design of deck for complex concrete bridge
DESCRIPTION
design of complex bridge deckTRANSCRIPT
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DESIGN OF DECKFOR COMPLEX CONCRETE BRIDGE
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GROUP NO. 04 (A)
Junaid Amin11-CE-79
Mujtaba Ahmed11-CE-54
Muhammad Asif11-CE-39
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BRIDGES
Bridges are define as structures, which provide a connection or passage over a gap without blocking the opening or passageway beneath.
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Elements of bridge•superstructure•substructure
Super Structure•Wearing surface •Deck •Primary members •Secondary members
Substructure•Abutments•Bearings•Pedestals•Back Wall•Wing Wall•Footings•Piles•Sheeting
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SUPER STRUCTURE THE PORTION OF THE BRIDGE THAT SUPPORTS THE DECK AND CONNECTS ONE SUBSTRUCTURE ELEMENT TO ANOTHER.
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WEARING SURFACEIt is that portion of deck which
resists traffic wear. In some instances it is a separate bitumen layer, while in some cases it is integral part of concrete deck. The integral wearing surface is typically ½ to 2 in (13 to 51mm).the bituminous wearing course usually varies in thickness from 2 to 4 in (51 to 102mm).
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DECK It is the physical extension of the
roadway across the obstruction to be bridged.
Functions:- To distribute loads transversely along the
bridge cross-section To distribute loads longitudinally along the
length of the bridge.
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PRIMARY MEMBERS
It distributes loads longitudinally and is usually designed principally to resist flexure and shear.SECONDARY MEMBERS
Secondary members are bracing between primary members designed to resist cross-sectional deformation of superstructure frame and help distribute part of the vertical load between stringers.
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STRINGERS
o Stringers are primary longitudinal support members, usually rectangular pieces that are 5 or more inches thick. With a depth more than 2 inches greater than the thickness.
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SUB STRUCTURE PORTION OF THE BRIDGE THAT SUPPORTS THE SUPERSTRUCTURE AND DISTRIBUTES ALL BRIDGE LOADS TO BELOW-GROUND BRIDGE FOOTINGS.
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ABUTMENTS
They are earth retaining structures which supports the superstructure and overpass roadway at the beginning and end of a bridge.
BEARINGS These are mechanical systems which
transmit the vertical and horizontal loads of superstructure to substructure and accommodate movement between superstructure and substructure.
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PEDESTAL
A pedestal is a short column on an abutment or pier under a bearing which directly supports a superstructure primary member
BACK WALL
It is also called stem, is the primary component of the abutment acting as a retaining structure at each approach.
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WINGS WALL
A wing wall is a side wall to the abutment back wall or stem designed to assist in confining earth behind the abutment
FOOTINGS As bearing transfer the superstructure loads to
the substructure, so in turn do the abutment and pier footing transfer loads from the substructure to the subsoil or piles. A footing supported by soil without piles are called a spread footing .a footing supported by piles is known as a pile cap
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Types Of Decks
In-situ Reinforce
d Concrete
Decks
Precast Concrete Decks
Open Steel Grid
Decks
Timber Decks
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SIMPLE & COMPLEX CONCRETE BRIDGES
Bridge decks are an integral part of the bridge structure by providing the direct riding surface for motor vehicles. In addition, bridge decks directly transfer load from the moving traffic to the major load-carrying members.
In Simple Concrete Bridges, the span of the bridges is simple and straight. Therefore it uses simple formwork for its casting or construction as shown in fig (A).
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Figure (A)
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In Complex concrete bridges, according to International Paper on Complex concrete construction, shapes or geometry of structure is complex. So we need complex arrangement of formwork to get that geometry. For example Reinforced Concrete Box Girder Decks as shown in fig (B).
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Figure (B)
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COMPARISON BETWEEN BOX GIRDER AND T-BEAM GIRDER BRIDGES
A box girder is formed when two web plates are joined by a common flange at both the top and the bottom. The closed cell which is formed has a much greater torsional stiffness than an open section
Span range is more for box bridge girder as compare to T-beam Girder Bridge resulting in comparatively lesser number of piers for the same valley width and hence results in economy.
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Slab bridge decks are useful for short spans
. Box girders are used for spans from 40m up to 300m using either in-situ or precast concrete segmental construction. Box girders produce elegant solutions.
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In-situ Concrete Box Girder Deck
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Precast Concrete Box Girder Decks
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DESIGN CONSIDERATIONS Concrete decks are primarily designed
for flexure in the transverse direction; therefore, the spacing of adjacent girders is important. AASHTO Table A4-1 provides a listing of design moments for “S” (girder spacing) values between 4 ft. and 15 ft.
For the typical deck slab, MTD 10-20 (Caltrans 2008b) provides the minimum deck slab thicknesses and reinforcement schedule for various girder types. The typical deck slab thickness varies from 7 in. to 10 3/8 in. depending on the girder type and spacing.
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The minimum concrete cover is determined in accordance with CA 5.12.3. Extreme environments can have a negative effect on the service life of a concrete deck slab. Corrosion of the reinforcing steel should be a major concern when designing a bridge deck in an extreme environment. MTD 10-5 gives details about Corrosion of steel
For design purposes, the minimum compressive concrete strength fc'=3.6 ksi shall be used for reinforced concrete (CA 5.4.2.1).
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DESIGN APPROACHES Service Limit State
Concrete decks are designed to meet the requirements for Service I limit state (AASHTO 9.5.2). Service limit state is used to control excessive deformation and cracking.
Strength Limit StateConcrete decks must be designed for Strength I limit state. Because concrete deck slabs are usually designed as tension-controlled reinforced concrete components, the resistance factor is Ǿ=0.9 (AASHTO 5.5.4.2). Strength II limit state typically is not checked for deck designs
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Extreme Event Limit StateMost bridge decks include an overhang with a concrete barrier attached. Therefore, the deck overhang has to be designed to meet the requirements for Extreme Event II.
Fatigue Limit StateConcrete decks supported by multi-girder systems are not required to beinvestigated for fatigue (AASHTO 9.5.3).
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ANALYSIS METHODS Approximate Method of Analysis
Caltrans traditionally designs concrete
bridge decks as transverse strips as a flexure member. This method is called the Approximate Method of Analysis (AASHTO 4.6.2.1). The concrete deck is assumed to be transverse slab strips, which is supported by the girders. To simplify the design, it is assumed that the girders are rigid supports.
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Empirical Method of Analysis
Empirical Design (AASHTO 9.7.1) is a method of deck slab design based on the concept of internal arching action within concrete slabs. But, until further durability testing of this design method is completed, the empirical design method is not permitted for concrete bridge deck design in California (CA 9.7.2.2).
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DESIGN METHODOLOGYFollowing are the steps for the design of deck of concrete box girder
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STEP-1 DETERMINATION OF DECK THICKNESS & COVER
Deck Thickness Deck thickness is selected according to
MTD 10-20. The minimum deck thickness varies depending upon the girder typec/c spacing of girders.
Deck Cover Deck cover is determined according to
CA (Caltrans) Table 5.12.3-1. typically top cover is taken as 2 inch whereas bottom cover is taken as 1 inch.
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STEP-2COMPUTATION UN-FACTORED MOMENTS For Dead Loads
The dead load moments for the deck slab, barrier and future wearing surface are computed for a one-foot wide section of the bridge deck using any approved structural analysis method. For e.g Moment Distribution Method or Computer aided analysis
For Live LoadsThe un-factored live load moments are determined from AASHTO Appendix A4, Table A4-1. This table can be used for decks supported on at least three or more girders, in which the minimum superstructure width, between centerline to centerline of exterior girders, cannot be less than 14′-0″.
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STEP-3CALCULATION OF FACTORED DESIGN MOMENTS
Factored moments for Maximum positive and Maximum Negative factored loads is calculated using following equation of strength I load combinations
Ƞ= load Modifier=1 m= Multiple Presence Factor
IM=Dynamic Load Allowance Load factors for dead slab, wearing surface
loads and live loads respectively
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STEP-4POSITIVE FLEXURE DESIGN AND NEGATIVE FLEXURE DESIGN
Maximum Negative Moments and Negative Moments are selected .Then using formulas followings details are calculated
Initially Bar size is assumedRequired Area for reinforcement is
calculatedBar spacing is calculated
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STEP-5 CHECK FOR CRACK CONTROL
Concrete cracking is controlled by the spacing of flexure reinforcement. To improve crack control in the concrete deck, the reinforcement has to be well distributed over the area of maximum tension. Therefore, AASHTO requires steel reinforcement spacing to satisfy the following formula-6:
Where
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STEP-6 TEMPERATURE AND SHRINKAGE REINFORCEMENT
Minimum reinforcement is needed in the slab to distribute the load across the slab, for shrinkage, and temperature change. For the typical slab design, AASHTO requires distribution reinforcement for the top of the slab and the bottom of the slab.
The top of the slab is for shrinkage and temperature reinforcement near the surface of exposed concrete slab. Following Criteria is Used for this Reinf.
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STEP-7 DISTRIBUTION STEEL
Distribution steel is provided at the bottom of slab which also acts as temperature and shrinkage steel. Following criteria is used for design.
S in Meters
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DESIGN EXAMPLE PROBLEM (COMPLEX CONCRETE BRIDGE):- (Design of Concrete Box Girder Type Deck) Given Information: A typical section of a reinforced concrete box
girder bridge is shown in Figure-1Max. Girder Spacing: S = 12 ft.Number of Girders: N = 5Concrete compressive strength: fc' = 3.6 ksi (CA 5.4.2.1)Reinforcement strength: fy = 60 ksiType 732 Concrete Barrier weight: w732 = 0.410 klfFuture wearing surface, wfws = 0.140 kcf (AASHTO Table 3.5.1-1)(Assume 3″ thick asphalt section were, wfws = 0.140 kcf × 0.25ft = 0.035 ksf)Reinforced Concrete unit weight, wrc = 0.150 kcf (AASHTO C3.5.1)
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STEP-1 DETERMINE MINIMUM DECK THICKNESS & COVER According to CA 9.7.1.1 (Caltrans 2008a), the
minimum deck thickness must conform to the deck design standards specified by MTD 10-20 (Caltrans 2008b). The minimum deck thickness varies depending on the girder type and the centerline to centerline spacing. Therefore, for a reinforced concrete box girder bridge,S = 12.00 ft assumes a minimum thickness t = 9 1/8 in.The minimum concrete cover is determined according to CA Table 5.12.3-1. For the top surface of the bridge deck in a non-corrosive atmosphere the minimum cover is specified as:Deck Top Cover: Ctop = 2.0 in.The minimum cover specified for the bottom surface of the deck slab is:Deck Bottom Cover: Cbottom = 1.0 in.
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STEP-2A COMPUTE UN-FACTORED DEAD LOAD MOMENTS
The dead load moments for the deck slab, barrier and future wearing surface are computed for a one-foot wide section of the bridge deck using any approved structural analysis method. This can include the continuous beam equations, moment distribution, or an acceptable computer analysis program. Table-1 lists the tabulated un-factored dead load moments for each bay given in tenth points using a finite element analysis.
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TABLE-1
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STEP-2B COMPUTE UN-FACTORED LIVE LOAD MOMENTS
The un-factored live load moments are determined from AASHTO Appendix A4, Table A4-1. This table can be used for decks supported on at least three or more girders, in which the minimum superstructure width, between centerline to centerline of exterior girders, cannot be less than 14′-0″. The moments are calculated using the equivalent strip method (AASHTO 4.6.2.1.3) for concrete slabs supported on parallel girders. The values given in the table include multiple presence factors and the dynamic load allowance. To be conservative use the largest span length between girders to find the maximum live load force effect.
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STEP-3 CALCULATE THE FACTORED DESIGN MOMENTS
Concrete decks are designed for strength, service and extreme limit states according to AASHTO 9.5. Fatigue and fracture limit states need not be investigated for concrete decks supported by multiple girders (AASHTO 5.5.3 Fatigue Limit State). Therefore,
Strength I Load Combination
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PARAMETERS OF THE FORMULAS
Where, Ƞ= 1 For the slab and barrier (DC): =1.25 (Maximum
Factor) For future wearing surface (DW): =1.50
(Maximum Factor) Multiple Presence Factor =m=1.20 for one lane
of vehicular live load. This value is included in the tabulated moments provided in Table A4-1. Dynamic Load Allowance (M) is also included in Table A4-1 tabulated moments.
=1.75 , For Strength Limits State I
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STEP-3A MAXIMUM POSITIVE FACTORED MOMENTS
Based on Table-1, the maximum un-factored positive moment due to the slab, barrier, and future wearing surface is located in Bay 2 or 3 at a distance of 0.5S. The maximum positive moment equals 8.01 kip-ft./ft, as shown in Section 10.6.5. Therefore, the maximum positive factored moment is
Mu=1.0[(1.25)(0.70+0.13)+(1.5)(0.20)+(1.75)(8.01)] = 15.36 kip-ft./ft.
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STEP-3B MAXIMUM NEGATIVE FACTORED MOMENTS
The maximum un-factored negative moment due to the slab, barrier and future wearing surface is located in Bay 1 at a distance of 0 (center of exterior girder). The negative moment can be reduced at the face of the girder. The negative moment can be interpolated between 0.0S and 0.1S. Based on the reduced negative moments at the interior face of the girder, the maximum negative factored moment is
Mu = 1.0[(1.25)(1.29+1.71)+(1.5)(0.17)+(1.75)(9.40)] = 20.46 kip-ft./ft.
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STEP-4 POSITIVE FLEXURE DESIGNTo design for the maximum positive moment, first, assume
an initial bar size. From this initial bar size, the required area of steel can be calculated. Then the reinforcement spacing can be determined. For this example the assumed initial reinforcing steel size is #5. For a #5-bar,Bar area = 0.31 in2Bar diameter = 0.625 in.Next, determine the effective depth (de), which is equal to the total slab thickness minus the bottom cover, Cbottom , and minus half the bar diameter. Figure-2 shows the relationship between the effective depth and the slab thickness.
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Figure-2 Simple Rectangular Concrete Section with Tension Reinforcement.
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For a rectangular section, assume, where a is the depth of the equivalent stress block, and t is the deck thickness. Solve for the required amount of reinforcement, as follows:
Where, b=12in
Putting Values, we get z = 9.56 in²
As = 0.459 in²
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Check
Next Determine the spacing between Bars
Use 8 inch spacing for #5 Bars.
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To verify that tension controls the section design and that the proper resistance factor is used to check the strain in the extreme tension reinforcing steel (AASHTO CA 5.7.2.1). The strain, stress and force diagrams for a rectangular concrete section are shown in Figure-3.
Fig-3 Development of Bending Strain, Stress, and Force Actions in a Section.
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The steel yields and the section is tension controlled, therefore, the proper resistance factor was used.
Finally, check maximum spacing for primary reinforcement (AASHTO 5.10.3.2). The spacing of the slab reinforcement shall not exceed 1.5 times the thickness of the
slab or 18.0 in.
In this case the maximum spacing equals 8.0 in., which is less than either case.
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STEP-5 NEGATIVE FLEXURE DESIGN
Designing for the maximum negative flexure reinforcement is similar to designing for the maximum positive moment reinforcement. These bars are the primary reinforcing steel over the girders as shown in Figure-4.
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Assuming #6 bar size.Bar area =0.44 in²Bar diameter =0.750 in.The effective depth, de , for the negative moment is equal to the total slab thickness minus the top cover, C(top) , and half the bar diameter.
Based on the maximum negative momentz =8.262 in².A s =0.740 in²
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Required Bar Spacing is
Use 7 in Spacing for #6 bar size.
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STEP-6 CHECK FOR CRACK CONTROL UNDER SERVICE LIMIT STATE
Concrete cracking is controlled by the spacing of flexure reinforcement. To improve crack control in the concrete deck, the reinforcement has to be well distributed over the area of maximum tension. Therefore, AASHTO requires steel reinforcement spacing to satisfy the following formula:
In which
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STEP-6A DETERMINE MAXIMUM LOADING UNDER SERVICE LIMIT STATE
Service I load combination
Positve moment due to service loading
Negative moment due to service loading:
Note: Negative Service Loading Controls
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STEP-6B DETERMINE MAXIMUM REQUIRED SPACING FOR CRACK CONTROL
Determine the neutral axis location, y, based on the transformed section properties.
So
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Where,
Calculate the crack moment of inertia, Icr , for the transformed section.
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Next, calculate the tensile stress, fss , in the steel reinforcement at service limit state
Finally, determine βs , and then input that value into the formula-6 to calculate the maximum spacing, s, of the reinforcement that would satisfy the LRFD crack control requirement.
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To convert the required spacing to Caltrans’ Standard Plan Bridge Details, we must multiply the spacing by 2. This is due to the fact that the transverse deck reinforcement spacing diagrams add an extra top bar for the given spacing. Therefore, if the required calculated spacing is 5.29 in., then the spacing shown on the typical section would be 10.58 in. In the design example case, we would specify #6 @ S = 10 1/2 in.
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STEP-7 MINIMUM REINFORCEMENT
Minimum reinforcement is needed in the slab to distribute the load across the slab, for shrinkage, and temperature change. For the typical slab design, AASHTO requires distribution reinforcement for the top of the slab and the bottom of the slab.
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STEP-7A TOP OF SLAB SHRINKAGE AND TEMPERATURE REINFORCEMENT
The top slab reinforcement is for shrinkage and temperature changes near the surface of the exposed concrete slab. The area of reinforcement has to meet the following requirements:
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For the design example slab:
Therefore, As = 0.11 as a minimum. Use #4 bars in top slab.
Bar area = 0.2 in².Bar Spacing=12(0.2)/0.11=21.8in
Use maximum 18.0 in.
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STEP-7B BOTTOM OF SLAB DISTRIBUTION REINFORCEMENT
The reinforcement in the bottom of the slab is a percentage of the primary deck reinforcement. The primary deck reinforcement is perpendicular to the direction of traffic, therefore, the requirement is 220/S≤ 67 percent, where S is the effective span length (ft.) as specified in Article 9.7.2.3. For the design example, the effective span length is the clear distance from face of girder to face of girder, which is 11 ft.
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To facilitate better lateral load distribution, Caltrans’ Reinforced Concrete Technical Committee recommends that the bottom deck reinforcement be placed within the center half of the deck span. Therefore,
Twelve bars are distributed within 1/2 the effective span length. Compared this with the standard Deck Slab Reinforcement Details “G” bars and “D” bars per MTD Table 10-20.1(a): The required “G” bars for 12′-0″ girder spacing are 5 - #4
barsThe required “D” bars for 12′-0″ girder spacing are 13 - #5 bars
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Figure-6 Bridge Deck Reinforcement Details
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