/m2
ONE WAY SHEAR :
Critical section is at ‘d’ from the face,
Vu1 = qu*B*[((B-b)/2)-d]
= 318.8*1.5*[((1.5-0.23)/2)-d]
= 303.66-478.2d
Along shorter direction,
Vc1 = Tc *B*d
= 360*1.5*d
= 540d
63
Vu1 = Vc1
303.66-478.2d = 540d
Therefore d = 298.23mm
Along longer direction,
Vu1= qu *L*((L-a)/2)-d)
= 318.8*2.5*((2.5-0.6)/2)-d)
= 757.15-797d
Vc1= 360*2.5*d
= 900d
Vu1= Vc1
757.15= 1697d
d= 446.17mm
Therefore, provide d= 480mm
Overall depth, D= 480+75+(16/2)
= 563mm
TWO-WAY SHEAR:
The critical section is at ‘d/2’ from face,
Shear force, Vu2= qu*((L*B) - (a+d)*(b+d))
= 318.8*((3.75) – (0.7668)
= 951.04kN
Shear stress, Tv= Vu2/(perimeter*d)
= 951.04/((0.23+0.6+(2*0.48))*2*480)
= 0.553Mpa
Shear strength of concrete, Tc= 0.25*(fck)1/2
ks= 0.5+βc< 1
βc= 0.23/0.6= 0.383
64
ks= 0.5+0.383 = 0.883< 1
Shear strength= Tc* ks
= 0.25*(20)1/2* 0.883
= 0.987> Tv
Hence safe
Overall depth, D= 563mm
dx= 480mm
dy= 480-16= 464mm
Vu1= 318.8*L*[((B-b)/2)-dy]
= 318.8*2.5*[((1.5-0.23)/2)-0.464]
= 136.3kN
Tv= Vu1/(L*d)
= 136.3/(2.5*464)
= 0.117Mpa
Tv < Tc
Hence safe
FLEXURAL REINFORCEMENT:
Mux= (q/8)*L*(B-b)2
= (318.8/8)*1.5*(1.5-0.23)2
= 96.41kN-m
R= Mu/(B*d2)
= 96.41*106/(1.5*0.482*103)
= 0.297
(Ptreq/100)= (0.5*fck)/fy* 1- [1-((4.58*R)/fck)]1/2
= 7.28*10-4 < 0.25
Hence ok
65
Astrequired = 0.25*1500*(480/100)
= 1800mm2
Using 16mm bars, Aø= 201mm2
N= 1800/201= 8.95= 9 no’s
Astprovided= 9*201
= 1809mm2
Spacing, s= [1500-((75*2*)-16)]/(9-1)
= 146.6mm
Therefore, provide 9 # 16mm ø @ 165mm c/c
Muy = [(318.8*2.5)/8]*(2.5-0.6)2
= 359.65kN-m
R= Muy/(L*dy2)
= (359.65*106)/(2.5*4642*103)
= 0.668
(Pt/100)= 1.9*10-3 < 0.25
Hence ok
Astrequired= 0.25*2500*(464/100)
= 2900mm2
Aø= 201mm2
N= 14.43= 15 no’s
Astprovided = 15*201
= 3015mm2
Spacing, s= [2500-((75*2)-(16*2))]/(15-1)
= 170mm
Therefore, provide 15 # 16mm ø @ 165mm c/c
66
DEPTH OF FOUNDATION:
Df= (q/r)* [(1-sinθ)/(1+sinθ)]2
= (318.8/18)*[(1-sin30)/(1+sin30)]2
= 1.97m
67
FOOTING 4:
Axial load = 201kN
Self weight = 0.1*201 = 20.1kN
Total load = 221.1kN
SBC = 250kN/m2
Area required = 221.1/250
= 0.884m2
Column size = 0.23*0.45m2
ratio a/b = 0.23/0.45 = 0.51
Area = B*L = 0.51*L2
0.884 = o.383*L2
L = 1.315m
B = 0.672m
Therefore, provide 0.7*1.5m2
Area provided = 0.7*1.5
= 1.05m2
Net factored soil pressure = (1.5*201)/1.05
= 287.14kN/m2
ONE WAY SHEAR :
Critical section is at ‘d’ from the face,
Vu1 = qu*B*[((B-b)/2)-d]
= 287.14*0.7*[((0.7-0.23)/2)-d]
= 47.23-200.998d
Along shorter direction,
Vc1 = Tc *B*d
68
= 360*0.7*d
= 252d
Vu1 = Vc1
47.23-200.998d = 252d
Therefore d = 104.3mm
Along longer direction,
Vu1= qu *L*((L-a)/2)-d)
= 287.14*1.5*((1.5-0.45)/2)-d)
= 193.82-430.71d
Vc1= 360*1.5*d
= 540d
Vu1= Vc1
193.82-430.71d= 540d
d= 199.7mm
Therefore, provide d= 250mm
Overall depth, D= 250+75+(10/2)
= 330mm
TWO-WAY SHEAR:
The critical section is at ‘d/2’ from face,
Shear force, Vu2= qu*((L*B) - (a+d)*(b+d))
= 184.3kN
Shear stress, Tv= Vu2/(perimeter*d)
= 184.3/((0.23+0.45+(2*0.25))*2*250)
= 0.312Mpa
Shear strength of concrete, Tc= 0.25*(fck)1/2
ks= 0.5+βc< 1
69
ks= 0.5+0.51 = 1.01
ks= 1
Shear strength= Tc* ks
= 0.25*(20)1/2* 1
= 1.12> Tv
Hence safe
Overall depth, D= 330mm
dx= 250mm
dy= 250-10= 240mm
Vu1= 287.14*L*[((B-b)/2)-dy]
= 287.14*1.5*[0.235-0.234]
= 0.43kN
Tv= Vu1/(L*d)
= 0.43/(1500*234)
= 0.00001kN/m2
Tv < Tc
Hence safe
FLEXURAL REINFORCEMENT:
Astx = 0.25*700*(250/100)
= 437.5mm2
provide 10mm bars, Aø= 78.56mm2
N= 5.7= 6 no’s`
Astprovided = 6*78.56= 471.34mm2
Spacing, s = [(700-(75*(2-10)))/(6-1)]
= 112mm
Therefore, provide 6 no’s # 10mm ø @ 110mm c/c
70
Asty = 0.25*1500*(240/100)
= 900mm2
Aø = 78.56mm2
N = 11.45 = 12no’s
Astprovided= 12*78.56
= 942.72mm2
Spacing, s= [1500-((75*2*)-(10*2))]/(12-1)
= 124.54mm
Therefore, provide 12no’s # 16mm ø @ 140mm c/c
DEPTH OF FOUNDATION:
Df= (q/r)* [(1-sinθ)/(1+sinθ)]2
= (287.14/18)*[(1-sin30)/(1+sin30)]2
= 1.77m
71
72
6.2 DESIGN OF COLUMN
Pu =958.7 kN
Mx=9.56 kN-m
My=5.83 kN-m
Column size = 230x 600
M20 Fe415
Assume clear cover = 40 mm
Assume dia. Of main steel = 25 mm
Dia. Of link = 8mm
Therefore effective cover = 40+8+25/2 = 60.5 mm
Assume % of steel as p= 1.2%
Emin.x = L/500 + d/30
= 2929/500 + 600/30
=25.858 mm
Emin.y= 2929/500 + 230/30
= 13.525 mm = 20 (min.)
p/fck = 1.2/20 = 0.06
Pu/fckbd = 0.35
From clause 39.6 from pg. 71
Puz= 0.45fck.Ac + 0.75fy.Asc
(Ac = Ag-Ast; Ag=230*600)
= 1742.53 kN
Pu/Puz = 0.55
From pg. 71 clause no 39.6
αn= 1.6
For bending about X-axis
d’/d = 60.5/600 = 0.1008
Selecting appropriate chart from SP-16
Mu/fckbd2 = 0.07
73
Mu.x1 = 115.92 kN-m
For bending about Y-axis
d’/d = 60.5/230 =0.263
Selecting chart from SP-16
Mu/fckbd2 = 0.1
Mu.y1= 63.48 kN-m
(Mu.x/Mu.x1)αn + (Mu.y/Mu.y1)αn < 1
= 0.041 < 1
Hence the assumed column size and % of steel are O.K.
Reinforcement
Asc = 860 mm2
Assuming 12 mm bars,
Hence Provide 8- 12 mm bars
Lateral ties
Provide lateral ties of dia 8 mm
Provide 8mm# bars @ 250mm c/c
74
75
76
6.3 DESIGN OF BEAMS
L1= Length of the beam B1= 3.61mL2= Length of the beam B2= 3.67mL3= Length of the beam B3= 2.5mL4= Length of the beam B4= 3.61mL5= Length of the beam B5= 3.67m
DATA:Live load on slab =2kN/m2
Floor finishes= 1.5kN/m2
Self weight of slab= 0.125*25= 3.125kN/m2
Cross section of beam= 230*360mmSelf weight of beam= 0.23*0.6*25= 3.45kN/mInternal wall weight= 0.115*19*(3.05-0.3)= 6.009kN/mTotal triangular dead load on slab= 3.125+1.5= 4.625kN/m2
Total live load= 2kN/m2
Beam B1:UD live load= (W*Lx)/3 = (2*3.61)/3= 2.41kN/mTotal UD live load= 2*2.41= 4.82kN/m [load is acting from two slabs on the beam since we have to multiply with 2].Total UD live load approximately= 4.82kN/m.Converting triangular load to uniformly distributed load= (W*Lx)/3 Triangular dead load to UD load= (W*Lx)/3 = (2*(4.625*3.61))/3 = 11.13kN/m.Total dead load= 11.13+6.009+3.45 = 20.59kN/m.L.L= 4.82kN/m and D.L= 20.59kN/m.
Beam B2:UD live load= (W*Lx)/3 = (2*3.67)/3= 2.45kN/mTotal UD live load= 2*2.45= 4.9kN/m [load is acting from two slabs on the beam since we have to multiply with 2].Converting triangular load to uniformly distributed load= (W*Lx)/3 Triangular dead load to UD load= (W*Lx)/3 = (2*(4.625*3.67))/3 = 11.31kN/m.Total dead load= 11.31+6.009+3.45 = 20.77kN/m.L.L= 4.9kN/m and D.L= 20.77kN/m.
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Beam B3:UD live load= (W*Lx)/3 = (2*2.5)/3= 1.67kN/mTotal UD live load= 2*1.67= 3.34kN/m [load is acting from two slabs on the beam since we have to multiply with 2].Converting triangular load to uniformly distributed load= (W*Lx)/3 Triangular dead load to UD load= (W*Lx)/3 = (2*(4.625*2.5))/3 = 7.71kN/m.Total dead load= 7.71+6.009+3.45 = 17.17kN/m.L.L= 3.34kN/m and D.L= 17.17kN/m.
Beam B4:UD live load= (W*Lx)/3 = (2*3.61)/3= 2.41kN/mTotal UD live load= 2*2.41= 4.82kN/m [load is acting from two slabs on the beam since we have to multiply with 2].Converting triangular load to uniformly distributed load= (W*Lx)/3 Triangular dead load to UD load= (W*Lx)/3 = (2*(4.625*3.61))/3 = 11.13kN/m.Total dead load= 11.13+6.009+3.45 = 20.59kN/m.L.L= 4.82kN/m and D.L= 20.59kN/m.
Beam B5:UD live load= (W*Lx)/3 = (2*3.67)/3= 2.45kN/mTotal UD live load= 2*2.45= 4.9kN/m [load is acting from two slabs on the beam since we have to multiply with 2].Converting triangular load to uniformly distributed load= (W*Lx)/3 Triangular dead load to UD load= (W*Lx)/3 = (2*(4.625*3.67))/3 = 11.31kN/m.Total dead load= 11.31+6.009+3.45 = 20.77kN/m.L.L= 4.9kN/m and D.L= 20.77kN/m.
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MOMENT AND SHEAR COEFFICIENTS:
MOMENT COEFFICIENTS
DL αd 0 1/12 -1/10 1/16 -1/12 1/16 -1/12 1/16 -1/10 1/12 0LL αl 0 1/10 -1/9 1/12 -1/9 1/12 -1/9 1/12 -1/9 1/10 0
SHEAR COEFFICIENTS:
DL αd 0.4 0.6 0.55 0.5 0.5 0.5 0.5 0.6 0.55 0.4LL αl 0.45 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.6 0.45
MOMENTS OF SPAN AB:Live load, wl= 4.82kN/m.Dead load,wd= 20.59kN/m.Moment= [(1/10)*wl*l2] + [(1/12)*wd*l2] = [(1/10)*4.82*(3.61)2] + [(1/12)*20.59*(3.61)2] = 28.64kN-m.Moment of support ‘B’ , = [(-1/9)*wl*l2] + [(-1/10)*wd*l2] = [(-1/9)*4.82*(3.61)2] + [(-1/10)*20.59*(3.61)2] = 33.81kN-m.MOMENTS OF SPAN BC:Live load, wl= 4.9kN/m.Dead load,wd= 20.77kN/m.Moment= [(1/10)*wl*l2] + [(1/12)*wd*l2] = [(1/10)*4.9*(3.67)2] + [(1/12)*20.77*(3.67)2] = 29.91kN-m.Moment of support ‘C’ , = [(-1/9)*wl*l2] + [(-1/10)*wd*l2] = [(-1/9)*4.9*(3.67)2] + [(-1/10)*20.77*(3.67)2] = 35.3kN-m.MOMENTS OF SPAN CD:Live load, wl= 3.34kN/m.Dead load,wd= 17.17kN/m.Moment= [(1/10)*wl*l2] + [(1/12)*wd*l2] = [(1/10)*3.34*(2.5)2] + [(1/12)*17.17*(2.5)2] = 11.02kN-m.Moment of support ‘C’ , = [(-1/9)*wl*l2] + [(-1/10)*wd*l2] = [(-1/9)*3.34*(2.5)2] + [(-1/10)*17.17*(2.5)2] = 13.05kN-m.
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MOMENTS OF SPAN DE:Live load, wl= 4.82kN/m.Dead load,wd= 20.59kN/m.Moment= [(1/10)*wl*l2] + [(1/12)*wd*l2] = [(1/10)*4.82*(3.61)2] + [(1/12)*20.59*(3.61)2] = 28.64kN-m.Moment of support ‘D’ , = [(-1/9)*wl*l2] + [(-1/10)*wd*l2] = [(-1/9)*4.82*(3.61)2] + [(-1/10)*20.59*(3.61)2] = 33.81kN-m.
MOMENTS OF SPAN EF:Live load, wl= 4.9kN/m.Dead load,wd= 20.77kN/m.Moment= [(1/10)*wl*l2] + [(1/12)*wd*l2] = [(1/10)*4.9*(3.67)2] + [(1/12)*20.77*(3.67)2] = 29.91kN-m.Moment of support ‘E’ , = [(-1/9)*wl*l2] + [(-1/10)*wd*l2] = [(-1/9)*4.9*(3.67)2] + [(-1/10)*20.77*(3.67)2] = 35.3kN-m.SUPPORT SHEAR FORCES:A, B, C, D, E and F are the supports of the continuous beam.Support A:Shear force= [(0.4*wd) + (0.45*wl)] * L = [(0.4*20.59) + (0.45*4.82)] * 3.61 = 37.54kN.Support B(outer side):Shear force= [(0.6*wd) + (0.6*wl)] * L = [(0.6*20.59) + (0.6*4.82)] * 3.61 = 55.01kN.Support B(inner side):Shear force= [(0.55*wd) + (0.6*wl)] * L = [(0.55*20.77) + (0.6*4.9)] * 3.67 = 52.7kN.Support C(outer side):Shear force= [(0.5*wd) + (0.6*wl)] * L = [(0.5*20.77) + (0.6*4.9)] * 3.67 = 48.8kNSupport C(inner side):Shear force= [(0.5*wd) + (0.6*wl)] * L = [(0.5*17.17) + (0.6*3.34)] * 2.5 = 26.45kN.
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Support D(outer side):Shear force= [(0.5*wd) + (0.6*wl)] * L = [(0.5*17.17) + (0.6*3.34)] * 2.5 = 26.45kN.Support D(inner side):Shear force= [(0.5*wd) + (0.6*wl)] * L = [(0.5*20.59) + (0.6*4.82)] * 3.61 = 47.65kN.Support E(outer side):Shear force= [(0.6*wd) + (0.6*wl)] * L = [(0.6*20.59) + (0.6*4.82)] * 3.61 = 55.05kN.Support E(inner side):Shear force= [(0.55*wd) + (0.6*wl)] * L = [(0.55*20.77) + (0.6*4.9)] * 3.67 = 52.7kN.Support F(outer side):Shear force= [(0.4*wd) + (0.45*wl)] * L = [(0.55*20.77) + (0.45*4.9)] * 3.67 = 38.55kN.Mulimit= 0.138 * fck* b * d2
= 0.138 * 20* 230 * (600-50)2 [cover=50] = 192.03kN-m.Maximum bending moment developed at the support of the beam= 29.91kN-m.Mulimit> Maximum bending moment.But we have to provide Ast for the maximum bending moment.Ast= (0.36* fck* b* Xumax)/(0.87* fy) = (0.36* 20* 230* 0.48* 550)/(0.87* 415) = 1210.86mm2.Additional steel for 29.92kN-m by a couple of Ast and Asc,Asc= M/[(fsc- fcc)* (d-d’)]d= effective depth= 550mmd’= effective cover= 50mmd’/d= 50/550 = 0.09Asc= (29.91*106)/[(352-(0.446*20)) * (550-50)] = 174.36mm2.From IS 456-2000, fsc for 0.09 is 352Mpa. 0.87* 415* Ast2= fsc* Asc 0.87* 415* Ast2 = 352* 174.36 Ast2= 170mm2.The maximum positive bending moment for span EF is 29.91kN-m.The maximum positive bending moment for span DE is 28.64kN-m.According to IS 456-2000, clause 22.5, the average of the bending moments can be taken.
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i.e., (29.91+28.64)/2 = 29.275kN-m.for span DE and EF,Xu = (0.87* fy* Ast)/(0.36* fck* b) = (0.87* 415* Ast)/(0.36* 20* 230)Xu= 0.218* Ast29.275* 106= (0.87* 415* Ast) * [(550- (0.42* 0.218* Ast)]29.275* 106= [(361.05* Ast) * (550- (0.09* Ast))]29.275* 106= 198577.5*Ast- 32.49Ast2
Ast= 151.16mm2
Provide 2no’s of 16mm diameter bars.So, provide Ast= 2* 201 = 402mm2
In addition to this, provide 4no’s of 16mm diameter bars at the top.Total steel at top of the support is, = (4* 201) + (402) = 1286mm2 > 1210.86mm2.Maximum shear force at support E= 55.05kN.P= (100* Ast)/(b* d) = (100* 1286)/(230* 550) = 1.016Allowable shear stress for M20 grade of concrete is 0.62Mpa.Nominal shear stress= V/(bw* d) = (55.05* 103)/(230* 550) = 0.435Mpa.Nominal shear stress is less than design shear stress.Provide 8mm diameter 2legged stirrups @ 250mm c/c throughout.Spacing not more than 0.75*d = 0.75* 550 = 412.5mm.Provided spacing is within the limit Hence safe.
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6.4 DESIGN OF SLABS
DATA:
Slab NO:S1
Grade of concrete= M20
Grade of steel= Fe415
Dimensions : 3.93*5.25m
EFFECTIVE DEPTH OF SLAB:
Assuming overall depth of slab= 125mm
Let effective cover of slab= 20mm
Effective depth of slab= 105mm
EFFECTIVE SPAN OF THE SLAB:
As per clause no.22.2 (b) of IS: 456-2000, if the width of the support is
less than 1/12 of clear span, the effective span shall be
Clear span + effective depth of slab
(OR) } whichever is less
Clear span + c/c of supports
Effective span in short direction:
3930/12= 327.5 > 230mm
3.93 + 0.1= 4.03m
3.93 + 0.23= 4.16m
Lx= 4.03m
Effective span in long direction:
5250/12= 437.5 > 230mm
5.25 + 0.1= 5.35m
5.25 + 0.23= 5.48m
Ly= 5.35m
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Aspect ratio= Ly/Lx= 5.35/4.03= 1.33 (<2)
Hence the slab is designed as two-way slab with two adjacent
edges discontinuous
The bending moment coefficients from table.26 of IS: 456-2000 as follows
αx αy
-ve moment at continuous edge 0.067 0.047
+ve moment at mid span 0.051 0.035
LOADS ON SLABS:
Considering unit weight of slab= 25
Dead load= 4.375 kN/m2
Live load= 2kN/m2
Total load= 6.375kN/m2
Factored load intensity= Wu= 6.375*1.5= 9.56kN/m2
CALCULATION OF BENDING MOMENT:
Short span direction
-ve moment at continuous edge= αX w LX2
= 0.067*9.56*4.03*4.03
= 10.4 kN-m
+ve moment at mid span= αX w LX2
= 0.051*9.56*4.03*4.03
= 7.92 kN-m
Long span direction
-ve moment at continuous edge= αy w Lx2
= 0.047*9.56*4.03*4.03
= 7.3kN-m
+ve moment at mid span= αy w Lx 2
84
= 0.035*9.56*4.03*4.03
= 5.43 kN-m
CHECK FOR DEPTH:
M= 0.138*fkc*b*d2
10.4X106= 0.138X20X1000Xd2
d= 62mm
Overall depth required= 62 + 25= 87mm
Overall depth provided= 125mm
Hence, satisfied
Dx= 125-25-8/2= 96mm
Dy= 125-25-8-8/2= 88mm
CALCULATION OF STEEL:
Mu= 0.87*fy*Ast*d*(1-((Ast*fy)/(b*d*fck)))
Short span
Ast –ve= 310mm2
Ast +ve= 230mm2
Long span
Ast –ve= 210mm2
Ast +ve= 155mm2
Minimum steel @ 0.12%= (0.12/100)*1000*125
= 150mm2
Use 8mm diameter bars
Aø= (3.14/4)*82= 50.26mm2
SHORT SPAN:
Spacing s1= (Aø /Ast )*1000
= (50.26/307.69)*1000
85
= 160mm
S2= 210mm
LONG SPAN:
S3= 230mm
S4= 320
Dx = 125-25-(8/2)
= 96mm
Dy= Dx-8
= 88mm
Maximum spacing Sx= 3d or 300mm
= 3*96 or 300mm
= 288 or 300mm
Sy= 3*88 or 300mm
= 264 or 300mm
Select whichever is less
Therefore, Sx =280mm
Sy =250mm
TORSIONAL REINFORCEMENT:
Torsional steel= (3/4)*Ast max
= 230mm2
Use 6mm diameter bars
Spacing= (28.3/230)*1000
= 120mm
use 6mm diameter bars @ 120mm c/c spacing
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CHECK FOR STIFFNESS:
fs= 0.58*fy*(Ast req/Ast prov)
IS 456-2000
Modification factor, k= 2.24
Allowable l/d= 26*2.24
= 58.24mm
Actual l/d= 4030/100
= 40.3mm
Hence satisfied
87
DATA:
Slab NO:S2Grade of concrete= M20Grade of steel= Fe415Dimensions : 3.05*3.93m
EFFECTIVE DEPTH OF SLAB:Assuming overall depth of slab= 125mmLet effective cover of slab= 20mmEffective depth of slab= 105mm
EFFECTIVE SPAN OF THE SLAB:As per clause no.22.2 (b) of IS: 456-2000, if the width of the support is less than 1/12 of clear span, the effective span shall be
Clear span + effective depth of slab (OR) } whichever is lessClear span + c/c of supportsEffective span in short direction: 3050/12= 327.5 > 230mm 3.05 + 0.1= 3.15m 3.05 + 0.23= 3.28m Lx= 3.15mEffective span in long direction: 3930/12= 327.5 > 230mm 3.93 + 0.1= 4.03m 3.93 + 0.23= 4.16m Ly= 4.03mAspect ratio= Ly/Lx= 4.03/3.15= 1.28 (<2)Hence the slab is designed as two-way slab with two adjacentedges discontinuousThe bending moment coefficients from table.26 of IS: 456-2000 as follows αx αy-ve moment at continuous edge 0.05 0.037+ve moment at mid span 0.037 0.028
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LOADS ON SLABS:Considering unit weight of slab= 25
Dead load= 4.375 kN/m2Live load= 2kN/m2Total load= 6.375kN/m2Factored load intensity= Wu= 6.375*1.5= 9.56kN/m2CALCULATION OF BENDING MOMENT:Short span direction-ve moment at continuous edge= αx w Lx^2 = 0.05*9.56*3.152
= 4.74 kN-m+ve moment at mid span= αx w Lx^2 = 0.037*9.56*3.152
= 3.5 kN-mLong span direction-ve moment at continuous edge= αy w Lx^2 = 0.037*9.56*3.152
= 3.5kN-m+ve moment at mid span= αy w Lx^2 = 0.028*9.56*3.152
= 2.66 kN-mCHECK FOR DEPTH: M= 0.138*fkc*b*d^2 4.74*10^6= 0.138*20*1000*d^2 d= 42mmOverall depth required= 42 + 25= 67mmOverall depth provided= 125mm Hence, satisfied Dx= 125-25-8/2= 96mm Dy= 125-25-8-8/2= 88mmCALCULATION OF STEEL:Mu= 0.87*fy*Ast*d*(1-((Ast*fy)/(b*d*fck)))Short spanAst –ve= 135mm2Ast +ve= 100mm2Long spanAst –ve= 100mm2Ast +ve= 75mm2
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Minimum steel @ 0.12%= (0.12/100)*1000*125 = 150mm2Use 8mm diameter barsAø= (3.14/4)*64= 50.26mm2SHORT SPAN:Spacing s1= (Aø/Ast )*1000 = (50.26/135)*1000= 380mmS2= 510mmLONG SPAN:S3= 510mmS4= 670mmDx = 125-25-(8/2)= 96mmDy= Dx-8= 88mmMaximum spacing Sx= 3d or 300mm = 3*96 or 300mm = 288 or 300mm Sy= 3*88 or 300mm = 264 or 300mm Select whichever is less Therefore, Sx =280mm Sy =250mmTORSIONAL REINFORCEMENT: Torsional steel= (3/4)*Ast max = 102mm2 Use 6mm diameter barsSpacing= (28.27/102)*1000 = 300mm use 8mm diameter bars @ 300mm c/c spacing CHECK FOR STIFFNESS: fs= 0.58*fy*(Ast req/Ast prov) IS 456-2000 Modification factor, k= 2.24 Allowable l/d = 26*2.24 = 58.24mmActual l/d= 3150/10 = 31.5mm Hence satisfied
90
DATA:
Slab NO:S3
Grade of concrete= M20
Grade of steel= Fe415
Dimensions : 3.35*5.5m
EFFECTIVE DEPTH OF SLAB:
Assuming overall depth of slab= 125mm
Let effective cover of slab= 25mm
Effective depth of slab= 100mm
EFFECTIVE SPAN OF THE SLAB:
As per clause no.22.2 (b) of IS: 456-2000, if the width of the support is
less than 1/12 of clear span, the effective span shall be
Clear span + effective depth of slab
(OR) } whichever is less
Clear span + c/c of supports
Effective span in short direction:
3350/12= 279.1 > 230mm
3.35 + 0.1= 3.45m
3.35 + 0.23= 3.58m
Lx= 3.58m
Effective span in long direction:
5500/12= 458.3 > 230mm
5.5 + 0.1= 5.6m
5.5 + 0.23= 5.73m
Ly= 5.73m
Aspect ratio= Ly/Lx= 5.73/3.58= 1.6 (<2)
Hence the slab is designed as two-way slab with two adjacent
91
edges discontinuous
The bending moment coefficients from table.26 of IS: 456-2000 as follows
αx αy
-ve moment at continuous edge 0.07 0.037
+ve moment at mid span 0.055 0.028
LOADS ON SLABS:
Considering unit weight of slab= 25
Dead load= 4.375 kN/Sqm
Live load= 2 kN/Sqm
Total load= 6.375 kN/Sqm
Factored load intensity= Wu= 6.375*1.5= 9.56kN/Sqm
CALCULATION OF BENDING MOMENT:
Short span direction
-ve moment at continuous edge= αx w Lx^2
= 0.07*9.56*3.58*3.58
= 7.96 kN-m
+ve moment at mid span= αx w Lx^2
= 0.055*9.56*3.58*3.58
= 6.25 kN-m
Long span direction
-ve moment at continuous edge= αy w Lx^2
= 0.037*9.56*3.58*3.58
= 4.21kN-m
+ve moment at mid span= αy w Lx*2
= 0.035*9.56*3.58*3.58
= 3.18 kN-m
CHECK FOR DEPTH:
M= 0.138*fck*b*d^2
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7.96*10^6= 0.138*20*1000*d^2
d= 55mm
Overall depth required= 55 + 25= 80mm
Overall depth provided= 125mm
Hence, satisfied
Dx= 125-25-8/2= 96mm
Dy= 125-25-8-8/2= 88mm
CALCULATION OF STEEL:
Mu= 0.87*fy*Ast*d*(1-((Ast*fy)/(b*d*fck)))
Short span
Ast –ve= 240sqmm
Ast +ve= 180sqmm
Long span
Ast –ve= 120sqmm
Ast +ve= 90sqmm
Minimum steel @ 0.12%= (0.12/100)*1000*125
= 150mm2
Use 8mm diameter bars
Aø= (3.14/4)*82= 50.26mm2
SHORT SPAN:
Spacing s1= (Aø/Ast )*1000
= (50.26/236.02)*1000
= 200mm
S2= 250mm
LONG SPAN:
S3= 400mm
S4= 560mm
Dx = 125-25-(8/2)
= 96mm
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Dy= Dx-8
= 88mm
Maximum spacing Sx= 3d or 300mm
= 3*96 or 300mm
= 288 or 300mm
Sy= 3*88 or 300mm
= 264 or 300mm
Select whichever is less
Therefore, Sx =280mm
Sy =250mm
TORSIONAL REINFORCEMENT:
Torsional steel= (3/4)*Ast max
= 180mm2
Use 6mm diameter bars
Spacing= (28.3/180)*1000
= 160mm
use 6mm diameter bars @ 160mm c/c spacing
CHECK FOR STIFFNESS:
fs= 0.58*fy*(Ast req/Ast prov)
IS 456-2000
Modification factor, k= 2.24
Allowable l/d= 26*2.24
= 58.24mm
Actual l/d= 4030/100
= 40.3mm
Hence satisfied
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DESIGN OF ONE WAY SLAB:
Dimension= 17.06*2.40Overall depth= 125mmEffective cover= 20mmEffective depth= 125-20-(10/2) = 100mmLx= 2.40+0.1= 2.5mLy= 17.06+0.1= 17.16mAspect ratio= 17.16/2.5 = 6.86.> 2Hence, the slab is designed as one way slab.Loads on slabs:Total load= 6.375kN/m2
Factored load= 6.375*1.5 = 9.56 kN/m2
Bending moment:Maximum bending moment= wl2/10 = 5.98kN-mCheck for depth:M= 0.138*fck*bd2
5.98*106= 0.138*20*1000* d2
d= 46mmOverall depth required= 46+20= 66mmOverall depth provided= 125mm Hence satisfied.Calculation of steel:Main steel:Mu= 0.87*fy*Ast*d{1-[( Ast*fy)/(bd* fck)]} Ast= 172mm2
Minimum steel= (0.12/100)*1000*125 = 150mm2
Use 8mm diameter bars.Aø= (3.14*64)/4 = 50.26mm2 No. of bars= Ast/Aø = 4bars.
Spacing= 50.26/172
95
= 290mmmaximum spacing= 3d or 300mm = 3*100 or 300Therefore, provide 8mm ø bars at 230mm c/c spacing. Distribution steel:
Ast= (0.12/100)*1000*125 = 150mm2
Use 6mm diameter bars Spacing= 180mmTherefore, provide 6mm diameter bars at 180mm c/c spacing.Check for stiffness:fs= 0.58*fy*( Astrequired/ Astprovided) = 205Modification factoe,k= 1.6Allowable l/d= 26*1.6 = 41.6Actual l/d= 2500/125 = 20 Hence ok.
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DESIGN OF CANTILEVER SLAB:
Span, l= 1.6mEffective length= 1.56+(0.23/2) = 1.675mAssume d= 150mmLoads:Total load= 7kN/m2
Factored load= 7*1.5 = 10.5 kN/m2
Bending moment:Maximum bending moment= wl2/2 = 14.73kN-mCheck for depth:M= 0.138*fck*bd2
d= 75mmAssume effective cover= 20mmOverall depth required= 75+20= 95mmOverall depth provided= 150mm Hence satisfied.Main steel:Mu= 0.87*fy*Ast*d{1-[( Ast*fy)/(bd* fck)]} Ast= 425mm2mm2
Minimum steel= (0.12/100)*1000*125 = 150mm2
Use 8mm diameter bars.Aø= (3.14*64)/4 = 50.26mm2 No. of bars= Ast/Aø = 11bars.Spacing= 50.26/420 = 100mmMaximum spacing= 3d or 300mm = 3*100 or 300Therefore, provide 8mm ø bars at 100mm c/c spacing.
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Distribution steel:
Ast= (0.12/100)*1000*125 = 150mm2
Use 6mm diameter bars Spacing= 180mmTherefore, provide 6mm diameter bars at 180mm c/c spacing.Check for stiffness:fs= 0.58*fy*( Astrequired/ Astprovided) = 216.62Modification factoe,k= 1.6Allowable l/d= 7*1.6 = 11.2Actual l/d= 1675/150 = 11.16 Hence ok.
98
99
6.5 DESIGN OF DOG LEGGED STAIRCASE
Height between floors = 3050 mm
height of each flight = 3050/2 = 1525 mm
width of the wall = 230 mm
live load = 3 kN/m2
floor finish = 1 kN/m2
Preliminary design:
Raiser = 150 mm
Tread =b 270 mm
No. of raisers per flight = 1525/150 = 10
No .of treads = 10-1 = 9
Total going = 9x270 = 2340 mm
Width of landing = 1 m
Width of staircase = 1.2 m
Design loads:
self weight = 0.15x25 = 3.75 kN/m2
Floor finish = 1 kN/m2
Live load = 3 kN/m 2
Total load = 7.75 kN/m2
Design load = 1.5x 7.75 = 11.63 kN/m2
Leff = 2500=2x75 =2650 mm
Flight design:
Dimensions = 1.2m x 2.86m
Overall depth of slab = 115 mm
Cover = 20 mm
Eff. Depth = 115-20-10/2 = 90 mm
100
Ly/Lx = 2.38 > 2
Main steel::
B.M. = Wl2/8 =(11.63*1.22)/8
=2.09 kN-m
Mu = 0.87*fy*Ast*d (1-(Ast*fy/b*d*ck))
Ast = 65.3 mm2
Min. steel = .12%bd = 120 mm2
Use 8mm bars
Spacing = 50.26*1000/120 = 418 mm
Max. spacing = 3d or 300 mm
=270 mm
Provide 8 mm bars @ 240 mm c/c
Distribution steel:
Ast = 0.12%bd= 120 mm2
use 6 mm bars
Spacing = 28.27*1000/120
=235 mm
Provide 6 mm bars @ 230 mm c/c
Check for stiffness:
Basic l/d = 26
Pt = Ast*100/bd
= 0.12%
K=2
Allowble l/d = 26*2 = 52
Actual l/d = 1200/90 = 13.33
Hence satisfied.
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7.1 STAAD INPUT
STATIC EQUIVALENT METHOD
STAAD SPACESTART JOB INFORMATIONENGINEER DATE 26-Dec-08END JOB INFORMATIONINPUT WIDTH 79UNIT METER KNJOINT COORDINATES1 -0.28 0 10.74; 2 3.65 0 10.74; 3 7 0 10.74; 4 -0.28 0 5.49; 5 3.65 0 5.49;6 7 0 5.49; 7 -0.28 0 2.44; 8 3.65 0 2.44; 9 3.65 0 0; 10 -0.28 0 0; 11 7 0 0;12 7 0 2.44; 13 -0.28 -1.25 10.74; 14 -0.28 -1.25 5.49; 15 -0.28 -1.25 2.44;16 -0.28 -1.25 0; 17 3.65 -1.25 10.74; 18 3.65 -1.25 5.49; 19 3.65 -1.25 2.44;20 3.65 -1.25 0; 21 7 -1.25 10.74; 22 7 -1.25 5.49; 23 7 -1.25 2.44;24 7 -1.25 0; 25 9.5 0 10.74; 26 13.43 0 10.74; 27 16.78 0 10.74;28 9.5 0 5.49; 29 13.43 0 5.49; 30 16.78 0 5.49; 31 9.5 0 2.44;32 13.43 0 2.44; 33 13.43 0 0; 34 9.5 0 0; 35 16.78 0 0; 36 16.78 0 2.44;37 9.5 -1.25 10.74; 38 9.5 -1.25 5.49; 39 9.5 -1.25 2.44; 40 9.5 -1.25 0;41 13.43 -1.25 10.74; 42 13.43 -1.25 5.49; 43 13.43 -1.25 2.44;44 13.43 -1.25 0; 45 16.78 -1.25 10.74; 46 16.78 -1.25 5.49;47 16.78 -1.25 2.44; 48 16.78 -1.25 0; 49 16.78 0 -2.4; 50 -0.28 0 -2.4;51 7 0 -2.4; 52 9.5 0 -2.4; 53 7 0 -8; 54 7 0 -11.48; 55 7 0 -14.88;56 -0.28 0 -14.88; 57 -0.28 0 -11.48; 58 -0.28 0 -8; 59 3.33 0 -8;60 3.33 0 -11.48; 61 3.33 0 -14.88; 62 -0.28 -1.25 -11.48; 63 -0.28 -1.25 -8;64 3.33 -1.25 -11.48; 65 3.33 -1.25 -8; 66 7 -1.25 -8; 67 7 -1.25 -11.48;68 -0.28 -1.25 -14.88; 69 3.33 -1.25 -14.88; 70 7 -1.25 -14.88; 71 16.78 0 -8;72 16.78 0 -11.48; 73 16.78 0 -14.88; 74 9.5 0 -14.88; 75 9.5 0 -11.48;76 9.5 0 -8; 77 13.11 0 -8; 78 13.11 0 -11.48; 79 13.11 0 -14.88;80 9.5 -1.25 -11.48; 81 9.5 -1.25 -8; 82 13.11 -1.25 -11.48; 83 13.11 -1.25 -8;84 16.78 -1.25 -8; 85 16.78 -1.25 -11.48; 86 9.5 -1.25 -14.88;87 13.11 -1.25 -14.88; 88 16.78 -1.25 -14.88; 89 3.33 0 -2.4; 92 13.11 0 -2.4;93 -0.28 -1.25 -2.4; 94 7 -1.25 -2.4; 95 9.5 -1.25 -2.4; 96 16.78 -1.25 -2.4;97 3.33 -1.25 -2.4; 98 13.11 -1.25 -2.4; 99 3.33 0 -16.44;100 3.33 -1.25 -16.44; 101 13.11 0 -16.44; 102 13.11 -1.25 -16.44;103 -0.28 3.05 10.74; 104 3.65 3.05 10.74; 105 7 3.05 10.74;106 -0.28 3.05 5.49; 107 3.65 3.05 5.49; 108 7 3.05 5.49; 109 -0.28 3.05 2.44;110 3.65 3.05 2.44; 111 3.65 3.05 0; 112 -0.28 3.05 0; 113 7 3.05 0;114 7 3.05 2.44; 115 9.5 3.05 10.74; 116 13.43 3.05 10.74;117 16.78 3.05 10.74; 118 9.5 3.05 5.49; 119 13.43 3.05 5.49;120 16.78 3.05 5.49; 121 9.5 3.05 2.44; 122 13.43 3.05 2.44; 123 13.43 3.05 0;124 9.5 3.05 0; 125 16.78 3.05 0; 126 16.78 3.05 2.44; 127 16.78 3.05 -2.4;128 -0.28 3.05 -2.4; 129 7 3.05 -2.4; 130 9.5 3.05 -2.4; 131 7 3.05 -8;
102
132 7 3.05 -11.48; 133 7 3.05 -14.88; 134 -0.28 3.05 -14.88;135 -0.28 3.05 -11.48; 136 -0.28 3.05 -8; 137 3.33 3.05 -8;138 3.33 3.05 -11.48; 139 3.33 3.05 -14.88; 140 16.78 3.05 -8;141 16.78 3.05 -11.48; 142 16.78 3.05 -14.88; 143 9.5 3.05 -14.88;144 9.5 3.05 -11.48; 145 9.5 3.05 -8; 146 13.11 3.05 -8; 147 13.11 3.05 -11.48;148 13.11 3.05 -14.88; 149 3.33 3.05 -2.4; 150 13.11 3.05 -2.4;151 3.33 3.05 -16.44; 152 13.11 3.05 -16.44; 153 -0.28 6.1 10.74;154 3.65 6.1 10.74; 155 7 6.1 10.74; 156 -0.28 6.1 5.49; 157 3.65 6.1 5.49;158 7 6.1 5.49; 159 -0.28 6.1 2.44; 160 3.65 6.1 2.44; 161 3.65 6.1 0;162 -0.28 6.1 0; 163 7 6.1 0; 164 7 6.1 2.44; 165 9.5 6.1 10.74;166 13.43 6.1 10.74; 167 16.78 6.1 10.74; 168 9.5 6.1 5.49; 169 13.43 6.1 5.49;170 16.78 6.1 5.49; 171 9.5 6.1 2.44; 172 13.43 6.1 2.44; 173 13.43 6.1 0;174 9.5 6.1 0; 175 16.78 6.1 0; 176 16.78 6.1 2.44; 177 16.78 6.1 -2.4;178 -0.28 6.1 -2.4; 179 7 6.1 -2.4; 180 9.5 6.1 -2.4; 181 7 6.1 -8;182 7 6.1 -11.48; 183 7 6.1 -14.88; 184 -0.28 6.1 -14.88; 185 -0.28 6.1 -11.48;186 -0.28 6.1 -8; 187 3.33 6.1 -8; 188 3.33 6.1 -11.48; 189 3.33 6.1 -14.88;190 16.78 6.1 -8; 191 16.78 6.1 -11.48; 192 16.78 6.1 -14.88;193 9.5 6.1 -14.88; 194 9.5 6.1 -11.48; 195 9.5 6.1 -8; 196 13.11 6.1 -8;197 13.11 6.1 -11.48; 198 13.11 6.1 -14.88; 199 3.33 6.1 -2.4;200 13.11 6.1 -2.4; 201 3.33 6.1 -16.44; 202 13.11 6.1 -16.44;203 -0.28 9.15 10.74; 204 3.65 9.15 10.74; 205 7 9.15 10.74;206 -0.28 9.15 5.49; 207 3.65 9.15 5.49; 208 7 9.15 5.49; 209 -0.28 9.15 2.44;210 3.65 9.15 2.44; 211 3.65 9.15 0; 212 -0.28 9.15 0; 213 7 9.15 0;214 7 9.15 2.44; 215 9.5 9.15 10.74; 216 13.43 9.15 10.74;217 16.78 9.15 10.74; 218 9.5 9.15 5.49; 219 13.43 9.15 5.49;220 16.78 9.15 5.49; 221 9.5 9.15 2.44; 222 13.43 9.15 2.44; 223 13.43 9.15 0;224 9.5 9.15 0; 225 16.78 9.15 0; 226 16.78 9.15 2.44; 227 16.78 9.15 -2.4;228 -0.28 9.15 -2.4; 229 7 9.15 -2.4; 230 9.5 9.15 -2.4; 231 7 9.15 -8;232 7 9.15 -11.48; 233 7 9.15 -14.88; 234 -0.28 9.15 -14.88;235 -0.28 9.15 -11.48; 236 -0.28 9.15 -8; 237 3.33 9.15 -8;238 3.33 9.15 -11.48; 239 3.33 9.15 -14.88; 240 16.78 9.15 -8;241 16.78 9.15 -11.48; 242 16.78 9.15 -14.88; 243 9.5 9.15 -14.88;244 9.5 9.15 -11.48; 245 9.5 9.15 -8; 246 13.11 9.15 -8; 247 13.11 9.15 -11.48;248 13.11 9.15 -14.88; 249 3.33 9.15 -2.4; 250 13.11 9.15 -2.4;251 3.33 9.15 -16.44; 252 13.11 9.15 -16.44; 253 -0.28 12.2 10.74;254 3.65 12.2 10.74; 255 7 12.2 10.74; 256 -0.28 12.2 5.49; 257 3.65 12.2 5.49;258 7 12.2 5.49; 259 -0.28 12.2 2.44; 260 3.65 12.2 2.44; 261 3.65 12.2 0;262 -0.28 12.2 0; 263 7 12.2 0; 264 7 12.2 2.44; 265 9.5 12.2 10.74;266 13.43 12.2 10.74; 267 16.78 12.2 10.74; 268 9.5 12.2 5.49;269 13.43 12.2 5.49; 270 16.78 12.2 5.49; 271 9.5 12.2 2.44;272 13.43 12.2 2.44; 273 13.43 12.2 0; 274 9.5 12.2 0; 275 16.78 12.2 0;276 16.78 12.2 2.44; 277 16.78 12.2 -2.4; 278 -0.28 12.2 -2.4; 279 7 12.2 -2.4;280 9.5 12.2 -2.4; 281 7 12.2 -8; 282 7 12.2 -11.48; 283 7 12.2 -14.88;284 -0.28 12.2 -14.88; 285 -0.28 12.2 -11.48; 286 -0.28 12.2 -8;
103
287 3.33 12.2 -8; 288 3.33 12.2 -11.48; 289 3.33 12.2 -14.88;290 16.78 12.2 -8; 291 16.78 12.2 -11.48; 292 16.78 12.2 -14.88;293 9.5 12.2 -14.88; 294 9.5 12.2 -11.48; 295 9.5 12.2 -8; 296 13.11 12.2 -8;297 13.11 12.2 -11.48; 298 13.11 12.2 -14.88; 299 3.33 12.2 -2.4;300 13.11 12.2 -2.4; 301 3.33 12.2 -16.44; 302 13.11 12.2 -16.44;303 -0.28 15.25 10.74; 304 3.65 15.25 10.74; 305 7 15.25 10.74;306 -0.28 15.25 5.49; 307 3.65 15.25 5.49; 308 7 15.25 5.49;309 -0.28 15.25 2.44; 310 3.65 15.25 2.44; 311 3.65 15.25 0; 312 -0.28 15.25 0;313 7 15.25 0; 314 7 15.25 2.44; 315 9.5 15.25 10.74; 316 13.43 15.25 10.74;317 16.78 15.25 10.74; 318 9.5 15.25 5.49; 319 13.43 15.25 5.49;320 16.78 15.25 5.49; 321 9.5 15.25 2.44; 322 13.43 15.25 2.44;323 13.43 15.25 0; 324 9.5 15.25 0; 325 16.78 15.25 0; 326 16.78 15.25 2.44;327 16.78 15.25 -2.4; 328 -0.28 15.25 -2.4; 329 7 15.25 -2.4;330 9.5 15.25 -2.4; 331 7 15.25 -8; 332 7 15.25 -11.48; 333 7 15.25 -14.88;334 -0.28 15.25 -14.88; 335 -0.28 15.25 -11.48; 336 -0.28 15.25 -8;337 3.33 15.25 -8; 338 3.33 15.25 -11.48; 339 3.33 15.25 -14.88;340 16.78 15.25 -8; 341 16.78 15.25 -11.48; 342 16.78 15.25 -14.88;343 9.5 15.25 -14.88; 344 9.5 15.25 -11.48; 345 9.5 15.25 -8;346 13.11 15.25 -8; 347 13.11 15.25 -11.48; 348 13.11 15.25 -14.88;349 3.33 15.25 -2.4; 350 13.11 15.25 -2.4; 351 3.33 15.25 -16.44;352 13.11 15.25 -16.44;MEMBER INCIDENCES1 1 2; 2 3 2; 3 1 4; 4 4 5; 5 5 6; 6 4 7; 8 8 9; 9 10 9; 10 7 10; 11 9 11;12 6 12; 13 8 5; 14 2 5; 15 3 6; 16 1 13; 17 4 14; 18 12 11; 19 7 15; 20 10 16;21 2 17; 22 5 18; 23 8 19; 24 9 20; 25 3 21; 26 6 22; 27 12 23; 28 11 24;29 25 26; 30 27 26; 31 25 28; 32 28 29; 33 29 30; 34 28 31; 36 32 33; 37 34 33;38 31 34; 39 33 35; 40 30 36; 41 32 29; 42 26 29; 43 27 30; 44 25 37; 45 28 38;46 36 35; 47 31 39; 48 34 40; 49 26 41; 50 29 42; 51 32 43; 52 33 44; 53 27 45;54 30 46; 55 36 47; 56 35 48; 57 11 34; 58 49 35; 59 50 10; 62 53 54; 63 54 55;64 56 57; 65 58 57; 66 58 59; 67 59 53; 70 61 60; 71 60 59; 72 57 62; 73 58 63;74 60 64; 75 59 65; 76 66 53; 77 54 67; 78 55 61; 79 61 56; 80 56 68; 81 61 69;82 55 70; 83 71 72; 84 72 73; 85 74 75; 86 76 75; 87 76 77; 88 77 71; 91 79 78;92 78 77; 93 75 80; 94 76 81; 95 78 82; 96 77 83; 97 84 71; 98 72 85; 99 73 79;100 79 74; 101 74 86; 102 79 87; 103 73 88; 104 50 58; 105 89 59; 108 92 77;109 49 71; 110 50 93; 111 51 94; 112 50 89; 113 89 51; 114 52 95; 115 49 96;116 52 92; 117 92 49; 118 89 97; 119 92 98; 120 51 52; 122 99 100; 123 101 102;125 51 53; 126 52 76; 127 103 104; 128 105 104; 129 103 106; 130 106 107;131 107 108; 132 106 109; 133 109 110; 134 110 111; 135 112 111; 136 109 112;137 111 113; 138 108 114; 139 110 107; 140 104 107; 141 105 108; 142 103 1;143 106 4; 144 114 113; 145 109 7; 146 112 10; 147 104 2; 148 107 5; 149 110 8;150 111 9; 151 105 3; 152 108 6; 153 114 12; 154 113 11; 155 115 116;156 117 116; 157 115 118; 158 118 119; 159 119 120; 160 118 121; 161 121 122;162 122 123; 163 124 123; 164 121 124; 165 123 125; 166 120 126; 167 122 119;168 116 119; 169 117 120; 170 115 25; 171 118 28; 172 126 125; 173 121 31;
104
174 124 34; 175 116 26; 176 119 29; 177 122 32; 178 123 33; 179 117 27;180 120 30; 181 126 36; 182 125 35; 183 113 124; 184 127 125; 185 128 112;186 113 129; 187 124 130; 188 131 132; 189 132 133; 190 134 135; 191 136 135;192 136 137; 193 137 131; 194 132 138; 195 138 135; 196 139 138; 197 138 137;198 135 57; 199 136 58; 200 138 60; 201 137 59; 202 53 131; 203 132 54;204 133 139; 205 139 134; 206 134 56; 207 139 61; 208 133 55; 209 140 141;210 141 142; 211 143 144; 212 145 144; 213 145 146; 214 146 140; 215 141 147;216 147 144; 217 148 147; 218 147 146; 219 144 75; 220 145 76; 221 147 78;222 146 77; 223 71 140; 224 141 72; 225 142 148; 226 148 143; 227 143 74;228 148 79; 229 142 73; 230 128 136; 231 149 137; 232 150 146; 233 127 140;234 128 50; 235 129 51; 236 128 149; 237 149 129; 238 130 52; 239 127 49;240 130 150; 241 150 127; 242 149 89; 243 150 92; 244 129 130; 245 139 151;246 151 99; 247 152 101; 248 148 152; 249 129 131; 250 130 145; 251 153 154;252 155 154; 253 153 156; 254 156 157; 255 157 158; 256 156 159; 257 159 160;258 160 161; 259 162 161; 260 159 162; 261 161 163; 262 158 164; 263 160 157;264 154 157; 265 155 158; 266 153 103; 267 156 106; 268 164 163; 269 159 109;270 162 112; 271 154 104; 272 157 107; 273 160 110; 274 161 111; 275 155 105;276 158 108; 277 164 114; 278 163 113; 279 165 166; 280 167 166; 281 165 168;282 168 169; 283 169 170; 284 168 171; 285 171 172; 286 172 173; 287 174 173;288 171 174; 289 173 175; 290 170 176; 291 172 169; 292 166 169; 293 167 170;294 165 115; 295 168 118; 296 176 175; 297 171 121; 298 174 124; 299 166 116;300 169 119; 301 172 122; 302 173 123; 303 167 117; 304 170 120; 305 176 126;306 175 125; 307 163 174; 308 177 175; 309 178 162; 310 163 179; 311 174 180;312 181 182; 313 182 183; 314 184 185; 315 186 185; 316 186 187; 317 187 181;318 182 188; 319 188 185; 320 189 188; 321 188 187; 322 185 135; 323 186 136;324 188 138; 325 187 137; 326 131 181; 327 182 132; 328 183 189; 329 189 184;330 184 134; 331 189 139; 332 183 133; 333 190 191; 334 191 192; 335 193 194;336 195 194; 337 195 196; 338 196 190; 339 191 197; 340 197 194; 341 198 197;342 197 196; 343 194 144; 344 195 145; 345 197 147; 346 196 146; 347 140 190;348 191 141; 349 192 198; 350 198 193; 351 193 143; 352 198 148; 353 192 142;354 178 186; 355 199 187; 356 200 196; 357 177 190; 358 178 128; 359 179 129;360 178 199; 361 199 179; 362 180 130; 363 177 127; 364 180 200; 365 200 177;366 199 149; 367 200 150; 368 179 180; 369 189 201; 370 201 151; 371 202 152;372 198 202; 373 179 181; 374 180 195; 375 203 204; 376 205 204; 377 203 206;378 206 207; 379 207 208; 380 206 209; 381 209 210; 382 210 211; 383 212 211;384 209 212; 385 211 213; 386 208 214; 387 210 207; 388 204 207; 389 205 208;390 203 153; 391 206 156; 392 214 213; 393 209 159; 394 212 162; 395 204 154;396 207 157; 397 210 160; 398 211 161; 399 205 155; 400 208 158; 401 214 164;402 213 163; 403 215 216; 404 217 216; 405 215 218; 406 218 219; 407 219 220;408 218 221; 409 221 222; 410 222 223; 411 224 223; 412 221 224; 413 223 225;414 220 226; 415 222 219; 416 216 219; 417 217 220; 418 215 165; 419 218 168;420 226 225; 421 221 171; 422 224 174; 423 216 166; 424 219 169; 425 222 172;426 223 173; 427 217 167; 428 220 170; 429 226 176; 430 225 175; 431 213 224;432 227 225; 433 228 212; 434 213 229; 435 224 230; 436 231 232; 437 232 233;
105
438 234 235; 439 236 235; 440 236 237; 441 237 231; 442 232 238; 443 238 235;444 239 238; 445 238 237; 446 235 185; 447 236 186; 448 238 188; 449 237 187;450 181 231; 451 232 182; 452 233 239; 453 239 234; 454 234 184; 455 239 189;456 233 183; 457 240 241; 458 241 242; 459 243 244; 460 245 244; 461 245 246;462 246 240; 463 241 247; 464 247 244; 465 248 247; 466 247 246; 467 244 194;468 245 195; 469 247 197; 470 246 196; 471 190 240; 472 241 191; 473 242 248;474 248 243; 475 243 193; 476 248 198; 477 242 192; 478 228 236; 479 249 237;480 250 246; 481 227 240; 482 228 178; 483 229 179; 484 228 249; 485 249 229;486 230 180; 487 227 177; 488 230 250; 489 250 227; 490 249 199; 491 250 200;492 229 230; 493 239 251; 494 251 201; 495 252 202; 496 248 252; 497 229 231;498 230 245; 499 253 254; 500 255 254; 501 253 256; 502 256 257; 503 257 258;504 256 259; 505 259 260; 506 260 261; 507 262 261; 508 259 262; 509 261 263;510 258 264; 511 260 257; 512 254 257; 513 255 258; 514 253 203; 515 256 206;516 264 263; 517 259 209; 518 262 212; 519 254 204; 520 257 207; 521 260 210;522 261 211; 523 255 205; 524 258 208; 525 264 214; 526 263 213; 527 265 266;528 267 266; 529 265 268; 530 268 269; 531 269 270; 532 268 271; 533 271 272;534 272 273; 535 274 273; 536 271 274; 537 273 275; 538 270 276; 539 272 269;540 266 269; 541 267 270; 542 265 215; 543 268 218; 544 276 275; 545 271 221;546 274 224; 547 266 216; 548 269 219; 549 272 222; 550 273 223; 551 267 217;552 270 220; 553 276 226; 554 275 225; 555 263 274; 556 277 275; 557 278 262;558 263 279; 559 274 280; 560 281 282; 561 282 283; 562 284 285; 563 286 285;564 286 287; 565 287 281; 566 282 288; 567 288 285; 568 289 288; 569 288 287;570 285 235; 571 286 236; 572 288 238; 573 287 237; 574 231 281; 575 282 232;576 283 289; 577 289 284; 578 284 234; 579 289 239; 580 283 233; 581 290 291;582 291 292; 583 293 294; 584 295 294; 585 295 296; 586 296 290; 587 291 297;588 297 294; 589 298 297; 590 297 296; 591 294 244; 592 295 245; 593 297 247;594 296 246; 595 240 290; 596 291 241; 597 292 298; 598 298 293; 599 293 243;600 298 248; 601 292 242; 602 278 286; 603 299 287; 604 300 296; 605 277 290;606 278 228; 607 279 229; 608 278 299; 609 299 279; 610 280 230; 611 277 227;612 280 300; 613 300 277; 614 299 249; 615 300 250; 616 279 280; 617 289 301;618 301 251; 619 302 252; 620 298 302; 621 279 281; 622 280 295; 623 303 304;624 305 304; 625 303 306; 626 306 307; 627 307 308; 628 306 309; 629 309 310;630 310 311; 631 312 311; 632 309 312; 633 311 313; 634 308 314; 635 310 307;636 304 307; 637 305 308; 638 303 253; 639 306 256; 640 314 313; 641 309 259;642 312 262; 643 304 254; 644 307 257; 645 310 260; 646 311 261; 647 305 255;648 308 258; 649 314 264; 650 313 263; 651 315 316; 652 317 316; 653 315 318;654 318 319; 655 319 320; 656 318 321; 657 321 322; 658 322 323; 659 324 323;660 321 324; 661 323 325; 662 320 326; 663 322 319; 664 316 319; 665 317 320;666 315 265; 667 318 268; 668 326 325; 669 321 271; 670 324 274; 671 316 266;672 319 269; 673 322 272; 674 323 273; 675 317 267; 676 320 270; 677 326 276;678 325 275; 679 313 324; 680 327 325; 681 328 312; 682 313 329; 683 324 330;684 331 332; 685 332 333; 686 334 335; 687 336 335; 688 336 337; 689 337 331;690 332 338; 691 338 335; 692 339 338; 693 338 337; 694 335 285; 695 336 286;696 338 288; 697 337 287; 698 281 331; 699 332 282; 700 333 339; 701 339 334;
106
702 334 284; 703 339 289; 704 333 283; 705 340 341; 706 341 342; 707 343 344;708 345 344; 709 345 346; 710 346 340; 711 341 347; 712 347 344; 713 348 347;714 347 346; 715 344 294; 716 345 295; 717 347 297; 718 346 296; 719 290 340;720 341 291; 721 342 348; 722 348 343; 723 343 293; 724 348 298; 725 342 292;726 328 336; 727 349 337; 728 350 346; 729 327 340; 730 328 278; 731 329 279;732 328 349; 733 349 329; 734 330 280; 735 327 277; 736 330 350; 737 350 327;738 349 299; 739 350 300; 740 329 330; 741 339 351; 742 351 301; 743 352 302;744 348 352; 745 329 331; 746 330 345;DEFINE MATERIAL STARTISOTROPIC CONCRETEE 2.17185e+007POISSON 0.17DENSITY 23.5616ALPHA 1e-005DAMP 0.05END DEFINE MATERIALMEMBER PROPERTY INDIAN16 17 19 TO 28 44 45 47 TO 56 72 TO 77 80 TO 82 93 TO 98 101 TO 103 110 111 -114 115 118 119 142 143 145 TO 154 170 171 173 TO 182 198 TO 203 206 TO 208 -219 TO 224 227 TO 229 234 235 238 239 242 243 266 267 269 TO 278 294 295 -297 TO 306 322 TO 327 330 TO 332 343 TO 348 351 TO 353 358 359 362 363 366 -367 390 391 393 TO 402 418 419 421 TO 430 446 TO 451 454 TO 456 467 TO 472 -475 TO 477 482 483 486 487 490 491 514 515 517 TO 526 542 543 545 TO 554 -570 TO 575 578 TO 580 591 TO 596 599 TO 601 606 607 610 611 614 615 638 639 -641 TO 650 666 667 669 TO 678 694 TO 699 702 TO 704 715 TO 720 723 TO 725 -730 731 734 735 738 739 PRIS YD 0.23 ZD 0.6122 123 246 247 370 371 494 495 618 619 742 743 PRIS YD 0.23 ZD 0.45MEMBER PROPERTY INDIAN127 TO 141 144 155 TO 169 172 183 TO 197 204 205 209 TO 218 225 226 -230 TO 233 236 237 240 241 244 245 248 TO 265 268 279 TO 293 296 307 TO 321 -328 329 333 TO 342 349 350 354 TO 357 360 361 364 365 368 369 372 TO 389 -392 403 TO 417 420 431 TO 445 452 453 457 TO 466 473 474 478 TO 481 484 485 -488 489 492 493 496 TO 513 516 527 TO 541 544 555 TO 569 576 577 581 TO 590 -597 598 602 TO 605 608 609 612 613 616 617 620 TO 637 640 651 TO 665 668 -679 TO 693 700 701 705 TO 714 721 722 726 TO 729 732 733 736 737 740 741 -744 TO 746 PRIS YD 0.56 ZD 0.23UNIT MMS NEWTONMEMBER PROPERTY INDIAN1 TO 6 8 TO 15 18 29 TO 34 36 TO 43 46 57 TO 59 62 TO 67 70 71 78 79 -83 TO 88 91 92 99 100 104 105 108 109 112 113 116 117 120 125 -126 PRIS YD 300 ZD 230UNIT METER KNCONSTANTSBETA 90 MEMB 22 50 74 75 81 95 96 102 122 123 148 176 200 201 207 221 222 -
107
228 246 247 272 300 324 325 331 345 346 352 370 371 396 424 448 449 455 469 -470 476 494 495 520 548 572 573 579 593 594 600 618 619 644 672 696 697 703 -717 718 724 742 743MATERIAL CONCRETE MEMB 1 TO 6 8 TO 34 36 TO 59 62 TO 67 70 TO 88 91 TO 105 -108 TO 120 122 123 125 TO 746SUPPORTS13 TO 24 37 TO 48 62 TO 70 80 TO 88 93 TO 98 100 102 FIXED*SEISMIC WEIGHTSDEFINE 1893 LOADZONE 0.1 RF 3 I 1 SS 1*CHECK SOFT STOREYSELFWEIGHTMEMBER WEIGHT*external walls= 0.23*(3.05-0.3)*19 = 12.0181 TO 3 6 10 12 15 18 29 TO 31 34 38 40 43 46 57 TO 59 62 TO 65 78 79 -83 TO 86 99 100 104 109 120 125 TO 129 132 136 138 141 144 155 TO 157 160 -164 166 169 172 183 TO 185 188 TO 191 204 205 209 TO 212 225 226 230 233 -244 249 TO 253 256 260 262 265 268 279 TO 281 284 288 290 293 296 -307 TO 309 312 TO 315 328 329 333 TO 336 349 350 354 357 368 373 TO 377 380 -384 386 389 392 403 TO 405 408 412 414 417 420 431 TO 433 436 TO 439 452 -453 457 TO 460 473 474 478 481 492 497 TO 501 504 508 510 513 516 -527 TO 529 532 536 538 541 544 555 TO 557 560 TO 563 576 577 581 TO 584 597 -598 602 605 616 621 622 UNI 12.018*internal walls= 0.115*(3.05-0.3)*14 = 6.0094 5 8 9 11 13 14 32 33 36 37 39 41 42 66 67 70 71 87 88 91 92 105 108 112 -113 116 117 130 131 133 TO 135 137 139 140 158 159 161 TO 163 165 167 168 -186 187 192 TO 194 196 197 213 TO 215 217 218 231 232 236 237 240 241 254 -255 257 TO 259 261 263 264 282 283 285 TO 287 289 291 292 310 311 -316 TO 318 320 321 337 TO 339 341 342 355 356 360 361 364 365 378 379 381 -382 TO 383 385 387 388 406 407 409 TO 411 413 415 416 434 435 440 TO 442 444 -445 461 TO 463 465 466 479 480 484 485 488 489 502 503 505 TO 507 509 511 -512 530 531 533 TO 535 537 539 540 558 559 564 TO 566 568 569 585 TO 587 -589 590 603 604 608 609 612 613 UNI 6.009* cantilever load 4.375*(length)1.56 = 6.82578 79 99 100 204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 -700 701 721 722 UNI 6.825*FLOOR WEIGHT*YRANGE 0 15 fLOAD 4.375*parapet wall=(thickness)0.23*(ht)0.75*19 = 3.2775623 TO 625 628 632 634 637 640 651 TO 653 656 660 662 665 668 679 TO 681 684 -685 TO 687 700 701 705 TO 708 721 722 726 729 740 745 746 UNI 3.2775*FROM CODEDEFINE WIND LOAD
108
TYPE 1INT 0 0 HEIG 10 15*EXP 0.9 YR 1 12.5LOAD 1 SEISMIC LOAD X DIRECTION1893 LOAD XLOAD 2 SEISMIC LOAD Z DIRECTION1893 LOAD ZLOAD 3 WL IN X DIRECTIONWIND LOAD X 1 TYPE 1LOAD 4 WL IN - X DIRECTIONWIND LOAD X -1 TYPE 1LOAD 5 WL IN Z DIRECTIONWIND LOAD Z 1 TYPE 1LOAD 6 WL IN - Z DIRECTIONWIND LOAD Z -1 TYPE 1*DEAD LOADLOAD 7 DLSELFWEIGHT Y -1*WALL LOADMEMBER LOAD1 TO 3 6 10 12 15 18 29 TO 31 34 38 40 43 46 57 TO 59 62 TO 65 78 79 -83 TO 86 99 100 104 109 120 125 TO 129 132 136 138 141 144 155 TO 157 160 -164 166 169 172 183 TO 185 188 TO 191 204 205 209 TO 212 225 226 230 233 -244 249 TO 253 256 260 262 265 268 279 TO 281 284 288 290 293 296 -307 TO 309 312 TO 315 328 329 333 TO 336 349 350 354 357 368 373 TO 377 380 -384 386 389 392 403 TO 405 408 412 414 417 420 431 TO 433 436 TO 439 452 -453 457 TO 460 473 474 478 481 492 497 TO 501 504 508 510 513 516 -527 TO 529 532 536 538 541 544 555 TO 557 560 TO 563 576 577 581 TO 584 597 -598 602 605 616 621 622 UNI GY -12.0184 5 8 9 11 13 14 32 33 36 37 39 41 42 66 67 70 71 87 88 91 92 105 108 112 -113 116 117 130 131 133 TO 135 137 139 140 158 159 161 TO 163 165 167 168 -186 187 192 TO 194 196 197 213 TO 215 217 218 231 232 236 237 240 241 254 -255 257 TO 259 261 263 264 282 283 285 TO 287 289 291 292 310 311 -316 TO 318 320 321 337 TO 339 341 342 355 356 360 361 364 365 378 379 381 -382 TO 383 385 387 388 406 407 409 TO 411 413 415 416 434 435 440 TO 442 444 -445 461 TO 463 465 466 479 480 484 485 488 489 502 503 505 TO 507 509 511 -512 530 531 533 TO 535 537 539 540 558 559 564 TO 566 568 569 585 TO 587 -589 590 603 604 608 609 612 613 UNI GY -6.009*CANTILEVERMEMBER LOAD78 79 99 100 204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 -700 701 721 722 UNI GY -6.825*FLOOR LOADFLOOR LOAD
109
YRANGE 0 15 FLOAD -4.375 GY*PARAPET WALLMEMBER LOAD623 TO 625 628 632 634 637 640 651 TO 653 656 660 662 665 668 679 TO 681 684 -685 TO 687 700 701 705 TO 708 721 722 726 729 740 745 746 UNI GY -3.2775*LIVE LOADLOAD 8 LLFLOOR LOADYRANGE 0 12.3 FLOAD -2 GYYRANGE 12.3 15.6 FLOAD -1.5 GY*floor loadMEMBER LOAD132 136 160 164 256 260 284 288 380 384 408 412 504 508 532 536 628 632 656 -660 UNI GY -5.75188 TO 191 209 TO 212 230 233 249 250 312 TO 315 333 TO 336 354 357 373 374 -436 TO 439 457 TO 460 478 481 497 498 560 TO 563 581 TO 584 602 605 621 622 -684 TO 687 705 TO 708 726 729 745 746 UNI GY -7.6204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 700 701 721 -722 UNI GY -7.4192 TO 195 213 TO 216 316 TO 319 337 TO 340 440 TO 443 461 TO 464 564 TO 567 -585 TO 588 688 TO 691 709 TO 712 UNI GY -15236 237 240 241 360 361 364 365 484 485 488 489 608 609 612 613 732 733 736 -737 UNI GY -13135 137 163 165 259 261 287 289 383 385 411 413 507 509 535 537 631 633 659 -661 UNI GY -11130 131 158 159 254 255 282 283 378 379 406 407 502 503 530 531 626 627 654 -655 UNI GY -14.9183 TO 187 244 307 TO 311 368 431 TO 435 492 555 TO 559 616 679 TO 683 -740 UNI GY -5.25127 129 138 141 144 155 157 166 169 172 251 253 262 265 268 279 281 290 293 -296 375 377 386 389 392 403 405 414 417 420 499 501 510 513 516 527 529 538 -541 544 623 625 634 637 640 651 653 662 665 668 UNI GY -7.328127 129 155 157 251 253 279 281 375 377 403 405 499 501 527 529 623 625 651 -653 UNI GY -8.5133 161 257 285 381 409 505 533 629 657 UNI GY -6LOAD COMB 9 1.5(DL+LL)7 1.5 8 1.5LOAD COMB 10 1.5(DL+ELX)7 1.5 1 1.5LOAD COMB 11 1.5(DL-ELX)7 1.5 1 -1.5LOAD COMB 12 1.5(DL+ELZ)7 1.5 2 1.5
110
LOAD COMB 13 1.5(DL-ELZ)7 1.5 2 -1.5LOAD COMB 14 1.5(DL+WLX)7 1.5 3 1.5LOAD COMB 15 1.5(DL-WLX)7 1.5 4 1.5LOAD COMB 16 1.5(DL+WLZ)7 1.5 5 1.5LOAD COMB 17 1.5(DL-WLZ)7 1.5 6 1.5LOAD COMB 18 1.2(DL+LL+ELX)7 1.2 8 1.2 1 1.2LOAD COMB 19 1.2(DL+LL-ELX)7 1.2 8 1.2 1 -1.2LOAD COMB 20 1.2(DL+LL+ELZ)7 1.2 8 1.2 2 1.2LOAD COMB 21 1.2(DL+LL-ELZ)7 1.2 8 1.2 2 -1.2LOAD COMB 22 1.2(DL+LL+WLX)7 1.2 8 1.2 3 1.2LOAD COMB 23 1.2(DL+LL-WLX)7 1.2 8 1.2 4 1.2LOAD COMB 24 1.2(DL+LL+WLZ)7 1.2 8 1.2 5 1.2LOAD COMB 25 1.2(DL+LL-WLZ)7 1.2 8 1.2 6 1.2LOAD COMB 26 (0.9 DL+ 1.5 ELX)7 0.9 1 1.5LOAD COMB 27 (0.9 DL- 1.5 LLX)7 0.9 1 -1.5LOAD COMB 28 (0.9 DL+ 1.5 ELZ)7 0.9 2 1.5LOAD COMB 29 (0.9 DL- 1.5 ELZ)7 0.9 2 -1.5LOAD COMB 30 (0.9 DL+ 1.5 WLX)7 0.9 3 1.5LOAD COMB 31 (0.9 DL- 1.5 WLX)7 0.9 4 1.5LOAD COMB 32 (0.9 DL+ 1.5 WLZ)7 0.9 5 1.5LOAD COMB 33 (0.9 DL- 1.5 WLZ)7 0.9 6 1.5LOAD COMB 34 1.0(DL+LL)7 1.0 8 1.0
111
LOAD COMB 35 1.0(DL+ELX)7 1.0 1 1.0LOAD COMB 36 1.0(DL-ELX)7 1.0 1 -1.0LOAD COMB 37 1.0(DL+ELZ)7 1.0 2 1.0LOAD COMB 38 1.0(DL-ELZ)7 1.0 2 -1.0LOAD COMB 39 1.0(DL+WLX)7 1.0 3 1.0LOAD COMB 40 1.0(DL-WLX)7 1.0 4 1.0LOAD COMB 41 1.0(DL+WLZ)7 1.0 5 1.0LOAD COMB 42 1.0(DL-WLZ)7 1.0 6 1.0LOAD COMB 43 (1.0 DL+ 0.8 LL+ 0.8 ELX)7 1.0 8 0.8 1 0.8LOAD COMB 44 (1.0 DL+ 0.8 LL- 0.8 ELX)7 1.0 8 0.8 1 -0.8LOAD COMB 45 (1.0 DL+ 0.8 LL+ 0.8 ELZ)7 1.0 8 0.8 2 0.8LOAD COMB 46 (1.0 DL+ 0.8 LL- 0.8 ELZ)7 1.0 8 0.8 2 -0.8LOAD COMB 47 (1.0 DL+ 0.8 LL+ 0.8 WLX)7 1.0 8 0.8 3 0.8LOAD COMB 48 (1.0 DL+ 0.8 LL- 0.8 WLX)7 1.0 8 0.8 4 0.8LOAD COMB 49 (1.0 DL+ 0.8 LL+ 0.8 WLZ)7 1.0 8 0.8 5 0.8LOAD COMB 50 (1.0 DL+ 0.8 LL- 0.8 WLZ)7 1.0 8 0.8 6 0.8LOAD COMB 51 (0.9 DL+ 1.0 ELX)7 0.9 1 1.0LOAD COMB 52 (0.9 DL- 1.0 LLX)7 0.9 1 -1.0LOAD COMB 53 (0.9 DL+ 1.0 ELZ)7 0.9 2 1.0LOAD COMB 54 (0.9 DL- 1.0 ELZ)7 0.9 2 -1.0LOAD COMB 55 (0.9 DL+ 1.0 WLX)7 0.9 3 1.0LOAD COMB 56 (0.9 DL- 1.0 WLX)7 0.9 4 1.0
112
LOAD COMB 57 (0.9 DL+ 1.0 WLZ)7 0.9 5 1.0LOAD COMB 58 (0.9 DL- 1.0 WLZ)7 0.9 6 1.0PERFORM ANALYSISLOAD LIST 34 TO 58PRINT SUPPORT REACTIONLOAD LIST 9 TO 33START CONCRETE DESIGNCODE INDIANUNIT MMS NEWTONFC 20 ALLFYSEC 415 ALLMAXMAIN 25 ALLMAXSEC 12 ALLMINMAIN 12 ALLMINSEC 8 ALLCLEAR 40 ALLDESIGN COLUMN 16 17 19 TO 28 44 45 47 TO 56 72 TO 77 80 TO 82 93 TO 98 101 -102 TO 103 110 111 114 115 118 119 122 123 142 143 145 TO 154 170 171 173 -174 TO 182 198 TO 203 206 TO 208 219 TO 224 227 TO 229 234 235 238 239 242 -243 246 247 266 267 269 TO 278 294 295 297 TO 306 322 TO 327 330 TO 332 343 -344 TO 348 351 TO 353 358 359 362 363 366 367 370 371 390 391 393 TO 402 418 -419 421 TO 430 446 TO 451 454 TO 456 467 TO 472 475 TO 477 482 483 486 487 -490 491 494 495 514 515 517 TO 526 542 543 545 TO 554 570 TO 575 578 TO 580 -591 TO 596 599 TO 601 606 607 610 611 614 615 618 619 638 639 641 TO 650 -666 667 669 TO 678 694 TO 699 702 TO 704 715 TO 720 723 TO 725 730 731 734 -735 738 739 742 743CLEAR 25 ALLTORSION 1 ALLDESIGN BEAM 1 2 4 5 9 11 29 30 32 33 37 39 57 66 67 78 79 87 88 99 100 112 -113 116 117 120 127 128 130 131 133 135 137 155 156 158 159 161 163 165 183 -192 TO 195 204 205 213 TO 216 225 226 236 237 240 241 244 251 252 254 255 -257 259 261 279 280 282 283 285 287 289 307 316 TO 319 328 329 337 TO 340 -349 350 360 361 364 365 368 375 376 378 379 381 383 385 403 404 406 407 409 -411 413 431 440 TO 443 452 453 461 TO 464 473 474 484 485 488 489 492 499 -500 502 503 505 507 509 527 528 530 531 533 535 537 555 564 TO 567 576 577 -585 TO 588 597 598 608 609 612 613 616 623 624 626 627 629 631 633 651 652 -654 655 657 659 661 679 688 TO 691 700 701 709 TO 712 721 722 732 733 736 -737 740DESIGN BEAM 3 6 8 10 12 TO 15 18 31 34 36 38 40 TO 43 46 58 59 62 TO 65 70 -71 83 TO 86 91 92 104 105 108 109 125 126 129 132 134 136 138 TO 141 144 -157 160 162 164 166 TO 169 172 184 TO 191 196 197 209 TO 212 217 218 230 -
113
231 TO 233 245 248 TO 250 253 256 258 260 262 TO 265 268 281 284 286 288 290 -291 TO 293 296 308 TO 315 320 321 333 TO 336 341 342 354 TO 357 369 -372 TO 374 377 380 382 384 386 TO 389 392 405 408 410 412 414 TO 417 420 -432 TO 439 444 445 457 TO 460 465 466 478 TO 481 493 496 TO 498 501 504 506 -508 510 TO 513 516 529 532 534 536 538 TO 541 544 556 TO 563 568 569 581 -582 TO 584 589 590 602 TO 605 617 620 TO 622 625 628 630 632 634 TO 637 640 -653 656 658 660 662 TO 665 668 680 TO 687 692 693 705 TO 708 713 714 726 -727 TO 729 741 744 TO 746*CHECK CODE ALLCONCRETE TAKEEND CONCRETE DESIGNFINISH
RESPONSE SPECTRUM METHOD
STAAD SPACESTART JOB INFORMATIONENGINEER DATE 26-Dec-08END JOB INFORMATIONINPUT WIDTH 79UNIT METER KNJOINT COORDINATES1 -0.28 0 10.74; 2 3.65 0 10.74; 3 7 0 10.74; 4 -0.28 0 5.49; 5 3.65 0 5.49;6 7 0 5.49; 7 -0.28 0 2.44; 8 3.65 0 2.44; 9 3.65 0 0; 10 -0.28 0 0; 11 7 0 0;12 7 0 2.44; 13 -0.28 -1.25 10.74; 14 -0.28 -1.25 5.49; 15 -0.28 -1.25 2.44;16 -0.28 -1.25 0; 17 3.65 -1.25 10.74; 18 3.65 -1.25 5.49; 19 3.65 -1.25 2.44;20 3.65 -1.25 0; 21 7 -1.25 10.74; 22 7 -1.25 5.49; 23 7 -1.25 2.44;24 7 -1.25 0; 25 9.5 0 10.74; 26 13.43 0 10.74; 27 16.78 0 10.74;28 9.5 0 5.49; 29 13.43 0 5.49; 30 16.78 0 5.49; 31 9.5 0 2.44;32 13.43 0 2.44; 33 13.43 0 0; 34 9.5 0 0; 35 16.78 0 0; 36 16.78 0 2.44;37 9.5 -1.25 10.74; 38 9.5 -1.25 5.49; 39 9.5 -1.25 2.44; 40 9.5 -1.25 0;41 13.43 -1.25 10.74; 42 13.43 -1.25 5.49; 43 13.43 -1.25 2.44;44 13.43 -1.25 0; 45 16.78 -1.25 10.74; 46 16.78 -1.25 5.49;47 16.78 -1.25 2.44; 48 16.78 -1.25 0; 49 16.78 0 -2.4; 50 -0.28 0 -2.4;51 7 0 -2.4; 52 9.5 0 -2.4; 53 7 0 -8; 54 7 0 -11.48; 55 7 0 -14.88;56 -0.28 0 -14.88; 57 -0.28 0 -11.48; 58 -0.28 0 -8; 59 3.33 0 -8;60 3.33 0 -11.48; 61 3.33 0 -14.88; 62 -0.28 -1.25 -11.48; 63 -0.28 -1.25 -8;64 3.33 -1.25 -11.48; 65 3.33 -1.25 -8; 66 7 -1.25 -8; 67 7 -1.25 -11.48;68 -0.28 -1.25 -14.88; 69 3.33 -1.25 -14.88; 70 7 -1.25 -14.88; 71 16.78 0 -8;72 16.78 0 -11.48; 73 16.78 0 -14.88; 74 9.5 0 -14.88; 75 9.5 0 -11.48;76 9.5 0 -8; 77 13.11 0 -8; 78 13.11 0 -11.48; 79 13.11 0 -14.88;80 9.5 -1.25 -11.48; 81 9.5 -1.25 -8; 82 13.11 -1.25 -11.48; 83 13.11 -1.25 -8;84 16.78 -1.25 -8; 85 16.78 -1.25 -11.48; 86 9.5 -1.25 -14.88;87 13.11 -1.25 -14.88; 88 16.78 -1.25 -14.88; 89 3.33 0 -2.4; 92 13.11 0 -2.4;
114
93 -0.28 -1.25 -2.4; 94 7 -1.25 -2.4; 95 9.5 -1.25 -2.4; 96 16.78 -1.25 -2.4;97 3.33 -1.25 -2.4; 98 13.11 -1.25 -2.4; 99 3.33 0 -16.44;100 3.33 -1.25 -16.44; 101 13.11 0 -16.44; 102 13.11 -1.25 -16.44;103 -0.28 3.05 10.74; 104 3.65 3.05 10.74; 105 7 3.05 10.74;106 -0.28 3.05 5.49; 107 3.65 3.05 5.49; 108 7 3.05 5.49; 109 -0.28 3.05 2.44;110 3.65 3.05 2.44; 111 3.65 3.05 0; 112 -0.28 3.05 0; 113 7 3.05 0;114 7 3.05 2.44; 115 9.5 3.05 10.74; 116 13.43 3.05 10.74;117 16.78 3.05 10.74; 118 9.5 3.05 5.49; 119 13.43 3.05 5.49;120 16.78 3.05 5.49; 121 9.5 3.05 2.44; 122 13.43 3.05 2.44; 123 13.43 3.05 0;124 9.5 3.05 0; 125 16.78 3.05 0; 126 16.78 3.05 2.44; 127 16.78 3.05 -2.4;128 -0.28 3.05 -2.4; 129 7 3.05 -2.4; 130 9.5 3.05 -2.4; 131 7 3.05 -8;132 7 3.05 -11.48; 133 7 3.05 -14.88; 134 -0.28 3.05 -14.88;135 -0.28 3.05 -11.48; 136 -0.28 3.05 -8; 137 3.33 3.05 -8;138 3.33 3.05 -11.48; 139 3.33 3.05 -14.88; 140 16.78 3.05 -8;141 16.78 3.05 -11.48; 142 16.78 3.05 -14.88; 143 9.5 3.05 -14.88;144 9.5 3.05 -11.48; 145 9.5 3.05 -8; 146 13.11 3.05 -8; 147 13.11 3.05 -11.48;148 13.11 3.05 -14.88; 149 3.33 3.05 -2.4; 150 13.11 3.05 -2.4;151 3.33 3.05 -16.44; 152 13.11 3.05 -16.44; 153 -0.28 6.1 10.74;154 3.65 6.1 10.74; 155 7 6.1 10.74; 156 -0.28 6.1 5.49; 157 3.65 6.1 5.49;158 7 6.1 5.49; 159 -0.28 6.1 2.44; 160 3.65 6.1 2.44; 161 3.65 6.1 0;162 -0.28 6.1 0; 163 7 6.1 0; 164 7 6.1 2.44; 165 9.5 6.1 10.74;166 13.43 6.1 10.74; 167 16.78 6.1 10.74; 168 9.5 6.1 5.49; 169 13.43 6.1 5.49;170 16.78 6.1 5.49; 171 9.5 6.1 2.44; 172 13.43 6.1 2.44; 173 13.43 6.1 0;174 9.5 6.1 0; 175 16.78 6.1 0; 176 16.78 6.1 2.44; 177 16.78 6.1 -2.4;178 -0.28 6.1 -2.4; 179 7 6.1 -2.4; 180 9.5 6.1 -2.4; 181 7 6.1 -8;182 7 6.1 -11.48; 183 7 6.1 -14.88; 184 -0.28 6.1 -14.88; 185 -0.28 6.1 -11.48;186 -0.28 6.1 -8; 187 3.33 6.1 -8; 188 3.33 6.1 -11.48; 189 3.33 6.1 -14.88;190 16.78 6.1 -8; 191 16.78 6.1 -11.48; 192 16.78 6.1 -14.88;193 9.5 6.1 -14.88; 194 9.5 6.1 -11.48; 195 9.5 6.1 -8; 196 13.11 6.1 -8;197 13.11 6.1 -11.48; 198 13.11 6.1 -14.88; 199 3.33 6.1 -2.4;200 13.11 6.1 -2.4; 201 3.33 6.1 -16.44; 202 13.11 6.1 -16.44;203 -0.28 9.15 10.74; 204 3.65 9.15 10.74; 205 7 9.15 10.74;206 -0.28 9.15 5.49; 207 3.65 9.15 5.49; 208 7 9.15 5.49; 209 -0.28 9.15 2.44;210 3.65 9.15 2.44; 211 3.65 9.15 0; 212 -0.28 9.15 0; 213 7 9.15 0;214 7 9.15 2.44; 215 9.5 9.15 10.74; 216 13.43 9.15 10.74;217 16.78 9.15 10.74; 218 9.5 9.15 5.49; 219 13.43 9.15 5.49;220 16.78 9.15 5.49; 221 9.5 9.15 2.44; 222 13.43 9.15 2.44; 223 13.43 9.15 0;224 9.5 9.15 0; 225 16.78 9.15 0; 226 16.78 9.15 2.44; 227 16.78 9.15 -2.4;228 -0.28 9.15 -2.4; 229 7 9.15 -2.4; 230 9.5 9.15 -2.4; 231 7 9.15 -8;232 7 9.15 -11.48; 233 7 9.15 -14.88; 234 -0.28 9.15 -14.88;235 -0.28 9.15 -11.48; 236 -0.28 9.15 -8; 237 3.33 9.15 -8;238 3.33 9.15 -11.48; 239 3.33 9.15 -14.88; 240 16.78 9.15 -8;241 16.78 9.15 -11.48; 242 16.78 9.15 -14.88; 243 9.5 9.15 -14.88;244 9.5 9.15 -11.48; 245 9.5 9.15 -8; 246 13.11 9.15 -8; 247 13.11 9.15 -11.48;
115
248 13.11 9.15 -14.88; 249 3.33 9.15 -2.4; 250 13.11 9.15 -2.4;251 3.33 9.15 -16.44; 252 13.11 9.15 -16.44; 253 -0.28 12.2 10.74;254 3.65 12.2 10.74; 255 7 12.2 10.74; 256 -0.28 12.2 5.49; 257 3.65 12.2 5.49;258 7 12.2 5.49; 259 -0.28 12.2 2.44; 260 3.65 12.2 2.44; 261 3.65 12.2 0;262 -0.28 12.2 0; 263 7 12.2 0; 264 7 12.2 2.44; 265 9.5 12.2 10.74;266 13.43 12.2 10.74; 267 16.78 12.2 10.74; 268 9.5 12.2 5.49;269 13.43 12.2 5.49; 270 16.78 12.2 5.49; 271 9.5 12.2 2.44;272 13.43 12.2 2.44; 273 13.43 12.2 0; 274 9.5 12.2 0; 275 16.78 12.2 0;276 16.78 12.2 2.44; 277 16.78 12.2 -2.4; 278 -0.28 12.2 -2.4; 279 7 12.2 -2.4;280 9.5 12.2 -2.4; 281 7 12.2 -8; 282 7 12.2 -11.48; 283 7 12.2 -14.88;284 -0.28 12.2 -14.88; 285 -0.28 12.2 -11.48; 286 -0.28 12.2 -8;287 3.33 12.2 -8; 288 3.33 12.2 -11.48; 289 3.33 12.2 -14.88;290 16.78 12.2 -8; 291 16.78 12.2 -11.48; 292 16.78 12.2 -14.88;293 9.5 12.2 -14.88; 294 9.5 12.2 -11.48; 295 9.5 12.2 -8; 296 13.11 12.2 -8;297 13.11 12.2 -11.48; 298 13.11 12.2 -14.88; 299 3.33 12.2 -2.4;300 13.11 12.2 -2.4; 301 3.33 12.2 -16.44; 302 13.11 12.2 -16.44;303 -0.28 15.25 10.74; 304 3.65 15.25 10.74; 305 7 15.25 10.74;306 -0.28 15.25 5.49; 307 3.65 15.25 5.49; 308 7 15.25 5.49;309 -0.28 15.25 2.44; 310 3.65 15.25 2.44; 311 3.65 15.25 0; 312 -0.28 15.25 0;313 7 15.25 0; 314 7 15.25 2.44; 315 9.5 15.25 10.74; 316 13.43 15.25 10.74;317 16.78 15.25 10.74; 318 9.5 15.25 5.49; 319 13.43 15.25 5.49;320 16.78 15.25 5.49; 321 9.5 15.25 2.44; 322 13.43 15.25 2.44;323 13.43 15.25 0; 324 9.5 15.25 0; 325 16.78 15.25 0; 326 16.78 15.25 2.44;327 16.78 15.25 -2.4; 328 -0.28 15.25 -2.4; 329 7 15.25 -2.4;330 9.5 15.25 -2.4; 331 7 15.25 -8; 332 7 15.25 -11.48; 333 7 15.25 -14.88;334 -0.28 15.25 -14.88; 335 -0.28 15.25 -11.48; 336 -0.28 15.25 -8;337 3.33 15.25 -8; 338 3.33 15.25 -11.48; 339 3.33 15.25 -14.88;340 16.78 15.25 -8; 341 16.78 15.25 -11.48; 342 16.78 15.25 -14.88;343 9.5 15.25 -14.88; 344 9.5 15.25 -11.48; 345 9.5 15.25 -8;346 13.11 15.25 -8; 347 13.11 15.25 -11.48; 348 13.11 15.25 -14.88;349 3.33 15.25 -2.4; 350 13.11 15.25 -2.4; 351 3.33 15.25 -16.44;352 13.11 15.25 -16.44;MEMBER INCIDENCES1 1 2; 2 3 2; 3 1 4; 4 4 5; 5 5 6; 6 4 7; 8 8 9; 9 10 9; 10 7 10; 11 9 11;12 6 12; 13 8 5; 14 2 5; 15 3 6; 16 1 13; 17 4 14; 18 12 11; 19 7 15; 20 10 16;21 2 17; 22 5 18; 23 8 19; 24 9 20; 25 3 21; 26 6 22; 27 12 23; 28 11 24;29 25 26; 30 27 26; 31 25 28; 32 28 29; 33 29 30; 34 28 31; 36 32 33; 37 34 33;38 31 34; 39 33 35; 40 30 36; 41 32 29; 42 26 29; 43 27 30; 44 25 37; 45 28 38;46 36 35; 47 31 39; 48 34 40; 49 26 41; 50 29 42; 51 32 43; 52 33 44; 53 27 45;54 30 46; 55 36 47; 56 35 48; 57 11 34; 58 49 35; 59 50 10; 62 53 54; 63 54 55;64 56 57; 65 58 57; 66 58 59; 67 59 53; 70 61 60; 71 60 59; 72 57 62; 73 58 63;74 60 64; 75 59 65; 76 66 53; 77 54 67; 78 55 61; 79 61 56; 80 56 68; 81 61 69;82 55 70; 83 71 72; 84 72 73; 85 74 75; 86 76 75; 87 76 77; 88 77 71; 91 79 78;92 78 77; 93 75 80; 94 76 81; 95 78 82; 96 77 83; 97 84 71; 98 72 85; 99 73 79;
116
100 79 74; 101 74 86; 102 79 87; 103 73 88; 104 50 58; 105 89 59; 108 92 77;109 49 71; 110 50 93; 111 51 94; 112 50 89; 113 89 51; 114 52 95; 115 49 96;116 52 92; 117 92 49; 118 89 97; 119 92 98; 120 51 52; 122 99 100; 123 101 102;125 51 53; 126 52 76; 127 103 104; 128 105 104; 129 103 106; 130 106 107;131 107 108; 132 106 109; 133 109 110; 134 110 111; 135 112 111; 136 109 112;137 111 113; 138 108 114; 139 110 107; 140 104 107; 141 105 108; 142 103 1;143 106 4; 144 114 113; 145 109 7; 146 112 10; 147 104 2; 148 107 5; 149 110 8;150 111 9; 151 105 3; 152 108 6; 153 114 12; 154 113 11; 155 115 116;156 117 116; 157 115 118; 158 118 119; 159 119 120; 160 118 121; 161 121 122;162 122 123; 163 124 123; 164 121 124; 165 123 125; 166 120 126; 167 122 119;168 116 119; 169 117 120; 170 115 25; 171 118 28; 172 126 125; 173 121 31;174 124 34; 175 116 26; 176 119 29; 177 122 32; 178 123 33; 179 117 27;180 120 30; 181 126 36; 182 125 35; 183 113 124; 184 127 125; 185 128 112;186 113 129; 187 124 130; 188 131 132; 189 132 133; 190 134 135; 191 136 135;192 136 137; 193 137 131; 194 132 138; 195 138 135; 196 139 138; 197 138 137;198 135 57; 199 136 58; 200 138 60; 201 137 59; 202 53 131; 203 132 54;204 133 139; 205 139 134; 206 134 56; 207 139 61; 208 133 55; 209 140 141;210 141 142; 211 143 144; 212 145 144; 213 145 146; 214 146 140; 215 141 147;216 147 144; 217 148 147; 218 147 146; 219 144 75; 220 145 76; 221 147 78;222 146 77; 223 71 140; 224 141 72; 225 142 148; 226 148 143; 227 143 74;228 148 79; 229 142 73; 230 128 136; 231 149 137; 232 150 146; 233 127 140;234 128 50; 235 129 51; 236 128 149; 237 149 129; 238 130 52; 239 127 49;240 130 150; 241 150 127; 242 149 89; 243 150 92; 244 129 130; 245 139 151;246 151 99; 247 152 101; 248 148 152; 249 129 131; 250 130 145; 251 153 154;252 155 154; 253 153 156; 254 156 157; 255 157 158; 256 156 159; 257 159 160;258 160 161; 259 162 161; 260 159 162; 261 161 163; 262 158 164; 263 160 157;264 154 157; 265 155 158; 266 153 103; 267 156 106; 268 164 163; 269 159 109;270 162 112; 271 154 104; 272 157 107; 273 160 110; 274 161 111; 275 155 105;276 158 108; 277 164 114; 278 163 113; 279 165 166; 280 167 166; 281 165 168;282 168 169; 283 169 170; 284 168 171; 285 171 172; 286 172 173; 287 174 173;288 171 174; 289 173 175; 290 170 176; 291 172 169; 292 166 169; 293 167 170;294 165 115; 295 168 118; 296 176 175; 297 171 121; 298 174 124; 299 166 116;300 169 119; 301 172 122; 302 173 123; 303 167 117; 304 170 120; 305 176 126;306 175 125; 307 163 174; 308 177 175; 309 178 162; 310 163 179; 311 174 180;312 181 182; 313 182 183; 314 184 185; 315 186 185; 316 186 187; 317 187 181;318 182 188; 319 188 185; 320 189 188; 321 188 187; 322 185 135; 323 186 136;324 188 138; 325 187 137; 326 131 181; 327 182 132; 328 183 189; 329 189 184;330 184 134; 331 189 139; 332 183 133; 333 190 191; 334 191 192; 335 193 194;336 195 194; 337 195 196; 338 196 190; 339 191 197; 340 197 194; 341 198 197;342 197 196; 343 194 144; 344 195 145; 345 197 147; 346 196 146; 347 140 190;348 191 141; 349 192 198; 350 198 193; 351 193 143; 352 198 148; 353 192 142;354 178 186; 355 199 187; 356 200 196; 357 177 190; 358 178 128; 359 179 129;360 178 199; 361 199 179; 362 180 130; 363 177 127; 364 180 200; 365 200 177;366 199 149; 367 200 150; 368 179 180; 369 189 201; 370 201 151; 371 202 152;
117
372 198 202; 373 179 181; 374 180 195; 375 203 204; 376 205 204; 377 203 206;378 206 207; 379 207 208; 380 206 209; 381 209 210; 382 210 211; 383 212 211;384 209 212; 385 211 213; 386 208 214; 387 210 207; 388 204 207; 389 205 208;390 203 153; 391 206 156; 392 214 213; 393 209 159; 394 212 162; 395 204 154;396 207 157; 397 210 160; 398 211 161; 399 205 155; 400 208 158; 401 214 164;402 213 163; 403 215 216; 404 217 216; 405 215 218; 406 218 219; 407 219 220;408 218 221; 409 221 222; 410 222 223; 411 224 223; 412 221 224; 413 223 225;414 220 226; 415 222 219; 416 216 219; 417 217 220; 418 215 165; 419 218 168;420 226 225; 421 221 171; 422 224 174; 423 216 166; 424 219 169; 425 222 172;426 223 173; 427 217 167; 428 220 170; 429 226 176; 430 225 175; 431 213 224;432 227 225; 433 228 212; 434 213 229; 435 224 230; 436 231 232; 437 232 233;438 234 235; 439 236 235; 440 236 237; 441 237 231; 442 232 238; 443 238 235;444 239 238; 445 238 237; 446 235 185; 447 236 186; 448 238 188; 449 237 187;450 181 231; 451 232 182; 452 233 239; 453 239 234; 454 234 184; 455 239 189;456 233 183; 457 240 241; 458 241 242; 459 243 244; 460 245 244; 461 245 246;462 246 240; 463 241 247; 464 247 244; 465 248 247; 466 247 246; 467 244 194;468 245 195; 469 247 197; 470 246 196; 471 190 240; 472 241 191; 473 242 248;474 248 243; 475 243 193; 476 248 198; 477 242 192; 478 228 236; 479 249 237;480 250 246; 481 227 240; 482 228 178; 483 229 179; 484 228 249; 485 249 229;486 230 180; 487 227 177; 488 230 250; 489 250 227; 490 249 199; 491 250 200;492 229 230; 493 239 251; 494 251 201; 495 252 202; 496 248 252; 497 229 231;498 230 245; 499 253 254; 500 255 254; 501 253 256; 502 256 257; 503 257 258;504 256 259; 505 259 260; 506 260 261; 507 262 261; 508 259 262; 509 261 263;510 258 264; 511 260 257; 512 254 257; 513 255 258; 514 253 203; 515 256 206;516 264 263; 517 259 209; 518 262 212; 519 254 204; 520 257 207; 521 260 210;522 261 211; 523 255 205; 524 258 208; 525 264 214; 526 263 213; 527 265 266;528 267 266; 529 265 268; 530 268 269; 531 269 270; 532 268 271; 533 271 272;534 272 273; 535 274 273; 536 271 274; 537 273 275; 538 270 276; 539 272 269;540 266 269; 541 267 270; 542 265 215; 543 268 218; 544 276 275; 545 271 221;546 274 224; 547 266 216; 548 269 219; 549 272 222; 550 273 223; 551 267 217;552 270 220; 553 276 226; 554 275 225; 555 263 274; 556 277 275; 557 278 262;558 263 279; 559 274 280; 560 281 282; 561 282 283; 562 284 285; 563 286 285;564 286 287; 565 287 281; 566 282 288; 567 288 285; 568 289 288; 569 288 287;570 285 235; 571 286 236; 572 288 238; 573 287 237; 574 231 281; 575 282 232;576 283 289; 577 289 284; 578 284 234; 579 289 239; 580 283 233; 581 290 291;582 291 292; 583 293 294; 584 295 294; 585 295 296; 586 296 290; 587 291 297;588 297 294; 589 298 297; 590 297 296; 591 294 244; 592 295 245; 593 297 247;594 296 246; 595 240 290; 596 291 241; 597 292 298; 598 298 293; 599 293 243;600 298 248; 601 292 242; 602 278 286; 603 299 287; 604 300 296; 605 277 290;606 278 228; 607 279 229; 608 278 299; 609 299 279; 610 280 230; 611 277 227;612 280 300; 613 300 277; 614 299 249; 615 300 250; 616 279 280; 617 289 301;618 301 251; 619 302 252; 620 298 302; 621 279 281; 622 280 295; 623 303 304;624 305 304; 625 303 306; 626 306 307; 627 307 308; 628 306 309; 629 309 310;630 310 311; 631 312 311; 632 309 312; 633 311 313; 634 308 314; 635 310 307;
118
636 304 307; 637 305 308; 638 303 253; 639 306 256; 640 314 313; 641 309 259;642 312 262; 643 304 254; 644 307 257; 645 310 260; 646 311 261; 647 305 255;648 308 258; 649 314 264; 650 313 263; 651 315 316; 652 317 316; 653 315 318;654 318 319; 655 319 320; 656 318 321; 657 321 322; 658 322 323; 659 324 323;660 321 324; 661 323 325; 662 320 326; 663 322 319; 664 316 319; 665 317 320;666 315 265; 667 318 268; 668 326 325; 669 321 271; 670 324 274; 671 316 266;672 319 269; 673 322 272; 674 323 273; 675 317 267; 676 320 270; 677 326 276;678 325 275; 679 313 324; 680 327 325; 681 328 312; 682 313 329; 683 324 330;684 331 332; 685 332 333; 686 334 335; 687 336 335; 688 336 337; 689 337 331;690 332 338; 691 338 335; 692 339 338; 693 338 337; 694 335 285; 695 336 286;696 338 288; 697 337 287; 698 281 331; 699 332 282; 700 333 339; 701 339 334;702 334 284; 703 339 289; 704 333 283; 705 340 341; 706 341 342; 707 343 344;708 345 344; 709 345 346; 710 346 340; 711 341 347; 712 347 344; 713 348 347;714 347 346; 715 344 294; 716 345 295; 717 347 297; 718 346 296; 719 290 340;720 341 291; 721 342 348; 722 348 343; 723 343 293; 724 348 298; 725 342 292;726 328 336; 727 349 337; 728 350 346; 729 327 340; 730 328 278; 731 329 279;732 328 349; 733 349 329; 734 330 280; 735 327 277; 736 330 350; 737 350 327;738 349 299; 739 350 300; 740 329 330; 741 339 351; 742 351 301; 743 352 302;744 348 352; 745 329 331; 746 330 345;DEFINE MATERIAL STARTISOTROPIC CONCRETEE 2.17185e+007POISSON 0.17DENSITY 23.5616ALPHA 1e-005 END DEFINE MATERIAL MEMBER PROPERTY INDIAN16 17 19 TO 28 44 45 47 TO 56 72 TO 77 80 TO 82 93 TO 98 101 TO 103 110 111 -114 115 118 119 142 143 145 TO 154 170 171 173 TO 182 198 TO 203 206 TO 208 -219 TO 224 227 TO 229 234 235 238 239 242 243 266 267 269 TO 278 294 295 -297 TO 306 322 TO 327 330 TO 332 343 TO 348 351 TO 353 358 359 362 363 366 -367 390 391 393 TO 402 418 419 421 TO 430 446 TO 451 454 TO 456 467 TO 472 -475 TO 477 482 483 486 487 490 491 514 515 517 TO 526 542 543 545 TO 554 -570 TO 575 578 TO 580 591 TO 596 599 TO 601 606 607 610 611 614 615 638 639 -641 TO 650 666 667 669 TO 678 694 TO 699 702 TO 704 715 TO 720 723 TO 725 -730 731 734 735 738 739 PRIS YD 0.23 ZD 0.6122 123 246 247 370 371 494 495 618 619 742 743 PRIS YD 0.23 ZD 0.45MEMBER PROPERTY INDIAN127 TO 141 144 155 TO 169 172 183 TO 197 204 205 209 TO 218 225 226 -230 TO 233 236 237 240 241 244 245 248 TO 265 268 279 TO 293 296 307 TO 321 -328 329 333 TO 342 349 350 354 TO 357 360 361 364 365 368 369 372 TO 389 -392 403 TO 417 420 431 TO 445 452 453 457 TO 466 473 474 478 TO 481 484 485 -488 489 492 493 496 TO 513 516 527 TO 541 544 555 TO 569 576 577 581 TO 590 -597 598 602 TO 605 608 609 612 613 616 617 620 TO 637 640 651 TO 665 668 -
119
679 TO 693 700 701 705 TO 714 721 722 726 TO 729 732 733 736 737 740 741 -744 TO 746 PRIS YD 0.56 ZD 0.23UNIT MMS NEWTONMEMBER PROPERTY INDIAN1 TO 6 8 TO 15 18 29 TO 34 36 TO 43 46 57 TO 59 62 TO 67 70 71 78 79 -83 TO 88 91 92 99 100 104 105 108 109 112 113 116 117 120 125 -126 PRIS YD 300 ZD 230UNIT METER KNCONSTANTSBETA 90 MEMB 22 50 74 75 81 95 96 102 122 123 148 176 200 201 207 221 222 -228 246 247 272 300 324 325 331 345 346 352 370 371 396 424 448 449 455 469 -470 476 494 495 520 548 572 573 579 593 594 600 618 619 644 672 696 697 703 -717 718 724 742 743MATERIAL CONCRETE MEMB 1 TO 6 8 TO 34 36 TO 59 62 TO 67 70 TO 88 91 TO 105 -108 TO 120 122 123 125 TO 746SUPPORTS13 TO 24 37 TO 48 62 TO 70 80 TO 88 93 TO 98 100 102 FIXED*SEISMIC WEIGHTS CUT OFF MODE SHAPE 10 DEFINE WIND LOADTYPE 1INT 0 0 HEIG 10 15LOAD 1 SEISMIC LOADINGSELFWEIGHT X 1.0
SELFWEIGHT Y 1.0
MEMBER LOAD*external walls= 0.23*(3.05-0.3)*19 = 12.0181 TO 3 6 10 12 15 18 29 TO 31 34 38 40 43 46 57 TO 59 62 TO 65 78 79 -83 TO 86 99 100 104 109 120 125 TO 129 132 136 138 141 144 155 TO 157 160 -164 166 169 172 183 TO 185 188 TO 191 204 205 209 TO 212 225 226 230 233 -244 249 TO 253 256 260 262 265 268 279 TO 281 284 288 290 293 296 -307 TO 309 312 TO 315 328 329 333 TO 336 349 350 354 357 368 373 TO 377 380 -384 386 389 392 403 TO 405 408 412 414 417 420 431 TO 433 436 TO 439 452 -453 457 TO 460 473 474 478 481 492 497 TO 501 504 508 510 513 516 -527 TO 529 532 536 538 541 544 555 TO 557 560 TO 563 576 577 581 TO 584 597 -598 602 605 616 621 622 UNI GY 12.018*internal walls= 0.115*(3.05-0.3)*14 = 6.009 4 5 8 9 11 13 14 32 33 36 37 39 41 42 66 67 70 71 87 88 91 92 105 108 112 -113 116 117 130 131 133 TO 135 137 139 140 158 159 161 TO 163 165 167 168 -186 187 192 TO 194 196 197 213 TO 215 217 218 231 232 236 237 240 241 254 -255 257 TO 259 261 263 264 282 283 285 TO 287 289 291 292 310 311 -
120
316 TO 318 320 321 337 TO 339 341 342 355 356 360 361 364 365 378 379 381 -382 TO 383 385 387 388 406 407 409 TO 411 413 415 416 434 435 440 TO 442 444 -445 461 TO 463 465 466 479 480 484 485 488 489 502 503 505 TO 507 509 511 -512 530 531 533 TO 535 537 539 540 558 559 564 TO 566 568 569 585 TO 587 -589 590 603 604 608 609 612 613 UNI GY 6.009* cantilever load 4.375*(length)1.56 = 6.82578 79 99 100 204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 -700 701 721 722 UNI GY 6.825*FLOOR WEIGHT*YRANGE 0 15 fLOAD 4.375*parapet wall=(thickness)0.23*(ht)0.75*19 = 3.2775623 TO 625 628 632 634 637 640 651 TO 653 656 660 662 665 668 679 TO 681 684 -685 TO 687 700 701 705 TO 708 721 722 726 729 740 745 746 UNI GY 3.2775MEMBER LOAD1 TO 3 6 10 12 15 18 29 TO 31 34 38 40 43 46 57 TO 59 62 TO 65 78 79 -83 TO 86 99 100 104 109 120 125 TO 129 132 136 138 141 144 155 TO 157 160 -164 166 169 172 183 TO 185 188 TO 191 204 205 209 TO 212 225 226 230 233 -244 249 TO 253 256 260 262 265 268 279 TO 281 284 288 290 293 296 -307 TO 309 312 TO 315 328 329 333 TO 336 349 350 354 357 368 373 TO 377 380 -384 386 389 392 403 TO 405 408 412 414 417 420 431 TO 433 436 TO 439 452 -453 457 TO 460 473 474 478 481 492 497 TO 501 504 508 510 513 516 -527 TO 529 532 536 538 541 544 555 TO 557 560 TO 563 576 577 581 TO 584 597 -598 602 605 616 621 622 UNI GY 12.0184 5 8 9 11 13 14 32 33 36 37 39 41 42 66 67 70 71 87 88 91 92 105 108 112 -113 116 117 130 131 133 TO 135 137 139 140 158 159 161 TO 163 165 167 168 -186 187 192 TO 194 196 197 213 TO 215 217 218 231 232 236 237 240 241 254 -255 257 TO 259 261 263 264 282 283 285 TO 287 289 291 292 310 311 -316 TO 318 320 321 337 TO 339 341 342 355 356 360 361 364 365 378 379 381 -382 TO 383 385 387 388 406 407 409 TO 411 413 415 416 434 435 440 TO 442 444 -445 461 TO 463 465 466 479 480 484 485 488 489 502 503 505 TO 507 509 511 -512 530 531 533 TO 535 537 539 540 558 559 564 TO 566 568 569 585 TO 587 -589 590 603 604 608 609 612 613 UNI GY 6.009*CANTILEVERMEMBER LOAD78 79 99 100 204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 -700 701 721 722 UNI GY 6.825*FLOOR LOADFLOOR LOADYRANGE 0 15 FLOAD 4.375 GY*PARAPET WALLMEMBER LOAD623 TO 625 628 632 634 637 640 651 TO 653 656 660 662 665 668 679 TO 681 684 -685 TO 687 700 701 705 TO 708 721 722 726 729 740 745 746 UNI GY 3.2775SPECTRUM SRSS X 1.0 ACC DAMP 0.05 SCALE 32.2
121
0.25 2.5; 0.5 2; 0.75 1.3; 1.00 1.0; 1.25 0.8; 1.5 0.7; 2.00 0.6; 2.25 0.45;
2.5 0.4; 2.75 0.4; 3.00 0.35; 3.25 0.3; 3.5 0.3; 3.75 0.25; 4.00 0.25
LOAD 2 SEISMIC LOADINGSELFWEIGHT X 1.0
SELFWEIGHT z 1.0
MEMBER LOAD1 TO 3 6 10 12 15 18 29 TO 31 34 38 40 43 46 57 TO 59 62 TO 65 78 79 -83 TO 86 99 100 104 109 120 125 TO 129 132 136 138 141 144 155 TO 157 160 -164 166 169 172 183 TO 185 188 TO 191 204 205 209 TO 212 225 226 230 233 -244 249 TO 253 256 260 262 265 268 279 TO 281 284 288 290 293 296 -307 TO 309 312 TO 315 328 329 333 TO 336 349 350 354 357 368 373 TO 377 380 -384 386 389 392 403 TO 405 408 412 414 417 420 431 TO 433 436 TO 439 452 -453 457 TO 460 473 474 478 481 492 497 TO 501 504 508 510 513 516 -527 TO 529 532 536 538 541 544 555 TO 557 560 TO 563 576 577 581 TO 584 597 -598 602 605 616 621 622 UNI GY 12.0184 5 8 9 11 13 14 32 33 36 37 39 41 42 66 67 70 71 87 88 91 92 105 108 112 -113 116 117 130 131 133 TO 135 137 139 140 158 159 161 TO 163 165 167 168 -186 187 192 TO 194 196 197 213 TO 215 217 218 231 232 236 237 240 241 254 -255 257 TO 259 261 263 264 282 283 285 TO 287 289 291 292 310 311 -316 TO 318 320 321 337 TO 339 341 342 355 356 360 361 364 365 378 379 381 -382 TO 383 385 387 388 406 407 409 TO 411 413 415 416 434 435 440 TO 442 444 -445 461 TO 463 465 466 479 480 484 485 488 489 502 503 505 TO 507 509 511 -512 530 531 533 TO 535 537 539 540 558 559 564 TO 566 568 569 585 TO 587 -589 590 603 604 608 609 612 613 UNI GY 6.009*CANTILEVERMEMBER LOAD78 79 99 100 204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 -700 701 721 722 UNI GY 6.825*FLOOR LOADFLOOR LOADYRANGE 0 15 FLOAD 4.375 GY*PARAPET WALLMEMBER LOAD623 TO 625 628 632 634 637 640 651 TO 653 656 660 662 665 668 679 TO 681 684 -685 TO 687 700 701 705 TO 708 721 722 726 729 740 745 746 UNI GY 3.2775SPECTRUM SRSS Z 1.0 ACC DAMP 0.05 SCALE 32.2
0.25 2.5; 0.5 2; 0.75 1.3; 1.00 1.0; 1.25 0.8; 1.5 0.7; 2.00 0.6; 2.25 0.45;
122
2.5 0.4; 2.75 0.4; 3.00 0.35; 3.25 0.3; 3.5 0.3; 3.75 0.25; 4.00 0.25 LOAD 3 WL IN X DIRECTIONWIND LOAD X 1 TYPE 1LOAD 4 WL IN - X DIRECTIONWIND LOAD X -1 TYPE 1LOAD 5 WL IN Z DIRECTIONWIND LOAD Z 1 TYPE 1LOAD 6 WL IN - Z DIRECTIONWIND LOAD Z -1 TYPE 1*DEAD LOADLOAD 7 DLSELFWEIGHT Y -1*WALL LOADMEMBER LOAD1 TO 3 6 10 12 15 18 29 TO 31 34 38 40 43 46 57 TO 59 62 TO 65 78 79 -83 TO 86 99 100 104 109 120 125 TO 129 132 136 138 141 144 155 TO 157 160 -164 166 169 172 183 TO 185 188 TO 191 204 205 209 TO 212 225 226 230 233 -244 249 TO 253 256 260 262 265 268 279 TO 281 284 288 290 293 296 -307 TO 309 312 TO 315 328 329 333 TO 336 349 350 354 357 368 373 TO 377 380 -384 386 389 392 403 TO 405 408 412 414 417 420 431 TO 433 436 TO 439 452 -453 457 TO 460 473 474 478 481 492 497 TO 501 504 508 510 513 516 -527 TO 529 532 536 538 541 544 555 TO 557 560 TO 563 576 577 581 TO 584 597 -598 602 605 616 621 622 UNI GY -12.0184 5 8 9 11 13 14 32 33 36 37 39 41 42 66 67 70 71 87 88 91 92 105 108 112 -113 116 117 130 131 133 TO 135 137 139 140 158 159 161 TO 163 165 167 168 -186 187 192 TO 194 196 197 213 TO 215 217 218 231 232 236 237 240 241 254 -255 257 TO 259 261 263 264 282 283 285 TO 287 289 291 292 310 311 -316 TO 318 320 321 337 TO 339 341 342 355 356 360 361 364 365 378 379 381 -382 TO 383 385 387 388 406 407 409 TO 411 413 415 416 434 435 440 TO 442 444 -445 461 TO 463 465 466 479 480 484 485 488 489 502 503 505 TO 507 509 511 -512 530 531 533 TO 535 537 539 540 558 559 564 TO 566 568 569 585 TO 587 -589 590 603 604 608 609 612 613 UNI GY -6.009*CANTILEVERMEMBER LOAD78 79 99 100 204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 -700 701 721 722 UNI GY -6.825*FLOOR LOADFLOOR LOADYRANGE 0 15 FLOAD -4.375 GY*PARAPET WALLMEMBER LOAD
123
623 TO 625 628 632 634 637 640 651 TO 653 656 660 662 665 668 679 TO 681 684 -685 TO 687 700 701 705 TO 708 721 722 726 729 740 745 746 UNI GY -3.2775*LIVE LOADLOAD 8 LLFLOOR LOADYRANGE 0 12.3 FLOAD -2 GYYRANGE 12.3 15.6 FLOAD -1.5 GY*floor loadMEMBER LOAD132 136 160 164 256 260 284 288 380 384 408 412 504 508 532 536 628 632 656 -660 UNI GY -5.75188 TO 191 209 TO 212 230 233 249 250 312 TO 315 333 TO 336 354 357 373 374 -436 TO 439 457 TO 460 478 481 497 498 560 TO 563 581 TO 584 602 605 621 622 -684 TO 687 705 TO 708 726 729 745 746 UNI GY -7.6204 205 225 226 328 329 349 350 452 453 473 474 576 577 597 598 700 701 721 -722 UNI GY -7.4192 TO 195 213 TO 216 316 TO 319 337 TO 340 440 TO 443 461 TO 464 564 TO 567 -585 TO 588 688 TO 691 709 TO 712 UNI GY -15236 237 240 241 360 361 364 365 484 485 488 489 608 609 612 613 732 733 736 -737 UNI GY -13135 137 163 165 259 261 287 289 383 385 411 413 507 509 535 537 631 633 659 -661 UNI GY -11130 131 158 159 254 255 282 283 378 379 406 407 502 503 530 531 626 627 654 -655 UNI GY -14.9183 TO 187 244 307 TO 311 368 431 TO 435 492 555 TO 559 616 679 TO 683 -740 UNI GY -5.25127 129 138 141 144 155 157 166 169 172 251 253 262 265 268 279 281 290 293 -296 375 377 386 389 392 403 405 414 417 420 499 501 510 513 516 527 529 538 -541 544 623 625 634 637 640 651 653 662 665 668 UNI GY -7.328127 129 155 157 251 253 279 281 375 377 403 405 499 501 527 529 623 625 651 -653 UNI GY -8.5133 161 257 285 381 409 505 533 629 657 UNI GY -6
UNIT METER KNLOAD COMB 9 1.5(DL+LL)7 1.5 8 1.5LOAD COMB 10 1.5(DL+ELX)7 1.5 1 1.5LOAD COMB 11 1.5(DL-ELX)7 1.5 1 1.5*LOAD COMB 12 1.5(DL+ELZ)*7 1.5*LOAD COMB 13 1.5(DL-ELZ)
124
*7 1.5LOAD COMB 14 1.5(DL+WLX)7 1.5 3 1.5LOAD COMB 15 1.5(DL-WLX)7 1.5 4 1.5LOAD COMB 16 1.5(DL+WLZ)7 1.5 5 1.5LOAD COMB 17 1.5(DL-WLZ)7 1.5 6 1.5LOAD COMB 18 1.2(DL+LL+ELX)7 1.2 8 1.2 1 1.2LOAD COMB 19 1.2(DL+LL-ELX)7 1.2 8 1.2 1 1.2*LOAD COMB 20 1.2(DL+LL+ELZ)*7 1.2 8 1.2*LOAD COMB 21 1.2(DL+LL-ELZ)*7 1.2 8 1.2LOAD COMB 22 1.2(DL+LL+WLX)7 1.2 8 1.2 3 1.2LOAD COMB 23 1.2(DL+LL-WLX)7 1.2 8 1.2 4 1.2LOAD COMB 24 1.2(DL+LL+WLZ)7 1.2 8 1.2 5 1.2LOAD COMB 25 1.2(DL+LL-WLZ)7 1.2 8 1.2 6 1.2LOAD COMB 26 (0.9 DL+ 1.5 ELX)7 0.9 1 1.5LOAD COMB 27 (0.9 DL- 1.5 LLX)7 0.9 1 1.5*LOAD COMB 28 (0.9 DL+ 1.5 ELZ)*7 0.9*LOAD COMB 29 (0.9 DL- 1.5 ELZ)*7 0.9LOAD COMB 30 (0.9 DL+ 1.5 WLX)7 0.9 3 1.5LOAD COMB 31 (0.9 DL- 1.5 WLX)7 0.9 4 1.5LOAD COMB 32 (0.9 DL+ 1.5 WLZ)7 0.9 5 1.5LOAD COMB 33 (0.9 DL- 1.5 WLZ)7 0.9 6 1.5LOAD COMB 34 1.0(DL+LL)7 1.0 8 1.0LOAD COMB 35 1.0(DL+ELX)
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7 1.0 1 1.0LOAD COMB 36 1.0(DL-ELX)7 1.0 1 1.0*LOAD COMB 37 1.0(DL+ELZ)*7 1.0*LOAD COMB 38 1.0(DL-ELZ)*7 1.0LOAD COMB 39 1.0(DL+WLX)7 1.0 3 1.0LOAD COMB 40 1.0(DL-WLX)7 1.0 4 1.0LOAD COMB 41 1.0(DL+WLZ)7 1.0 5 1.0LOAD COMB 42 1.0(DL-WLZ)7 1.0 6 1.0LOAD COMB 43 (1.0 DL+ 0.8 LL+ 0.8 ELX)7 1.0 8 0.8 1 0.8LOAD COMB 44 (1.0 DL+ 0.8 LL- 0.8 ELX)7 1.0 8 0.8 1 0.8*LOAD COMB 45 (1.0 DL+ 0.8 LL+ 0.8 ELZ)*7 1.0 8 0.8*LOAD COMB 46 (1.0 DL+ 0.8 LL- 0.8 ELZ)*7 1.0 8 0.8LOAD COMB 47 (1.0 DL+ 0.8 LL+ 0.8 WLX)7 1.0 8 0.8 3 0.8LOAD COMB 48 (1.0 DL+ 0.8 LL- 0.8 WLX)7 1.0 8 0.8 4 0.8LOAD COMB 49 (1.0 DL+ 0.8 LL+ 0.8 WLZ)7 1.0 8 0.8 5 0.8LOAD COMB 50 (1.0 DL+ 0.8 LL- 0.8 WLZ)7 1.0 8 0.8 6 0.8LOAD COMB 51 (0.9 DL+ 1.0 ELX)7 0.9 1 1.0LOAD COMB 52 (0.9 DL- 1.0 LLX)7 0.9*LOAD COMB 53 (0.9 DL+ 1.0 ELZ)*7 0.9*LOAD COMB 54 (0.9 DL- 1.0 ELZ)*7 0.9LOAD COMB 55 (0.9 DL+ 1.0 WLX)7 0.9 3 1.0LOAD COMB 56 (0.9 DL- 1.0 WLX)7 0.9 4 1.0LOAD COMB 57 (0.9 DL+ 1.0 WLZ)
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7 0.9 5 1.0LOAD COMB 58 (0.9 DL- 1.0 WLZ)7 0.9 6 1.0PERFORM ANALYSISLOAD LIST 34 TO 36 39 TO 44 47 TO 52PRINT SUPPORT REACTIONLOAD LIST 9 TO 11 14 TO 19 22 TO 27 30 TO 33PERFORM ANALYSIS PRINT ALLSTART CONCRETE DESIGNCODE INDIANUNIT MMS NEWTONFC 20 ALLFYSEC 415 ALLMAXMAIN 25 ALLMAXSEC 12 ALLMINMAIN 12 ALLMINSEC 8 ALLCLEAR 40 ALLDESIGN COLUMN 16 17 19 TO 28 44 45 47 TO 56 72 TO 77 80 TO 82 93 TO 98 101 -102 TO 103 110 111 114 115 118 119 122 123 142 143 145 TO 154 170 171 173 -174 TO 182 198 TO 203 206 TO 208 219 TO 224 227 TO 229 234 235 238 239 242 -243 246 247 266 267 269 TO 278 294 295 297 TO 306 322 TO 327 330 TO 332 343 -344 TO 348 351 TO 353 358 359 362 363 366 367 370 371 390 391 393 TO 402 418 -419 421 TO 430 446 TO 451 454 TO 456 467 TO 472 475 TO 477 482 483 486 487 -490 491 494 495 514 515 517 TO 526 542 543 545 TO 554 570 TO 575 578 TO 580 -591 TO 596 599 TO 601 606 607 610 611 614 615 618 619 638 639 641 TO 650 -666 667 669 TO 678 694 TO 699 702 TO 704 715 TO 720 723 TO 725 730 731 734 -735 738 739 742 743CLEAR 25 ALLTORSION 1 ALLDESIGN BEAM 1 2 4 5 9 11 29 30 32 33 37 39 57 66 67 78 79 87 88 99 100 112 -113 116 117 120 127 128 130 131 133 135 137 155 156 158 159 161 163 165 183 -192 TO 195 204 205 213 TO 216 225 226 236 237 240 241 244 251 252 254 255 -257 259 261 279 280 282 283 285 287 289 307 316 TO 319 328 329 337 TO 340 -349 350 360 361 364 365 368 375 376 378 379 381 383 385 403 404 406 407 409 -411 413 431 440 TO 443 452 453 461 TO 464 473 474 484 485 488 489 492 499 -500 502 503 505 507 509 527 528 530 531 533 535 537 555 564 TO 567 576 577 -585 TO 588 597 598 608 609 612 613 616 623 624 626 627 629 631 633 651 652 -654 655 657 659 661 679 688 TO 691 700 701 709 TO 712 721 722 732 733 736 -737 740DESIGN BEAM 3 6 8 10 12 TO 15 18 31 34 36 38 40 TO 43 46 58 59 62 TO 65 70 -71 83 TO 86 91 92 104 105 108 109 125 126 129 132 134 136 138 TO 141 144 -157 160 162 164 166 TO 169 172 184 TO 191 196 197 209 TO 212 217 218 230 -
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231 TO 233 245 248 TO 250 253 256 258 260 262 TO 265 268 281 284 286 288 290 -291 TO 293 296 308 TO 315 320 321 333 TO 336 341 342 354 TO 357 369 -372 TO 374 377 380 382 384 386 TO 389 392 405 408 410 412 414 TO 417 420 -432 TO 439 444 445 457 TO 460 465 466 478 TO 481 493 496 TO 498 501 504 506 -508 510 TO 513 516 529 532 534 536 538 TO 541 544 556 TO 563 568 569 581 -582 TO 584 589 590 602 TO 605 617 620 TO 622 625 628 630 632 634 TO 637 640 -653 656 658 660 662 TO 665 668 680 TO 687 692 693 705 TO 708 713 714 726 -727 TO 729 741 744 TO 746*CHECK CODE ALLCONCRETE TAKEEND CONCRETE DESIGNFINISH
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7.2 CONCLUSION:
Different types of Analysis can be employed for multiple design assessments. In the present theses, the analysis of the 5-storey building is done taking the seismic forces into considerations, using Static equivalent method and Response spectrum method. According to IS: 1893 2002, the analysis results are compared and it is found that Response spectrum method gives more conservative values for the design parameters, like bending moments, stresses, thus leading to more economic design. The reason for this is, the Dynamic analysis is done using accelerations-response spectrum than equivalizing the dynamic forces into static forces.
The approximate economy achieved using Response spectrum method over equivalent seismic method is 70 % in concrete quantity & 72 % in steel quantity.
The design of structural members (foundations, columns, beams, slabs) is done according to IS: 456 200
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7.3 DRAWINGS
TYPICAL FLOOR PLAN
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FLOOR OUTLINE
131
BEAMS LAYOUT
132
COLUMN LAYOUT
133
GRID LAYOUT
134
FRAME
135
REINFORCEMENT DETAILS ::
FOOTINGS
136
BEAMS:
137
SLABS
138
STAIR CASE
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7.4 REFERENCES:
1. ILLUSTRATED R.C.DESIGN BY V.L.SHAH & H.J.SHAH
2. REINFORCED CONCRETE DESIGN BY S.UNNIKRISHNA PILLAI
3. REINFORCED CONCRETE DESIGN BY RAMCHANDRA
4. REINFORCED CONCRETE DESIGN BY A.K.JAIN
CODES:
I.S 456 2000 PLAIN AND REINFORCED CONCRETE
I.S 875 1987 DESIGN LOADS PART 1 – DEAD LOADS PART 2 – LIVE LOADS
I.S 1893 2002 EARTHQUAKE RESISTANT DESIGN OF STRUCTURE
S.P 16 1980 DESIGN AIDS (FOR REINFORCED CONCRETE)
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