20150301 e2 seismic leaflet en
TRANSCRIPT
Hilti Corporation I 9494 Schaan I Liechtenstein I P +423-234 2111 I F +423-234 2965 I www.hilti.com/seismic
Hilti. Outperform. Outlast.
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Everything you require for easy and reliable seismic specifications.
Post-installed anchoring
Fastening structural and non-struc-tural elements according to new Eu-ropean regulations.
Ventilated facade
Aluminum sub construction for light ventilated façade systems, system tested for seismic applications.
Firestop
Solutions for pipe and cable penetra-tions through floors or walls, and for fire rated joint seals to reduce post earthquake impacts.
Post-installed rebar
Injectable mortar and everything re-quired for the safe installation of con-crete-to-concrete connections.
Installation systems
Maximum safety assured by expert design and the use of Hilti standard pre-design solutions.
Structure detection
PS 250 and PS 1000 - Compact, cordless and complete system quickly operational and simple to operate to detect rebar in order not to hit them during drilling.
Siding and decking
Nails and screws tested in accordance with the new AC 70 american standard.
Hilti engineering services
A team of qualified and experienced engineers is available to provide you with more detailed information and to help you determine and design the best solution for your particular project. Contact them by phone at 01 30 12 65 01 (from 8h30 to 12h30 and from 13h30 to 17h00), by fax at 01 30 12 52 40 or by e-mail at [email protected]
Hilti. Outperform. Outlast.
IN SEISMIC DESIGN.
HILTI PARTNER OF SPECIFYERS
Page 2 I Edition march 2015 www.hilti.fr/le-risque-sismique
Seismic design and specification of seismic products is crucial in both structural and non-structural applications.
Seismic-relevant structural applicationsStructural connections are vital to ensure that the structure responds to a seismic event in a proper, predictable manner. Connections should therefore be clearly detailed in the design phase to make certain that both contractors and building inspectors comprehend project specifications.Firm, well thought out specifications are the best way to ensure that the designed product is the one that is actually used.
Seismic retrofitting (e.g. bracings, shear reinforcement)
Structural steel element connections to concrete
Post-installed rebar connections
Shear wall fastenings
Siding and decking and roofing on metallic structure
Seismic-relevant non-structural applicationsAnchors are often used to fasten non-structural components. Their design and selection is therefore crucial in terms of minimi-zing both injuries to building occupants and the costs associated with seismic events.As fire is a common byproduct of earthquakes, firestop systems should be specified in accordance with their ability to withstand extreme deformation.
Secondary steel connections and fastenings for utilities
Equipments
Mechanical and electrical supports
Ventilated façade systems and curtain walls
Firestop cable and pipe penetrations and joints
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Hilti solution for earthquake applications
www.hilti.fr/le-risque-sismique Edition march 2015 I Page 3
Seismic design and specification of seismic products is crucial in both structural and non-structural applications.
Source: Taghavi S. and Miranda E.: “Seismic Performance and Loss Assessment of Nonstructural Building Components,” Proceedings of 7th National Conference on Earthquake Engineering, Boston, 2002.
Average Concrete Building
Repair costs resulting from a seismic event
Nonstructural
Contents
Office Hotel Hospital
18%20%
62%
13%17%
70%
8%
44% 48%
20%40%
40%
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3
7
4
10
8
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Structural
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Page 4 I Edition march 2015 www.hilti.fr/le-risque-sismique
New European testing procedure for determining the seismic suitability of fasteningsThe seismic pre-qualification of anchors has been regulated since early 2013 in Europe following the release of ETAG 001 Annex E. Anchors subject to this new test procedure must now incorporate in the ETA all the required seismic design technical data . The suitability for seismic loading is classified as:
ETA seismic category C1 – similar to U.S. pre-qualification procedure; only suitable for non-structural applications according to the EOTA TR045 recommendations
ETA seismic category C2 – arduous seismic crack movement tests qualify an anchor as suitable for more demanding structural and non-structural applications
New rating classifications for anchor perfor-mance under seismic load: C1 and C2
Structural applications
Acceleration (ag.S) Building importance II, III, IV
< 0.05g non-seismic
0.05g to 0.1gETA C2
> 0.1g
Non-structural applications
Acceleration (ag.S) Building importanceII, III
Building importanceIV
< 0.05g non-seismic
0.05g to 0.1g ETA C1ETA C2
> 0.1g ETA C2
The map above is based on national earthquake data (for ordinary buildings and ground type A) and provides perspective on the relevance of the new ETA guidelines in various countries. For more precise information see national regulations.
Hilti solution for earthquake applications
www.hilti.fr/le-risque-sismique Edition march 2015 I Page 5
a1) Capacity designThe anchorage is designed for the force corresponding to the yield of a ductile component or, if lower, the maximum force that can be transferred by the fixture or the attached element.
a2) Elastic designThe fastening is designed for the maximum load assuming an elastic behavior of the fastening and of the structure.
b) Design with requirements on the ductility of the anchorsThis design for ductile steel failure requires an anchor classified as ductile. Additionally, this approach is applicable only for the tension component and some provisions require to be observed in order to ensure that the cause of failure is steel failure.
Post-installed anchor seismic design
EOTA TR045 sets the fastening seismic design standardEOTA TR045 sets the standard for the seismic design of steel-to-concrete connections until the new EN 1992-4 is released (release date pending confirmation). This code is in full compliance with the standards in the new ETAG 001 Annex E.
Three design optionsThe design code incorporates three design approaches which are described below. Note that all three of these approaches are acceptable within their application conditions.
Hilti seismic qualified anchors
M8 M10 M12 M16 M20 M24 M30ETA seismic category C1 and C2
HIT-HY 200-A mortar + HIT-Z rod (galvanised and stainless)
ETA 12/0006 15/03/2013C1 C1 C1 C1 C1
C2 C2
HST stud anchor (galvanised and stainless) ETA 98/0001 08/05/2013
C1 C1 C1
C2 C2 C2
HDA undercut anchor (galvanised and stainless) ETA 99/0009 06/01/2015
C1 C1 C1 C1
C2 C2 C2 C2
ETA seismic category C1HIT-HY 200-A mortar + HIT-V rod (galvanised and stainless)
ETA 11/0493 20/06/2013 C1 C1 C1 C1 C1 C1 C1
HIT-RE 500-SD mortar + HIT-V rod and HIS-N sleeve (galvanised and stainless)
ETA 07/0260 16/05/2013 C1 C1 C1 C1 C1 C1 C1
HUS3-H, HUS3-C screw anchor (galvanised)HUS-HR screw anchor (stainless)
ETA 13/1038
ETA 08/0307
13/01/2015 29/04/2014
C1 * C1 * C1 *
Post installed anchor accessoryHilti dynamic set Filling washer, conical washer, nut and lock-nut.
Doubles shear resistance and prevents loosening.
* HUS3-H, HUS3-C, HUS-HR screw anchors are available in size 8, 10 and 14.
Page 6 I Edition march 2015 www.hilti.fr/le-risque-sismique
Design tools
Design is further simplified by Hilti’s own PROFIS software, which allows users to design fastening systems and rebar connections easily and in accordance with the state-of-the art seismic code framework.
Additionally, the printed version of the Fastening Technical Manual (FTM) provides all technical data for both anchoring and rebar connections.
PROFIS Anchor
Structural rebar applicationsApproved per CSTB seismic pre-qualification
Post-installed structural rebarReinforced concrete design assumes that concrete has negligible tensile strength while allowing for the design of rebar development length and avoiding brittle concrete failure, in the following two situations:• Transferring tensile loads from one bar to another (overlap splice)• Development length of the tensile force in a bar beyond a node in equilibrium
Seismic structural rebar approvalFrench DTA approvals delivered by CSTB, a member of EOTA, recognizes Hilti HIT-RE 500-SD and HIT-HY 200-A injectable mortars as products qualified for structural rebar applications in seismic zones. By applying engineering judgment, engineers can use this French approval when designing seismic structural post-installed rebar connections.
Included in the DTAs• The design bond strength fbd,seism of Hilti mortar considered for use in seismic zones• Formatted data for design with Eurocode 2 and Eurocode 8• Application limit information (e.g. transverse reinforcement, settings instructions)
DTA seismic approval
Hilti HIT-RE 500-SD Slow-curing anchor mortar.CSTB approval DTA 3/13-746 for seismic rebar applications.
FTM
Hilti HIT-HY 200-A fast-curing anchor mortar.CSTB approval DTA 3/13-749 for seismic rebar applications.
Hilti solution for earthquake applications
www.hilti.fr/le-risque-sismique Edition march 2015 I Page 7
PROFIS Rebar FTMDedicated web page for specifyers
Siding, decking and roofing applicationsTested according to AC 70 acceptance criteria
The screws and nails are not covered by any regulation in Europe as far as seis-mic behaviour is covered. Nevertheless, on seismic jobsite, the specifyer is quite often ask to justify also these fastenings.
Reason why Hilti has decided to test some nails and screw according to the quite new AC 70 american acceptance criteria which contains seismic test for nails on metallic base material.
If the resistances after the test are not more than 20% below the initial values, the fastening may be qualified for siesmic application without any loss of perfor-mance. This is similar to the C1 criteria for anchors.
Nails and screw seismic tested
Hilti X-ENP 19 Holds the most approvals worldwide for siding and decking
Hilti X-BT designed to create a weld to the base material for an extremely strong hold and high loading capacity
Hilti S-MD 31 PS, S-MD 33 PS For fastening of venitlated facade panels on aluminium structure
Page 8 I Edition march 2015 www.hilti.fr/le-risque-sismique
Recommanded firestop products in seismic
Fires following earthquakes represent a major risk, both for the safety of human lives and for the protection of facilities and assets.
After an earthquake, fire, smoke and water damage can cause severe problems including:
■ Damage to mechanical and electrical equipment■ Breaking/leaks in pipe systems■ Damage to electrical lines, including emergency equipment, lighting■ Damaged communication networks■ Gas leaks, creating an explosion risk■ Blocked, unusable escape routes
Once these problems have been managed there will also be a need for repair, maintenance and reinspection.Hilti seismic testsHilti has conducted extensive tests to determine the behavior of firestop products in a seismic event while taking fire integrity and smoke tightness issues in a post-earthquake environment into consideration. Test setup The quasi-static cyclic loads according to FEMA 461* protocol were applied directly on the penetrants, whereas the wall was fixed. Tests were carried out in x-direction (load in same direction as the penetrant), in y-direction (load perpendicular to the penetrant) and in z-direction (rotation with the center in the wall layer). Air/gas tightness was measured during the test with a pressure testing device to reach measurable conclusions about damages of the penetration seal. After the seismic test an additional firestop test was conducted to evaluate permeability of smoke and fire integrity of the relevant firestop system. ResultsSignificant factors that were measured: displacement (mm), movement force, pressure drop (Pa/min), start of pressure drop (mm), % pressure drop, plastic deformation of penetrant (kN), absolute pressure at start (Pa).Determining factors: flexibility-elasticity, adhesion, tightness, damage to penetrants, installation reliability.Outcome: recommendations for suitable and non-suitable firestop products, installation and design recommendations. * Federal Emergency Management Agency: Code for interim testing protocol for determining the seismic performance characteristics of structural and non-structural components.
Cable penetration
Firestop foam Hilti CFS-F FX Firestop acrylic sealant CFS-S ACR
Firestop block Hilti CFS-BL Firestop plug Hilti CFS-PL
Pipe penetration
Firestop collar Hilti CFS-C P
Joints
Firestop acrylic sealant CFS-S ACRFirestop silicone sealant CFS-S SIL
Firestop spray CFS-SP ACRFor joints applications and curtain walls
Firestop sleeve Hilti CFS-SL Firestop endless collar Hilti CFS-C EL
Hilti solution for earthquake applications
www.hilti.fr/le-risque-sismique Edition march 2015 I Page 9
Sub-structures for ventilated facade has been tested in seismic
Brackets
Bracket MFT-MFI MFor sliding point
L Profile In Aluminium, thickness 2,0 mm and 2,5 mm
Bracket MFT-MFI LFor fixed point
Profiles
T Profile In Aluminium, thickness 2,0 mm and 2,5 mm
Ventilated facade present a risk of falling down in case of earthquake. The French state of the art defines a
seismic test method for the entire system.
A design method based on EN 1998-1-1 (Eurocode 8) for non structural elements is also defined
(document CSTB 3725 dated January 2013).
For more information, please contact our technical back office.
Required displacement
Gliders
Required displacement
Test setup Three tests are defined:
■ Parallelogram test: This test is performed to observe the behaviour of the system to follow the movement of the building on which it is fixed. The ventilated facade is installed on a rigid frame (3 000 x 3 000 mm) fixed on the bottom. The support is gradually deformed in its plane (parallelogram) by a static displacement applied at the head according to the cycles predefined. The maximum displacement is ± 60 mm. A visual control is done on fall elements, breakage or deformation of a component system.
■ Dynamic test: This test is to observe the behavior of the system when the support on which it is mounted is moving in its plane under the action a cyclic reciprocating motion imposed. The ventilated facade is installed on a rigid frame (3 000 x 3 000 mm) on gliders. Cycles of movements are applied around the frequency of the system. The maximum displacement is ± 60 mm. A visual control is done on fall elements, breakage or deformation of a component system.
■ Dynamic perpendicular test: This test is the same as the dynamci test with movement perpendilar to its plane
Parallelogram test
Dynamic test
Page 10 I Edition march 2015 www.hilti.fr/le-risque-sismique
Installation systems need to be designed specifically to resist of seismic loads
PipesFor pipes installation, the basic principle is that the fastenings have to be designed so that the horizontal seismic loads can be taken in addition to the gravity forces.To take horizontal forces, the pipe fastenings must either be designed to be sufficiently flexurally stiff, or have bracing that can transfer the horizontal forces (Fh). It must be ensured that horizontal loads can be taken transversely and longitudinally in relation to the pipe axis.
Horizontal seismic forces Fh,x transverse in relation to pipe axisHorizontal seismic forces Fh,y in direction of pipe axis
Threaded rods
Hinge MQS-AB For bracing of threated rod to base material
Channels
Hinge MQS-AC For bracing of channel to base material or to angleExist in renforced version MQS-ACD
Angle MQS-W For connecting two channelsCan be installed on MQ 41, MQ 72, MQ 41 D
Hinge MQS-H For connecting two threaded rods
Hilti solution for earthquake applications
www.hilti.fr/le-risque-sismique Edition march 2015 I Page 11
Seismic bracing
Braces for a earthquake-resistant installation need to be arranged at a distance (b) from each other that must be assessed in relation to seismic acceleration, the mass of the pipes or (system in general) and the type of braces itself - i.e. the situation of the seismic brace respect to the main axis of the pipe. For this reason, we can distinguish three basic types of seismic-resistant media:■ Longitudinal bracing: seismic brace arranged longitudinally to the main direction of the plant - resistance to horizontal actions acting
along the main axis of the pipe■ Transversal bracing: seismic brace perpendicular to the main direction of the plant - resistance to horizontal actions acting transversely
of the pipe■ 4-way bracing: structure composed of both longitudinal and transversal braces, therefore able to withstand all of the forces acting on
the horizontal plane.
It is advantageous for the bracing to be at a spacing that is a multiple of the normal pipe fastening spacing of (s), so that, for example, every third or fourth pipe fastening is braced.
Design tools Manuel techniqueSystème de supportage
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édition Février 2014
Hilti France I 1 rue Jean Mermoz I 78778 Magny les Hameaux I T +33 1 30 12 50 00 I F + 33 1 30 12 50 12 I www.hilti.fr© 02/2014 I Hilti = marque déposée du Groupe Hilti. Photos et textes non contractuels, sous réserve d’erreur typographique I MK homologation I Ref 2038 I 4 000 ex.
Hilti. Performance. Fiabilité. Service client 0 825 01 05 05
Design is further simplified by Hilti PROFIS Installation, which helps users to design installation systems easily and in accordance with the state-of-the art code.
Additionally, the Installation systems catalogue provides all technical data for all products MM, MQ and MI.Download the latest version of Hilti PROFIS Installation and the technical data sheets from www.hilti.com.
Catalogue
Single pipe applicationTransversal bracing
Single pipe applicationLongitudinal bracing
Trapeze with threated rodsTransversal bracing
Trapeze with threated rodsLongitudinal bracing
Trapeze with threated rods4 ways bracing
PROFIS Installation