6 Appendix 2 11.1 Concrete overlay connection 315 11.1.1 Application range 315 11.1.2 Advantages of the method 315 11.2 Design of interface 317 11.2.1 Basic considerations 317 11.2.2 Ultimate limit state for shear transfer at the interface 317 11.2.3 Design shear force acting longitudinally at interface, V Sd 322 11.2.4 Serviceability limit state 323 11.2.5 Additional rules and detailing provisions 323 11.3 Examples 326 11.3.1 Example: Double-span slab 326 11.3.2 Example: Double-span beam with new slab 329 11.4 Test results 331 11.4.1 Transfer of shear across a concrete crack 331 11.4.2 Laboratory tests by Hilti Corporate Research 331 11.4.3 Working principle of connectors 332 11.4.4 Comparison with international test results 333 11.5 Notations 334 11.6 Reference literature 335 12. Injection mortar Hit HY 150 and HAS rod with nut or headplate 336 12.1 Terms 336 12.2 Data for the calculation 337 12.3 Minimum steel content for V ed 338 12.4 Product Information 342 6 314
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6 Appendix 2
11.1 Concrete overlay connection 315
11.1.1 Application range 315
11.1.2 Advantages of the method 315
11.2 Design of interface 317
11.2.1 Basic considerations 317
11.2.2 Ultimate limit state for shear transfer at the interface 317
11.2.3 Design shear force acting longitudinally at interface, VSd 322
11.2.4 Serviceability limit state 323
11.2.5 Additional rules and detailing provisions 323
11.3 Examples 326
11.3.1 Example: Double-span slab 326
11.3.2 Example: Double-span beam with new slab 329
11.4 Test results 331
11.4.1 Transfer of shear across a concrete crack 331
11.4.2 Laboratory tests by Hilti Corporate Research 331
11.4.3 Working principle of connectors 332
11.4.4 Comparison with international test results 333
11.5 Notations 334
11.6 Reference literature 335
12. Injection mortar Hit HY 150 and HAS rod with nut or headplate 336
12.1 Terms 336
12.2 Data for the calculation 337
12.3 Minimum steel content for Ved 338
12.4 Product Information 342
6
314
Connections for concrete overlays
11.1.1 Application rangeIf a new layer of concrete is applied to existing concrete withthe aim of strengthening or repairing a structure, reference ismade to a composite concrete structure. This overlay isusually cast directly or placed as shotcrete. It functions toaugment the flexural compression or flexural tension zones,depending on the placement. Prior to placement of the over-lay, the surface of the old concrete member is prepared bysuitable means and pre-wetted. Shrinkage of the new con-crete overlay can be reduced by careful selection of the con-crete mix. Forces of constraint caused by differential shrin-kage and, possibly, by differential temperature gradientscannot be avoided, however. Initially, stresses in the bond in-terface result from a combination of external loads and inter-nal forces of constraint. It must be borne in mind that stres-ses due to shrinkage and temperature gradients in the newconcrete typically reach their maximum at the perimeter(peeling forces). The combination of external and internalstresses often exceeds the capacity of the initial bond, thusrequiring the designer to allow for a de-bonded interface.This is particularly true in the case of bridge overlays whichare subject to fatigue stresses resulting from traffic loads. Furthermore, these stresses are dependent on time, and bond failure can take place years after overlayplacement. When this happens, the tensile forces set up must be taken up by reinforcement or connectorspositioned across the interface. Typical examples are shown schematically in Figures 1 and 2.
11.1.2 Advantages of the method➥ Simple and reliable application to a variety of cases➥ Monolithic structural component behavior assured➥ Shear forces are reliably transferred even if the interface is cracked➥ Suitable for use with the most common methods of surface roughening➥ Reduced requirements for anchor embedment
Repairing a bridge pavement
• Removal of damaged concrete layer using high-pressure water jetting
• Anchoring of additional reinforcement using HIT-HY 150
• Installation of shear connectors using HIT-HY 150• Placement of new concrete overlay
✔ Monolithic load-bearing behavior✔ Reliable transfer of shear✔ Stiff connection✔ Reduced anchor embedment
existingconcrete
new concrete
Figure 1: Strengthening a bridge deck
Case A:new concrete overlay
Case B:new concrete with additional tensile reinforcement
Figure 2: Strengthening a building floor
11 Appendix 2
11.1 Concrete overlay connection
315
6
Connections for concrete overlays
316
Strengthening the floor of an industrial building• Removal of covering and any loose overlay• Roughening of surface by shot-blasting• Installation of connectors using HIT-HY 150
according to the engineer's instructions• Inspection, if necessary, of concrete surface for
roughness and pull-away strength, and of connectors for pull-out strength
Repair and strengthening with shotcrete• Roughening of concrete surface• Installation of shear connectors using HIT-HY 150• Placement of reinforcement and overlay concrete
11.2.1 Basic considerationsStructures made of reinforced concrete or prestressed concrete which have a concrete overlay at least40 mm thick ([2], Section 2.5.3.5.8 (109)), or at least 60 mm thick on bridge structures, may be designedas monolithic building components if shear forces at the interface between the new and the old concre-te are resisted in accordance with the following rules:
11.2.2 Ultimate limit state for shear transfer at the interface11.2.2.1 Principle and set-up of the modelActions at the interface between new and old concrete are determined from the overall forces acting onthe entire building component.As a rule for the design, it must be assumed that the interface is de-bonded.Reinforcement or connectors crossing the interface surface must be placed in such a way that shearforces at the interface are transferred in the ultimate limit state.
As a result of the separation of the interface surfa-ces, connectors are subjected to a tensile forceand simultaneously to a bending moment depen-ding on the roughness of the interface surfaces.If the surfaces are roughened, additional in-terlocking effects and cohesion can take up part ofthe shear force at the interface.
11.2.2.2 Design shear resistance at interface, VRd
(1)
Where:
(2)
VRd design shear resistance at interfaceVSd design shear force acting at interface as per section 11.2.3�Rdj design shear strength at interface under consideration as per Formula (3) and Diagrams 1 to 3bj effective width of interface under considerationlj effective length of interface under consideration
“Interlock”(friction, cohesion)
“Pull-out”(friction)
“Dowel”(bending,
shearforce)
VRd >_ VSd
VRd = �Rdj · bj · Ij
6
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318
11.2.2.3 Design shear strength at interface, �Rdj
Formula (3) is used to calculate the design shear strength at the interface, �Rdj [6]. When doing so, an up-per limit is given by the design strength in the concrete struts:
(3)
Where:�Rd basic design shear strength of concrete as per [1], Section 4.3.2.3 (the smaller value
of new or old concrete), refer also to Table 2.kT cohesion factor as per Table 1� coefficient of friction as per Table 1� coefficient for effective tensile force in the connector as per Table 1� coefficient for effective dowel action as per Table 1� coefficient for effective concrete strength as per Table 1� efficiency factor as per [1], Formula (4.20); also refer to Table 2.� = As / bj lj reinforcing ratio corresponding to connectors of interface under consideration�n _< 0,6 fcd normal stress certainly acting on interface (positive compression)fyd design value of yield strength of connectorfcd design value of cylinder compressive strength of concrete (smaller value of new or old
concrete)Rt mean depth of interface roughness, measured according to the sand-patch method [9]
11.2.3 Design shear force acting longitudinally at interface, VSd
Normally, VSd is calculated from the bending resistance of the cross-section. (Shear failure of the mem-ber should not govern.)
11.2.3.1 Augmentation of compression zone
(4)
0,8 Reduction factor for non-rectangular stressdistribution
� = 0,85 Reduction factor for sustained compression
for: x > tnew as an approximation:
(5)
11.2.3.2 Augmentation of tension zone
(6)
If the reinforcement is staggered: allow for gradation
11.2.3.3 Shear force to be transferred at overlay perimeterAt the edges of a new concrete overlay, the design must consider a minimum tensile force Fcr. Here, particular attention must be paid to transferring the moment arising from Fcr:
(7)
Fcr tensile force effective in the overlay at the time when the cracks may first beexpected to occur, as per [1], Section 4.4.2.2
k = 0,8 for tnew _< 30 cm coefficient to allow for non-uniform self-equilibrating stressesfct,eff tensile strength of overlay effective at the time when the cracks may first be
expected to occur as per [1], Section 4.4.2.2 (for general cases: fct,eff = 3 N/mm2)
The following values may be used without further verification:
(8)
(9)
Ved shear force at interface derived from FcrNed tensile force resulting from moment of Fcr
Ved may be distributed uniformly over the length le:a) le = 3 tnew for rough surfacesb) le = 6 tnew for sand-blasted surfacesc) le = 9 tnew for smooth surfaces
Vcd = 0,8 · x · bnew · � · fcd + Ase,new · fyd
Vcd = tnew · bnew · � · fcd + Ase,new · fyd
Vtd = Ase, new · fyd
Fcr = tnew · b · k · fct,eff
Ved = Fcr
Ned =Ved c _< 1.5 · tnew––––– ;6
x
tnewAse, newOverlay
Existing concrete
Vtd
tnew
As
Overlay
Existing concrete
Ved
Ved
Ned
c
le
xtnew
As
Ase, new neutral axis
overlay
existing concrete
Vcd
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323
11.2.3.4 Regions without connectorsFor low shear stresses, connectors need not be used in the field of the overlay if the load is predomi-nantly static and if connectors are positioned around the perimeter in accordance with Section 11.2.3.3.
a) With surfaces blasted with a high-pressure water jet and scored surfaces, for
(10)
b) With clean, sand-blasted surfaces, provided that no tensile stresses set up by external forces per-pendicular to the interface are acting (assuming a non-cracked interface), for:
(11)
11.2.4 Serviceability limit stateAs an approximation for normal cases, the additional deformation of a strengthened bending elementmay be determined using the monolithic cross-section and then increased as follows:
(12)
weff additional deformation calculated for the reinforced section considering the flexibility of theconnectors
wcalc additional deformation calculated for the reinforced section assuming perfect bond factor per Table 3sd displacement of connectors under the mean permanent load (FP ~~ 0.5 Fuk)
The displacement, sd, per Table 3, can be used for more accurate calculations.
Table 3: Coefficients for calculation of deformation dia. = diameter of connectors
11.2.5 Additional rules and detailing provisions
11.2.5.1 Mixed surface treatmentsVariable surface treatments may only be used on the same building component if the different stiffnes-ses of the connections are taken into account. (See also Table 3, displacement sd.) Note that a non-cracked interface, i.e., rigid bond, is assumed for interfaces with small shear stresses not requiring fieldconnectors, as per Section 11.2.3.4.
11.2.5.2 Minimum amount of reinforcement at the interfaceThe following minimum amount of reinforcement passing through the interface must be provided ifconnectors cannot be omitted as described in Section 11.2.3.4:
1) Slabs and other structures in which no shear reinforcement is necessary:a) For rough interface surfaces (high-pressure water jet and scored): � _> 0.08%b) For sand-blasted interface surfaces � _> 0.12%c) For smooth interface surfaces: � _> 0.12%
2) Beams and other structures with shear reinforcement as per [1], Section 5.4.2.2
�Sd _< kT · �Rd + � · �n
�Sd _< �Rd + � · �n
weff = · wcalc
Surface treatment Mean roughness Rt mm� sd mm�
High-pressure water jets / Scoring > 3.0 1.0 ≈ 0.005 dia.Sand-blasting / Chipping hammer > 0.5 1.1 ≈ 0.015 dia.Smooth: wood forms /steel forms/ no forms – 1.2 ≈ 0.030 dia.
6
Connections for concrete overlays
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11.2.5.3 Layout of connectors
(1) The connectors must be positioned in the load-bearing direction of the building component withrespect to the distribution of the acting shear force in such a way that both the shear force at theinterface can be taken up and de-bonding of the new concrete overlay is prevented.
(2) In sand-blasted and smooth surfaces, the connectors may be equidistantly positioned over the corre-sponding length, lj, between neighboring critical sections when the load is predominantly static. Accor-ding to [3], Section 4.1.2 (4), critical sections are points subject to maximum bending moments, supportpoints, points where concentrated loads are acting and points with sudden changes in cross-section.
(3) If the new concrete overlay is on the tension side of the load-bearing component, the connectorsmust be distributed according to the graduation of the longitudinal reinforcement without makingany allowance for anchorage lengths.
(4) The connector spacing in the load-bearing direction may not be larger than 6 times the thickness ofthe new concrete overlay, or 800 mm.
11.2.5.4 Anchorage of connectors in the old and the new concrete(1) The connectors must be adequately embedded in the old concrete and the new overlay. The ac-
tually anchored tensile force, Nd, may be assumed to be:
(13)
� = coefficient as per Table 1.
(2) The type of application is decisive when determining the anchorage depth in the base material:(2a) Zones with shear reinforcement or other connecting reinforcement (Figure 7):
The basic value of anchorage depth, lb, must be determined according to (Appendix 2). The mini-mum anchorage depth is 10 times the diameter.It must be borne in mind that this generally concerns an overlap of the connector and existing rein-forcement (ls = �1 · lb, see [1], Section 5.2.4).Furthermore, the tensile force from the trussed-frame analogy as per [1], Section 4.3.2.4 must beverified for building components with required shear reinforcement.
(2b) Zones without shear reinforcement (VSd ≤ VRd1) or any other connecting reinforcement (Figure 8):The anchorage depth must be determined as per (Appendix 2). The edge distances and spacing(c1, s) of adhesive anchors must be ascertained according to anchor design.Cracks in concrete generally reduce the tensile loading capacity of adhesive anchors. If cracking isanticipated, the anchorage depth must be increased, e.g., in the case of pure tensile reinforcementor strengthening for bending with high shear force near beam supports or for concentrated loads.
(3) Plates, nuts or forged-on heads can be used to reduce the anchorage depth of connectors in a newconcrete overlay. If such a connector is used, the following checks must be made:a) Concrete cone failure must be checked in accordance with [5], Section 15.1.2.4.Sufficient reinforcement against splitting must be provided to take up splitting forces set up locallyat the top of the connectors. Calculation of the splitting forces may be based on a truss frameworkmodel which has a line of compressive action at an angle of 45º.Normally, the connectors should extend into the upper reinforcement of the concrete overlay andform a truss framework node there.b) The concrete bearing pressure under the head is limited as per [5] Section 15.1.2.3, or [1], Section 5.4.8.1.
(4) If interface surfaces are smooth, connectors must be provided with an embedment of at least 6 diameters (9 diameters recommended).
11.2.5.5 Minimum reinforcement in overlayThe procedure in [1] must be adopted to determine the minimum amount of reinforcement in the con-crete overlay.Beams: [1], Section 5.4.2.1.1 and 5.4.2.4Slabs: [1], Section 5.4.3.2.1
11.2.5.6 Recommendation for overlay placementPre-treatment:A primer consisting of thick cement mortar is recommended.The old concrete should be adequately pre-wetted (24 hours earlier the first time) before applying thecement mortar primer. At the time of placing the primer, the concrete surface should have dried to suchan extent that it has only a dull moist appearance.The mortar used as primer should consist of water and equal parts by weight of Portland cement andsand of particle size 0/2 mm. This mortar is then applied to the prepared concrete surface and brushed in.Overlay:The concrete mix for the overlay should normally be such that a low-shrinkage concrete results (W/C ≤ 0.40). The overlay must be placed on the still fresh primer i.e. wet on wet.Curing:Careful follow-up is necessary to ensure good durability of the overlay. Starting immediately after place-ment, the concrete overlay must be protected for a sufficiently long period, but at least five days,against drying out and excessive cooling.
11.2.5.7 Recommendation for surface treatment specification The roughness of the interface surface has a decisive influence on the shear force that can be transfer-red. In the case of this design process, the dimension to be measured is the mean depth of roughness,Rt, measured according to the sand-patch method [7]. It must be borne in mind that Rt is a mean valueand thus the difference between the peaks and valleys is about 2Rt.It is recommended that a mean depth of roughness, Rt, be stipulated when specifying the interface sur-face treatment. Prior to approving the treatment, a sample surface must be made and this then checkedon the basis of the sand-patch method.
6
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326
11.3 Examples
11.3.1 Example: Double-span slabGiven:Concrete: Overlay: 70 mm: C 30/37
Old concrete 150 mm: C 25/30Reinforcement: S500, fyk = 500 N/mm2
Span: Ase+ = 1’030 mm2/m
Support: Ase– = 1’420 mm2/m
Cracking tensile force at edge (11.2.3.3):Ved = 70 · 1 · 0.8 · 3 = 168 kN/m
➥ As = 0.0016 · 420 · 1000 = 672 mm2/m➡ selected: dia. 8 s = 200/150 mm
Forces to be anchored: same as a)
Bond shear stresses at sand-blasted interface surface:
2360 3640
d d
0,58N/mm2
0,55N/mm2
0,35N/mm2
0,38N/mm2
745
0,26N/mm2
20150,26N/mm2
6
Connections for concrete overlays
328
Smooth
Connectors at edge1st row 10 dia. s = 340 mm shear dowel+ 8 dia. s = 340 headed connector10 dia. s = 200 / 170 mm shear dowelEdge strip width: b = 630 mm10 dia. s = 200/250 mm shear dowel Strip width: btot = 2360 mmIntermediate support:10 dia. s = 200 / 170 mm shear dowelStrip width: b G 2 x 3640 mm
60
100
100
70
150
60
100
100 200 200
60
100
100
608 dia s = 250
mesh 6,5 dia. s = 100
pin 8 dia. s = 250
mesh 6,5 dia. s = 100
pin 8 dia.
mesh 6,5 dia. s = 100
pin 8 dia.
8 dia. s=1508 dia. s=150
8 dia. s=340 +10 dia. s=340
10 dia.s =170
60
High-pressure water jet
Connectors only at edge8 dia. s = 250 mm headed connector
Sand-blasted
Connectors at edge:8 dia. s = 200 / 150 mm headedconnectorEdge support:8 dia. s = 200 / 200 mm headedconnectorStrip width: btot = 745 mmIntermediate support:8 dia. s = 200 / 150 mm headedconnectorStrip width: b G 2 x 2015 mm
c) Surface without treatment (smooth)
Edge support/span: Mean shear stress at interface �d = 0.35 = 0.175 N/mm2
2
➥ From diagram: �req = 0.15 % Strip width 2360 mm
➥ As = 0.0015 · 10002 = 1500 mm2/m2
➡ selected dia. 10 s = 200/250 mm
At intermediate support: Mean shear stress at interface �d = 0.55 = 0.275 N/mm2
2
➥ From diagram: �req = 0.23 % half-strip width 3640 mm
➥ As = 0.0023 · 10002 = 2300 mm2/m2
➡ selected dia.10 s = 200/170 mm
Cracking tensile force at edge: Ved = 168 kN/mm2 Strip width le = 9 · 70 = 630 mm
➥ �d = 168’000 = 0.27 N/mm2
1000 · 630
➡ From diagram: �req = 0.23 %
➥ As = 0.0023 · 630 · 1000 = 1449 mm2/m➡ selected dia. 10 s = 200/170 mm
Anchorage of dowel: Ib = (6 times dia.) = 60 mm in new and old concreteForces to be anchored: Every second connector in an edge row should be a headed
connector designed as in a)
NRd = 11.2 = 32.9 > Ned = 28.0 kN0.34
Anchoring against de-bonding: It is recommended, that a suitable number of headed connectors also be installed in appropriate locations to prevent the concrete overlay from de-bonding locally.
Connections for concrete overlays
329
11.3.2 Example: Double-span beam with new slab
1200
0,180
0,600
0,200
6000
+ +
-
- -
+ +
6000
-383kNm
-329kN
230kNm
202kN
qd + gd = 88,5kN/m Cross-section:
2280 3720
6000
d=650
1,53N/mm2 1,10N/mm2
900
e = 90 e = 300 e = 140
1,30N/mm2
2,10N/mm22,50N/mm2
2,06N/mm2
d=650
1,30N/mm2
Given:Concrete: New slab: C 30/37, Beam C 25/30Reinforcement: Rebar S500; Ase
2 dia. 10 s = 300 mm As = 523 mm2/m � = 0.26 % �Rd = 1.3 N/mm2
2 dia. 10 s = 140 mm As = 1121 mm2/m � = 0.56 % �Rd = 2.1 N/mm2
2 dia. 10 s = 90 mm As = 1743 mm2/m � = 0.87 % �Rd = 2.9 N/mm2
Notes:● The anchorage length is determined by the existing stirrup-type reinforcement (lap splice).● The shear stresses at the interface are too high for smooth or sand-blasted surfaces.
High-pressure water jet: Sand-blasted: Smooth:
In this case, un-roughenedinterface surfaces cannot beused. The concrete edge at theend face would hinder thenecessary displacement of theconnectors.
11.3.3 Example: Foundation reinforcementGiven:
Concrete: Old C 20/25; New: C 25/30Rebar steel: S500; fyk = 500 N/mm2
Reinforcement existing in foundation:16 dia. s = 150 Ase = 1340 mm2
a) High-pressure water jet or scored�Rdj = 2.3 · 0.24 = 0.55 > �d = 0.19 N/mm2 ➡ no connectors required
b) Sand-blasted (special case: the interface has cracked due to the bending moment)�d = 0.19 N/mm2 ➡ As,req = 486 mm2/m (Formula 3) superimposed tensile force from bending
The minimum reinforcement for flexure governs: Ase,min > As,req + Ase,req
b) Sand-blasted�d,max = 0.38 N/mm2 ➡ �req = 0.16 % ➡ As,req = 0.0016 · 10002 = 1600 mm2/m2 selected 12 dia. s = 250 mm
Tensile force per connector Nd = 0.5 · 113 · 0.5 = 24.6 kN ➡ anchorage length, lb = 150 mm (Appendix 2, Section 10.3.5.1)1.15
400
100
ø16 e = 150mm
400
ø16 e = 150mm
125
4 ø12 e = 250/250
3000500 500
4000
700
200
900100
500
1000 d=750 250
0,38N/mm2
0,66N/mm2
Fd = 1120 kN/m
pd = 280 kN/m2
66
Connections for concrete overlays
330
Connections for concrete overlays
331
11.4. Test results
11.4.1 Transfer of shear across a concrete crackReview of the literature revealslittle research into the specificbehavior of reinforced bond in-terfaces between new and oldconcrete. The majority of theexisting studies concentrate onthe transfer of shear forcesacross cracks.The effect on the shear loadingcapacity of subsequent roug-hening the surface of the oldconcrete was first investigatedin 1960 in the United States.
A few years later, the so-called shear-friction theory was developed. This theory attempts to explain thephenomena with the aid of a simple saw-tooth model. According to this, the roughness of surfaces inthe case of relative displacement always leads to a widening of the interface which sets up stresses insteel connectors passing across the interface. They, in turn, create clamping forces across the interfaceand thus also frictional forces.In 1987, Tsoukantas and Tassios [4] presented analytical investigations into the shear resistance ofconnections between precast concrete components. They cover the different contributing mechanismsof friction and dowel action (Figure 9).
11.4.2 Laboratory tests by Hilti Corporate ResearchSpecific shear tests were carried out inthe laboratories of Hilti Corporate Re-search in cooperation with the Univer-sity of Innsbruck (Supervision: Profes-sor Dr. techn. M. Wicke), to investigatethe interrelationships of various degre-es of roughness and transferable shearstresses with various degrees of rein-forcement. Using a unique test frame design, it waspossible to avoid secondary eccentricmoments in the specimen and to achie-ve nearly parallel separation of the inter-face surfaces (Figure 10). The roughe-ned surfaces were treated with a de-bonding agent before the new concretewas placed.
The results clearly demonstrate that a significant increase in load-bearing capacity can be achieved byproper roughening of the surfaces. If the surfaces are very rough, the steel connectors across the bondinterface are primarily stressed in tension, whereas, if the surfaces are smooth, the shear resistance ofthe connectors (dowel action) predominates.When interface surfaces are rough and the amount of reinforcement at the interface is small (low shearstress), cohesion makes a major contribution to transferring the shear force.The general design concept is presented in the thesis by Randl [6].
Figure 9: Transfer of shear across a concrete crack (shear-friction model)
Figure 10: Shear tests
“Interlock”(friction, cohesion)
“Pull-out”(friction)
“Dowel”(bending, shear force)
6
Connections for concrete overlays
332
11.4.3 Working principle of connectors
The test results confirm the stronginfluence of roughness on shearresistance and shear stiffness. If the load-displacement curvesare regarded in conjunction withthe measured displacement, thethree components of cohesion,friction and dowel action can beisolated and determined quantita-tively. They make different contri-butions to the overall resistance(Figures 11, 12 and 13), depen-ding on surface roughness andamount of reinforcement. Hence, the frictional componentpredominates when the surface isblasted with a high-pressure wa-ter jet and larger amounts of rein-forcement are provided. But smallshear stresses can also be trans-ferred even when no reinforce-ment is present, due to the goodinterlocking effect of the interfacesurfaces. In the case of sand-bla-sted surfaces, however, shearstresses are transferred by a com-bination of friction and dowel ac-tion, but the forces that can be re-sisted are generally far smallerthan in the case of high-pressurewater blasting.Investigations were also conduc-ted as to whether the post-instal-led rebar connectors are stressedto yield at ultimate shear transfer.For this purpose, the strain in theconnectors at the level of the in-terface was measured. To avoidany disturbance of the bond, andin order to obtain the strain due totensile loading only, the straingauges were fitted in a centralbore along the longitudinal axis ofthe connectors.These test results clearly showthat, when surfaces have theabove-mentioned degrees ofroughness, the tensile force in the connectors has not reachedthe full connector tensile yieldstrength, contrary to assumpti-
ons for other design models.Tests carried out with connectorsof various lengths confirm this re-sult, as they showed that redu-ced anchorage lengths are suffi-cient to carry the effectiveconnector tensile force at maxi-mum shear transfer capacity. Ad-ditional connector embedment(e. g., as required for theoreticalconnector tensile yield) did notresult in increased shear transfer.
The load-bearing behavior ofsmooth interface surfaces withconnectors was also investiga-ted. As displacement readingsfor the horizontal and vertical di-rections showed, there is in thiscase also a separation of the in-terface under shear loading and,thus, owing to the lack of roughn-ess, a loss of contact betweenthe shear surfaces. In this case,the entire resistance is providedby dowel action.
On the basis of these findings,design approaches are develo-ped which permit separate andrealistic analyses of the variouscomponents of shear resistance.As a result, a standardized levelof safety is ensured with respectto resistance, regardless ofwhether the normal stresses atthe interface are induced by anexternally applied normal force orby internal connectors.
11.4.4 Comparison with inter-national test resultsIn his thesis [6], Randl has proventhrough a study of literature andwith reference to world-wide re-search results that the determi-ned design equations are conser-vative. The results are shown inFigures 14, 15 and 16.
Lengths:bj effective width of interface in the area under considerationc1 anchor edge distancelb anchorage depth of connector in base material as per Appendix 1ls splice length of reinforcement, as per [1], Section 5.2.4le length over which tensile cracking force is introducedlj effective length of interface under considerationRt mean depth of interface roughness, measured according to the san-patch methods spacing of connectors or rebarsd displacement of connectors under the mean of permanent load (Fp ≈ 0.5 Fuk)tnew thickness of concrete overlayweff additional deformation calculated for the reinforced section considering the flexibility of the
connectorswcalc additional deformation calculated for the reinforced section assuming perfect bondx distance of neutral axis from compressed edge (bending)
Areas:As cross-sectional area of interface reinforcement (connectors)Ase cross-sectional area of bending reinforcement
Forces:Fcr tensile force, effective in the overlay at the time when the cracks may first be expected to occur, as
per [1], Section 4.4.2.2Nd design value of tensile force in connectorNed tensile force resulting from moment of Fcr
VRd design shear resistance at interfaceVsd design shear force acting at interfaceVed shear force at interface derived from FcrVcd design shear force acting at interface in compression zoneVtd design shear force acting at interface in tension zone
Stresses:fcd design value of cylinder compressive strength of concretefyd design value of yield strength of connectorfct,eff tensile strength of overlay effective at the time when the cracks may first be
expected to occur, as per [1], Section 4.4.2.2σn normal stress (positive compression) certainly acting at interfaceτRd basic design shear strength of concrete as per [1], Section 4.3.2.3τTdj design shear strength at interface under consideration
Factors and coefficients:k Coefficient to allow for non-uniform self-equilibrating stresseskT cohesion factor as per Table 1α coefficient for effective dowel action as per Table 1β coefficient for effective concrete strength as per Table 1γ Increasing factor for deformation as per Table 3µ coefficient of friction as per Table 1ν efficiency factor as per [1], Formula (4.20); also refer to Table 2κ coefficient for effective tensile force in the connector as per Table 1ρ= As/bjlj reinforcing ratio corresponding to connectors at interface under consideration
Connections for concrete overlays
335
11.6 Reference literature
[1] EC2; Design of concrete structures: ENV 1992-1-1:1991;
Part 1. General rules and rules for buildings
[2] EC2; Design of concrete structures: ENV 1992-1-3:12/94
Part 1-3. General rules-Precast concrete elements and structures
[3] EC4; Design of composite steel and concrete structures: ENV 1994-1-1:1992;
Part 1-1. General rules and rules for buildings
[4] Tsoukantas S. G., Tassios T.P.; Shear Resistance of Connections between
Reinforced Concrete Linear Precast Elements. ACI Journal, May-June 1989.
[5] CEB-Guide; Design of Fastenings in Concrete, Part III, January 1997
Characteristic Resistance of Fastenings with Cast-in-Place Headed Anchors.
[6] Randl, N, Untersuchungen zur Kraftübertragung zwischen Neu- und Altbeton bei unterschiedli-
chen Fugenrauhigkeiten; Dissertation in Vorbereitung, Universität Innsbruck
(Investigation into the transfer of forces between new concrete and old concrete with different
interface surface roughnesses); thesis being prepared, University of Inssbruck, Austria.
Features : - Base material: concrete, concrete overlays
- No splitting forces in the base material
- Easy handling, injection
- Adjustable anchor head
- plate can be used as rebar holder
Material: Anchor rod: HAS: 5.8, ISO 898 T1, galvanised to 5 microns
Anchor plate: FeE 235, galvanised to 5 microns
Foil pack : Hilti HIT HY 150: standard size 330 ml
Hilti HIT HY 150: jumbo cartridge 1100 ml
Dispenser: MD 2000, P 5000 HY.
A4316
Corrosion resistance (by request)
HCRhighMo
Special Corrosion resistance
(by request)
Close edge distance / spacing
N
s
ch
12.1 Terms:
a) with nut b) with plate
Note: Nut and plate have to be marked after adjusting!hu anchoring depth in existing concrete ho height in the concrete overlay hef actual anchorage depth cü cover d0 drill bit diameter l anchor length m height of the nut axb lenght x width of the plate tp thickness of the platetnew thickness of the concrete overlay
concreteoverlay
existingconcrete
cü
m
ho hohefhef
d0
hu
a x b
tp
l
d0
cü
hu
l
existingconcrete
concreteoverlay
tnewtnew
6
Connection for concrete overlays
337
12.2 Data for the calculation
Calculation details (cp. also [1], page 294 to 298):
1. Bond stress Sd is calculated using the available area in the connection.
2. The necessary reinforcement content can be obtained from Diagram 1, 2 and 3, the Rd Sd must be satisfied.
3. Minimum steel content is given in section 12.3. 4. Anchor rod choice should be compared to the existing geometrical conditions.
5. Calculate number of rods s
jj
A
bln , control edge distances and spacings cmin, resp. smin
1) fyd = fyk/ Ms Ms = 1.2, cp. [2], equation. (6a)]
2)N A fd ds yd , cp. [1], section 11.2.5.4, equation (13) for rough and sandblasted surfaces
3) Cp. [1], page 195 - 203 (Valid for rough, clean, hammer or with compressed air drilled holes)
Cp. [1]. section 11.2.5.4 (2b): Cracks in in concrete reduce the capacity of rebar. In these cases a longer embedment lenght must be used. (e.g. for overlays or under tensile or bending loading with high shear component in the vicinity of the beam connection or of the acting loads).
Reinforcing ratio [%] HAS 5.8 fyk = 400 N/mm2 fyd = 333 N/mm2
Rd
j
[N/m
m2]
B55/45 (C40/50)
B50/40 (C35/45)
B45/35 (C30/37)
B35/25 (C25/30)
B30/20 (C20/25)
Connection for concrete overlays
342
12.4 Product Information
Hilti HIT-HY 150 for concrete
Foil pack HY 150
330ml 1100ml
Setting details
Drill hole. Brush. Blow out. Inject mortar. Insert rod. Wait for curing. Pave over.
HAS rod galvanised Anchor plate galvanised Steel, grade 5.8 Fe E 235 (St 37)
Ordering Designation Ordering Designation
HAS M8x110 HAS M16x190 SR-SMA SR-SMA-L
HAS M8x150 HAS M16x260 HAS M16x300 Ordering D. a b Tp Thread Size HAS M10x130 HAS M16x350 mm mm mm HAS M10x170 HAS M16x500 HAS M10x190 SR-SMA 8 35 28 6.5 M8 HAS M20x240 SR-SMA 10 33 23 6.5 M10 HAS M12x160 HAS M20x260 SR-SMA 12* 40 40 6 M12 HAS M12x220 HAS M20x300 SR-SMA 16* 40 40 8 M16 HAS M12x260 HAS M20x350 HAS M12x300 HAS M20x400 SR-SMA-L 12* 60 30 6 M12
Other lenghth and steel qualities are possible Other lenghth and steel qualities are possible
Text of tender offer
Providing and setting of injection anchors consisting of : Injection mortar Hilti HIT-HY 150 with HAS rod, steel, grade 5.8, M ..... x length ..... mm with anchor plateSR-SMA M .... x length ...... mm x width ...... mm x thickness ...... mm.
Drilling and cleaning of the borehole ..... mm, Tiefe .......mm according to the directions of the supplier As well as the hight adjustment of the plate, cutting of the overlong rebars and marking .