Shear transfer in lightweight reinforced concrete Alan H. Mattock Professor of Civil Engineering and Head, Structures and Mechanics Division University of Washington Seattle, Washington W. K. Li* Structural Engineer Surveyor, Nenniger and Chenevert, Inc. Consulting Engineers Montreal, Quebec T. C. Wang* Structural Engineer Kramer, Chin and Mayo, Inc. Consulting Engineers Seattle, Washington *Former Graduate Student, Department of Civil Engineering, University of Washington, Seattle, Washington. 20
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Shear transfer inlightweight reinforcedconcreteAlan H. MattockProfessor of Civil Engineering andHead, Structures and Mechanics DivisionUniversity of WashingtonSeattle, Washington
W. K. Li*Structural EngineerSurveyor, Nenniger and Chenevert, Inc.Consulting EngineersMontreal, Quebec
T. C. Wang*Structural EngineerKramer, Chin and Mayo, Inc.Consulting EngineersSeattle, Washington
*Former Graduate Student, Department of Civil Engineering,University of Washington, Seattle, Washington.
20
L ightweight concrete is being usedincreasingly in precast concrete
construction. This has resulted in aneed for connection design data whenlightweight concrete is used. Neitherthe ACI Building Code, ACI 318-71,1nor the PCI Design Handbook2 pro-vides any guidance in this respect.
The shear-friction provisions con-tained in Section 11.15 of ACI 318-71,which are used extensively in the con-nection design procedures developed inthe PCI Design Handbook, have onlybeen validated experimentally for thecase of shear transfer in normal weightconcrete.
The study reported here was directedtoward developing shear transfer designrecommendations for use in the designof connections in precast structuresmade of lightweight concrete.
Experimental Study
The experimental program reportedhere was designed to study theinfluence on single direction sheartransfer strength and behavior, ofthe type of aggregate used in makingthe concrete. The primary variablein the tests was the type of aggre-gate, four types being used:
1. Naturally occurring gravel andsand.
2. A predominantly coated roundedlightweight aggregate.
3. A predominantly crushed angularlightweight aggregate.
4. A "sanded lightweight" aggregate,in which most of the lightweightfine particles were replaced withnormal weight sand.
The test specimens were of the"push-off" type shown in Fig. 1, with ashear plane of 50 sq. in. area. Whenloaded as indicated by the arrows, shearwithout moment is produced in theshear plane. The reinforcement cross-ing the shear plane was in the form of
SynopsisA study is reported of thesingle direction shear trans-fer strength of lightweight ag-gregate concrete.Push-off tests were carriedout on specimens made fromsanded lightweight concrete,two types of all-lightweightconcrete, and sand and grav-el concrete.Both initially uncrackedspecimens and specimenscracked in the shear planebefore being subjected toshear, were tested.It was found that the sheartransfer strength of light-weight concrete is less thanthat of sand and gravel con-crete having the same com-pressive strength.The shear-friction provisionsof Section 11.15 of ACI 318-71 may be used in the de-sign of connections in light-weight concrete providingthe value of the coefficientsof friction fc, contained inSection 11.15.4, are multi-plied by the following factors:(a) For all-lightweight con-
crete having a unit weightnot less than 92 lb percu ft, multiply µ by 0.75.
(b) For sanded lightweightconcrete having a unitweight not less than 105lb per cu ft, multiply µby 0.85.
PCI JOURNAL/January-February 1976 21
•
Is closed..ҟ•
IRIGIHi• till hf A
-I.D * 1
N N N Nr r r r
L i Section A—A
!~-12 ^I
Fig. 1. Push-off specimen.
welded closed stirrups. This was to en-sure the effective anchorage of the rein-forcement on both sides of the shearplane. The specimens were cast on theirsides, so that at the time of casting theshear plane was horizontal.
Ten series of push-off specimenswere tested, as indicated in Table 1.The variables between test series werethe type of aggregate, the concretestrength, and whether or not a crack ex-isted in the shear plane before the sheartransfer test. The variable within eachseries was the reinforcement parameter,p/2,. The number of stirrups providedin the specimens within each series isset out in Table 2.
Materials and fabrication
When planning the project, the adviceof the Expanded Shale, Clay and SlateInstitute was sought as to the types ofaggregate and concrete mix designs thatshould be used in order that the resultsof the study would have the widestpractical applicability.
Current production of rotary kiln ex-panded lightweight aggregate is pre-dominantly of the coated surface typein the coarse fraction and a blend ofcrushed and coated surface aggregatein the fine fraction.
For the sake of brevity, lightweightaggregate having predominantly coated
22
Table 1. Program of push-off tests.
Series Aggregate Type Design
f at test
c (psi)
InitialCondition
A Coated lightweight aggregate 4000 Uncrackedand sand
B Coated lightweight aggregate 4000 Cracked
and sand
C Coated lightweight aggregate 2500 Cracked
and sand
0 Coated lightweight aggregate 6000 Cracked
and sand
j E Coated lightweight aggregate 4000 Untracked
only
F Coated lightweight aggregate 4000 Cracked
only
G Crushed lightweight aggregate 4000 Uncracked
only
H Crushed lightweight aggregate 4000 Cracked
only
M Natural gravel and sand 4000 Uncracked
N Natural gravel and sand 4000 Cracked
Table 2. Specimen numbering and reinforcement details.
Specimen No. X.0* X.l X.2 X.3 X.4 X.5 X.6
Number of#3 Stirrups 0 1 2 3 4 5 6
Reinforcement
Area, sq in. 0 0.22 0.44 0.66 0.88 1.10 1.32
* This specimen appears only in Series A, E, G, and M.
"X" is the letter designating the particular series.
rounded aggregate particles, will in thisreport be referred to as a "coated ag-gregate." Similarly, aggregate in whichthe various particle sizes are predom-inantly obtained by crushing larger-sized particles is referred to as"crushed aggregate." Most structurallightweight aggregate concretes usemainly sand for the fine fraction of theaggregate. Such concretes are referredto as "sanded lightweight" concretesand have a dry density of about 110 lbper cu ft.
In view of the foregoing, it was de-cided that the results of the studywould have the widest applicability ifemphasis were placed on tests involving
lightweight aggregate concrete made ofa "coated aggregate" in "sanded light-weight" mixes.
The first four test series (Series A, B,C, and D), therefore involve this typeof concrete. The second group of fourtest series (Series E, F, G, and H) in-volved "all-lightweight" concrete, Se-ries E and F using a "coated aggregate"and Series G and H using a "crushedaggregate." The final two series (SeriesM and N) used a natural gravel con-crete as a reference against which tocompare the performance of the light-weight concretes.
The natural aggregate used was aglacial outwash gravel obtained from a
PCI JOURNAL/January-February 1976 23
Fig. 2. Sample of coatedlightweight aggregate.
Fig. 3. Sample ofcrushed lightweight ag-
gregate.
Fig. 4. Sample of naturalsand and gravel.
local pit. The gradings of the coarseand fine fractions of each aggregate asdetermined by sieve analysis, are setout in Table 3. The appearance of theaggregates is seen in Figs. 2, 3, and 4.
Trial batches were made of the light-weight concretes, using proportionssuggested by the producers of the ag-gregates. The mix proportions selectedfor the various lightweight aggregateconcretes are given in Table 4. The mixproportions for the natural gravel con-crete were arrived at through the test-ing of trial batches and they are shownin Table 5. The weights shown in Ta-bles 4 and 5 are of aggregate as sup-plied, i.e., slightly damp. Exact mois-
ture contents were not measured.The proportions of the lightweight
concrete mixes were chosen so that fora 3-in, slump the design strength wouldbe attained at 28 days, after 7 daysmoist curing and a further 21 days cur-ing in air. The proportions of the sandand gravel concrete were chosen so thatfor a 3-in, slump the design strengthwould be attained at 4 days, after 2days moist curing and 2 days curing inair. Approximately 6 percent of en-trained air was included in all mixesto conform to usual practice with light-weight concrete. Complete details ofthe procedures followed are reportedelsewhere.4
24
Table 3. Grading of aggregates(cumulative percent retained).
Aggregate
Sieve
Size
CoatedLightweight
Crushed
Lightweight
Natural
Sand andGravel
Coarse Aggregate
3/4 in. 0 0 0
1/2 in. 0 19.4 53.8
3/8 in. 2.7 61.6 87.0
No. 4 92.5 96.4 99.9
Fine Aggregate
No. 4 1.8 0.4 1.8
No. 16 43.1 43.7 26.3
No. 50 81.9 74.2 76.2
No. 100 93.8 86.9 96.9
Table 4. Mix proportions for lightweight concretes(lbs per cu yd)Type I Lightweight Aggregate
Type of Concrete Portland Natural
Coarse FineCement Sand
Sanded Lightweight
coated aggregate)
Series A & B 500 740 227 1369
(f'C - 4000 psi)
Series C 400 744 220 1426
(f 2500 psi)
Series D 640 784 220 1091
(f = 6000 psi)
All-Lightweight
Series E & F 500 740 1049 --
(coated aggregate,V = 4000 psi)
Series G & H 517 825 1284 --
(crushed aggregate,4000 psi)
Note: In all mixes, water was provided to produce a 3-in. slump.
Table 5. Mix proportions for natural sand andgravel concrete (lbs per cu yd)
Type III
Concrete Portland Gravel SandCement
Series M & N 489 1798 1448(fc = 4000 psi)
Note: - In all mixes, water was provided to produce a 3-in. slump.
PCI JOURNAL/January-February 1976ҟ 25
Table 6. Data concerning test specimens.
(1)Concrete
Specimen Stirrup Reinforcement f . fct (2) Dry Shear StressNo. Yield Point Parameter
(psi) (psi) Density (3) (psi)f (ksi) Pf (psi) (lb. /cu. ft) u
Series A
-- 0 4230 402 111 500AD
Al 47.7 210 3740 336 111 758
A2 53.6 472 4095 367 105 914
A3 53.2 702 3910 349 110 1020
A4 50.9 896 4100 352 108 1100
A5 50.9 1120 3960 351 108 119D
A6 51.8 1368 4250 397 110 1344
Series B
81 49.6 218 3740 336 111 450
B2 50.9 448 3360 318 107 652
83 4 50.9 672 3910 349 110 840
B4 i 49.1 864 4100 352 108 940
85 50.5 1111 3960 351 108 1000
B6 51.8 1368 4250 397 110 1154
Series C
49.6 218 2330 254 102 364Cl
C2 53.6 472 2330 254 102 514
C3 50.9 672 2000 232 103 526
C4 52.3 921 2050 235 105 560
C5 53.6 1179 2330 269 106 640
C6 49.6 1309 2330 269 106 740
Series 0
D1 51.8 228 5995 376 108 370
D2 52.3 460 5995 376 108 668
D3 52.3 690 5710 379 10 772
04 52.3 920 5710 379 107 1022
D5 52.3 1151 5600 398 109. 1082
06 51.8 1368 5600 398 109 1220
Series E
EU -- 0 3960 365 92 560
El 52.3 230 4150 350 97 780
E2 52.3 460 4030 355 94 872
E3 52.3 } 690 4065 375 96 960
E4 53.2 936 4040 405 96 1150
E5 50.5 1111 4115 365 98 1200
E6 52.3 1381 4050 365 94 1250
Notes: (1) Concrete compressive strength at time of test, measured on 6 x 12-in.
cylinders.
(2) Concrete splitting tensile strength at time of test, measured on
Notes: (1) Concrete compressive strength at time of test, measured on 6 x 12-in.cylinders.
(2) Concrete splitting tensile strength at time of test, measured on6 x 12-in, cylinders.
v
(3) vu = - A , with = 1.0.cr
(4) Air dried density at time of test.
PCI JOURNAL/January-February 1976ҟ 27
Table 7. Average concrete properties at time of test(by series).
Compressive Splitting f f Air
Strength, f. Tensile ct ct Dry
Series (psi) Strength, f Density
(psi) c (lb./cu. ft.)
Sanded Lightweight Concretes
365 .090 5.74 109Series A 4040
Series B 3890 351 .090 5.63 109
Series C 2230 252 .113 5.34 104
Series D 5770 384 .067 5.06 108
All—Lightweight Concretes
370 .091 5.81 95Series E 4060
Series F 4050 365 .090 5.74 95
Series G 4085 395 .097 6.18 97
Series H 4095 390 .095 6.09 97
Sand and Gravel Concrete
380 .095 5.99 146Series M 4020
Series N 4045 385 .095 6.05 146
Type I portland cement was used forthe lightweight concrete mixes andType III portland cement was used forthe sand and gravel concrete mixes.
The deformed bar reinforcementused conformed to ASTM SpecificationA615. The #3 bar used for the sheartransfer reinforcement had a yieldpoint of approximately 50 ksi. The #6bar longitudinal reinforcement had ayield point of approximately 60 ksi.Reinforcement details and concreteproperties are shown in Tables 6 and 7.
Testing arrangements andprocedures
The push-off specimens were testedusing a Baldwin hydraulic testing ma-chine to load the specimen along theshear plane as indicated in Fig. 1. Typi-cal arrangements for test are shown inFig. 5. The specimen stood on the low-er platen of the testing machine andwas loaded through the sphericallyseated upper platen of the testing ma-chine, a load cell and a set of parallelplates and rollers.
The rollers ensured that separationof the two halves of the push-off speci-men was not restrained by the testingmachine. Both slip along the shearplane and separation across it weremeasured continuously using linear dif-ferential transformers attached to refer-ence points embedded in the specimen,as may be seen in Fig. 5.
Mast3 pointed out the need to con-sider the case of a crack existing in theshear plane before shear acts. There-fore prior to test, some of the specimenswere cracked along the shear plane byapplying line loads to their front andrear faces.
These loads were applied throughsteel wedges with the specimen in ahorizontal position. The dilation of thespecimen across the shear plane wasmeasured during the cracking opera-tion, using dial gages mounted on areference frame. The width of the crackproduced was approximately 0.01 in..
The specimens were subjected to acontinuously increasing load until fail-ure occurred, with short pauses as nec-
28
essary to mark any cracks which mayhave occurred. The average length oftime taken for a test was about 15 min-utes. The ultimate load was defined asthe maximum load that could be carriedby the specimen.
Specimen behaviorThe general behavior of all the initiallyuncracked specimens was similar. Noslip along the shear plane, nor separa-tion across the shear plane occurred inthese specimens until the formation ofdiagonal tension cracks in the region ofthe shear plane at shear stresses of from400 to 700 psi.
These cracks were initially 2 or 3 in.long and inclined at from 20 to 45 degto the shear plane. As the load in-creased, some of the cracks lengthenedand additional cracks formed, so thatat failure there were in general a largernumber of diagonal tension cracks inthe more heavily reinforced specimensthan in the more lightly reinforcedspecimens.
At failure some of the cracks propa-gated parallel to the shear plane, link-ing with others, and extensive compres-sion spalling occurred in the inclinedconcrete struts formed by the diagonaltension cracks.
In the initially uncracked specimensthere was no slip along the shear planein the true sense of the word. Relativemotion of the two halves of the speci-men occurred as a result of the rotationand compression of the inclined con-crete struts as the reinforcement cross-ing the shear plane stretched.
The component of this relative mo-tion parallel to the shear plane is re-ferred to as slip when discussing be-havior, for the sake of brevity. Thecomponent of the relative motion nor-mal to the shear plane is referred to asseparation. The slip and separation datahave been reported in detail else-where. 4 Typical shear-slip curves forinitialIy uncracked specimens are
Fig. 5. Arrangements for test of push-off specimen.
shown in Fig. 6.The general behavior of all the in-
itially cracked specimens was similar.Slip occurred along the preformedcrack in the shear plane from the com-mencement of loading, and at a pro-gressively increasing rate. In the caseof the heavily reinforced sand and grav-el concrete specimens, a few diagonaltension cracks occurred across the shearplane at high loads.
This behavior had been observed inprevious tests of sand and gravel con-crete push-off specimens. 5 However, nosuch diagonal tension cracks were ob-served in either the sanded-Iightweightor the aII-lightweight concrete speci-mens.
In all the initially cracked specimens,the slip increased at a rapid rate at fail-ure and a small amount of compressionspalling of the concrete occurred ad-jacent to the shear plane crack. Typicalshear-slip curves for initially crackedspecimens are shown in Fig. 7.
PCI JOURNAL/January-February 1976ҟ 29
Series G Initially uncrackedAll-lightweight, (crushed aggregate,) concrete.
It can be seen from the shear-slipcurves that the deformation behaviorwas relatively brittle in all cases. Themaximum shear resistance was notmaintained as the slip increased beyond
the value at which maximum shear re-sistance was developed.
The initially uncracked specimensbehaved in a more brittle fashion thanthe corresponding initially cracked spe-
Fig. 8. Effect of a crack in the shear plane on shear transferstrength of sanded lightweight concrete.
cimens, in that the shear resistance afterultimate decreased more rapidly as theslip increased. However, because theultimate strength of the initially un-cracked specimens was greater thanthat of the corresponding initiallycracked specimens, the residualstrengths of both types of specimenswere about the same for slips of 0.05in. or more.
Deformation behavior was found tobecome more brittle as the compressivestrength of the concrete increased; andalso to be more brittle in the case ofthe all-lightweight concretes than inthe cases of the sanded lightweightconcrete and the sand and gravel con-crete.
Ultimate shear transfer strengthThe values of ultimate shear transferstrength obtained in the tests are shownin Table 6, together with other perti-nent data concerning the test speci-mens. The ultimate shear transferstrength is expressed as a nominal ulti-mate shear stress:
_ Ultimate shearVu Area of shear plane
The ultimate shear is defined as themaximum shear carried by the speci-men during the test.
Effect of a crack in the shear plane—In Fig. 8 a comparison is made of theultimate shear transfer strengths of the
Sand and gravel concrete,ҟ•this study,—^^ •previous ҟ•ҟ♦ •ҟ-
'^0'0
a^ҟ8 Sanded lightweightconcrete
All-lightweight concrete
0ҟ
200 400 600 800 1000 1200 1400
Pfy (psi)
Fig. 9. Effect of aggregate type on shear transfer strength ofinitially cracked concrete having f, — 4000 psi.
sanded lightweight concrete specimensof Series A and B. The correspondingspecimens of these two series weremade as nearly identical as possible,except that the specimens of Series Awere tested in an initially uncrackedcondition, while those of Series B werecracked along the shear plane beforebeing tested.
It can be seen that for all values ofthe reinforcement parameter pf, consid-ered, the existence of a crack in theshear plane reduces the shear transferstrength, for a given value of pf, by analmost constant amount.
Similar behavior also occurred in thecase of the all-lightweight concrete spe-cimens. However, in the case of the
sand and gravel concrete specimens, thedifference in strength between the in-itially uncracked specimens and the in-itially cracked specimens decreasedcontinually as pf, increased.
In previous studies5 of shear transferin sand and gravel concrete, similarbehavior was observed. However inthat case (for concrete with f' — 4000psi), the strength of the initially crackedconcrete became equal to that of theinitially uncracked concrete when p f
was about 1350 psi.It was postulated that under the
clamping force provided by this largeamount of reinforcement, the crack"locked up" and the concrete behavedas if it were initially uncracked. In such
32
a case diagonal tension cracks formedacross the shear plane and the failurehad the characteristics of a shear trans-fer failure in initially untracked con-crete.
In the present tests diagonal tensioncracks also occurred for this heavy de-gree of reinforcement, but the strengthof the initially cracked concrete fell alittle short of that of the initially un-cracked concrete. It is posssible that thedifference in behavior noted in the twostudies is only apparent and was causedby experimental scatter in the strength.data.
In the previous study5 it was postu-lated that the upper limit to the sheartransfer strength of initially crackedconcrete of a particular compressivestrength resulted from this "locking up"of the crack and subsequent behavioras if initially uncracked. However, thisdoes not appear to be the case for light-weight concrete in which no evidenceof such "locking up" behavior was ob-served.
No diagonal tension cracks occurredin any of the initially cracked light-weight concrete and the shear transferstrength of the initially cracked light-weight concrete did not approach thatof the initially uncracked lightweightconcrete at high values of pfy,. The ceil-ing value of shear transfer strength forIightweight concrete must therefore re-sult from some other aspect of sheartransfer behavior as yet unidentified.
Effect of aggregate type on sheartransfer strength—In Fig. 9 a compari-son is made of the shear transferstrength of initially cracked concrete ofthree kinds, all having compressivestrengths of close to 4000 psi.
It can be seen that the shear transferstrength of the sand and gravel con-crete is consistently greater than thatof the lightweight concretes, for thesame amount of reinforcement, and thatthe sanded lightweight concrete hasa greater shear transfer strength than
all-lightweight concrete.
The differences in shear transferstrength do not correlate with the dif-ferences in concrete splitting tensilestrength. The shear transfer strength oflightweight concrete in design shouldnot therefore be related to the splittingtensile strength of the concrete.
The difference in the shear stresseswhich can be carried by lightweightand normal weight concretes of thesame compressive strength is usuallyattributed to differences in the tensilestrength of the concretes. However thiscannot be the case in this instance,since the average splitting tensilestrengths of the 4000 psi concretes were
6.02V7 for the sanded and gravel
concrete, 5.69/ f', for the sanded
lightweight concrete, 5.78 ,/ for thecoated all-lightweight aggregate con-
crete and 6. 14V7 for the crushedlightweight aggregate concrete. (seeTable 7).
The difference in shear transferstrength between lightweight concretesand sand and gravel concretes of thesame compressive strength is probablydue to differences in roughness of thecrack faces in contact. Some of thepush-off specimens were cut open aftertest and it could be seen that the crackfaces in the sand and gravel concretewere rougher than those in the light-weight concrete.
In sand and gravel concrete, thebond strength between the mortar andthe aggregate particles is smaller thanthe tensile strength of the aggregateparticles. Cracks therefore generallypropagate around the aggregate par-ticles, producing a rough surface.
In lightweight concrete the bondstrength between the mortar and theaggregate particles is apparently great-er than the tensile strength of the ag-gregate particles. In this case therefore,cracks propagate through the aggregate
Fig. 10. Comparison of shear transfer strength of initiallycracked, sanded lightweight concrete, with strength
predicted by current design equations.
and a smoother crack face results. Thisdifference in cracking behavior wasreadily apparent in both the push-offspecimens that were cut open after test,and in the appearance of the two halvesof cylinders subject to the splitting ten-sile strength test.
The difference in shear transfer be-tween the sanded lightweight concretesand the all-lightweight concretes ofsimilar compressive strength was prob-ably due to similar causes. In the sand-ed lightweight concrete the crackspropagated round the sand particles,producing a rougher surface than in theall-lightweight concrete.
The roughness produced by this of-
feet is only minor. However it is con-sidered that it could influence sheartransfer behavior, since the slips andseparations at ultimate measured in thetests are only of the order of the size ofthe sand grains.
It can also be seen in Fig. 9 thatwhile the rate of increase of shear trans-fer strength with increase in pfy isabout the same for all three concretesfor moderate values of p f ,, the sheartransfer strength of the lightweight con-cretes commences to increase at a less-er rate at a lower value of p f y thandoes the sand and gravel concrete.
It apears that for a given strength,the absolute maximum shear transferstrength obtainable is less in the case of
34
lightweight concretes than in the caseof sand and gravel concrete. This maybe due to the resistance to abrasion ofthe lightweight concrete crack facesbeing less than that of the sand andgravel concrete crack faces.
"Skid" marks could be seen on thecrack faces of the more heavily rein-forced lightweight concrete push-offspecimens cut open after test. Similardamage to the crack faces was not ob-served in the case of sand and gravelspecimens.
This may be the reason why the"Iocking up effect noted in heavilyreinforced sand and gravel concretepush-off specimens did not occur inheavily reinforced lightweight concretespecimens. Failure of the lightweightconcrete crack faces through extensiveshearing off of local roughness appar-ently occurs before the crack faces canbecome locked together.
Calculation of shear transfer strengthin design—Currently, the calculation ofshear transfer strength in design is us-ually based on the provisions of Section11.15—Shear-friction, of ACI 318-71.1According to these provisions, sheartransfer strength is given by:
vu = 0 Avffv p (1)
which may also be expressed as an ulti-mate shear stress:
Vuvu = Air = µPfv (2)
Section 11.15 also specifies that v,,shall not exceed 0.2f, nor 800 psi.
The value of the con fident of fric-tion µ, is to be taken as 1.4 for concretecast monolithically, 1.0 for concreteplaced against hardened concrete, and0.7 for concrete placed against as-rolledstructural steel.
In Section 6.1.9 of the PCI DesignHandbook,2 it is proposed that for val-ues of pfy greater than 600 psi, the
shear-friction equations can continue tobe used provided that the coefficient M,is multiplied by
300+ 0.5
pf„
That is, Eq. (2) then becomes:
vu = M!,µ1 pfy +0.51 (3)
Eq. (3) will be referred to as the PCIequation. Initially, no upper limit wasspecified for v calculated using thePCI equation, but subsequently an up-per limit of the lesser of 0.25f', or1200 psi was proposed for v,u.
In Figs. 10 and 11 comparisons aremade between measured shear transferstrengths in initially cracked light-weight concretes and the strengths pre-dicted by Eq. (2) and (3).
(Note that in making these compari-sons, the value of the capacity reduc-tion factor cA is taken as 1.0, since thematerial strengths and specimen dimen-sions are accurately known.)
It is seen that the PCI equation isunconservative for both sanded light-weight and aII-lightweight concretesand should therefore not be used in thedesign of connections between mem-bers of lightweight concrete.
In Fig. 10 it can be seen that theshear-friction equation, using pu= 1.4,becomes unconservative for sandedlightweight concrete when pf, exceedsabout 450 psi. It is therefore proposedthat the multiplying factor for sandedlightweight concrete, 0.85, containedin. Section 11.3.2 of ACI 318-71 shouldalso be applied to the coefficients offriction fit, contained in Section 11.15.4.
For a crack in monolithic sandedlightweight concrete, fie, then becomes1.19. A line corresponding to use of thisvalue of Ft in shear-friction calculationshas been drawn in Fig. 10 and it isseen to be reasonably conservative forsanded lightweight concrete.
0Shear Friction ; '° 0V = p fy P "./ 800 psibut ) 0.2fҟJPnor 800 psi 04(r = 1.4)ҟO
On Shear Frictionusing p = 0.75(1.4)
'ii= 1.05
0ҟ200 400 600 800 1000 1200 1400
pfy (psi)Fig. 11. Comparison of shear transfer strength of initiallycracked, all-lightweight concrete, with strength predicted
by current design equations.
It can be seen in Fig. 11 that theshear-friction equation, using li= 1.4for a crack in monolithic concrete (asspecified in Section 11.15.4 of ACI 318-71), can be considerably unconservativefor all-lightweight concrete.
It is therefore proposed that the mul-tiplying factor for all-lightweight con-crete, 0.75, contained in Section 11.3.2of ACI 318-71 should also be applied tothe coefficients in friction I,c containedin Section 11.15.4. For a crack in mono-lithic all-lightweight concrete, /i thenbecomes 1.05.
A line corresponding to use of thisvalue of p, in shear-friction calculationshas been drawn on Fig. 11 and it is
seen to be reasonably conservative forall-lightweight concrete.
It can be seen from Figs. 10 and 11that the limiting value for vu containedin Section 11.15.3 of ACI 318-71 (0.2f, but not more than 800 psi) is alsoappropriate for both sanded lightweightand all-lightweight concretes, providedthat the reduced values of fit, proposedabove are used.
Subsequent to the publication ofACT 318-71 and the PCI Design Hand-book, Mattock proposed6 the followingequation for the shear transfer strengthof sand and gravel concrete:
vu = 0.8 p f y + 400 psi (4)but not more than 0.3 f .
Fig. 12. Comparison of shear transfer strength of initiallycracked, sanded lightweight concrete, with strength
predicted by Eqs. (4) and (5).
Also, pf y was to be not less than200 psi.
In Figs. 12 and 13, the shear transferstrength predicted by Eq. (4) is com-pared with the measured shear transferstrength of sanded lightweight and all-lightweight concrete, respectively.
It can be seen that Eq. (4) is non-conservative in both cases and there-fore it should not be used in the designof connections between members madeof lightweight concrete. However, itcan also be seen that for moderatevalues of pf,,, v, increases with pf, atthe same rate as predicted by Eq. (4).
It is therefore proposed that the fol-lowing equations for shear transfer
strength be used for lightweight con-crete:(a) For sanded lightweight concrete:
v,,=0.8pfy + 250psi (5)
but not more than 0.2f', nor 1000 psi.
(b) For all-lightweight concrete:
v,, = 0.8 pf, + 200 psi (6)
but not more than 0.2 f', nor 800 psi.
Lines representing Eqs. (5) and (6)have been drawn on Figs. 12 and 13,respectively, and it can be seen thatthese equations provide a reasonablyconservative estimate of the shear trans-fer strength of the two types of light-weight concrete.
Fig. 13. Comparison of shear transfer strength of initiallycracked, all-lightweight concrete with strengths predicted
by Eqs. (4) and (6).
Conclusions for Design
On the basis of the study reported here,the following conclusions are drawnconcerning shear transfer in lightweightaggregate concrete:
1. The shear transfer strength oflightweight concrete is less than that ofsand and gravel concrete of the samecompressive strength.
2. The shear transfer strength oflightweight concrete is not significantlyaffected by the type of lightweight ag-gregate, i.e., by whether the aggregateis a "coated aggregate" or "crushed ag-gregate."
3. The shear-friction provisions ofSection 11.15 of ACI 318-71 may beused to calculate shear transfer strengthin the design of connections in light-weight concrete, providing the value ofthe coefficients of friction µ, containedin Section 11.15.4, are multiplied bythe following factors:
(a) For all-lightweight concrete hav-ing a unit weight not less than92 lb per cu ft, multiply [4 by0.75.
(b) For sanded lightweight concretehaving a unit weight not less than105 lb per cu ft, multiply It by0.85,
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4. The provisions of Section 6.1.9 ofthe PCI Design Handbook are not ap-plicable to lightweight concrete.
5. The shear transfer strength ofsanded lightweight concrete having aunit weight not less than 105 lb per cuft can be calculated using the followingequation:
v.=0.8pfr+250psi
but not more than 0.2f', nor 1000 psiand pf, to be not less than 200 psi.
6. The shear transfer strength ofall-lightweight concrete having a unitweight not less than 92 lb per cu ftcan be calculated using the followingequation:
v,,, 0.8pfy+200psi
but not more than 0.2f', nor 800 psiand pf,5 to be not Iess than 200 psi.
Notation
A0,. = area of shear plane
A„1 = total area of shear transfer re-inforcement
= compressive strength of con-crete measured on 6 x 12-in. cylinders.
ji = coefficient of friction used inthe shear-friction hypothesis
p = A,f/A,,0 = capacity reduction factor
Discussion of this paper is invited.Please forward your discussion toPCI Headquarters by June 1, 1976.
References
1. ACI Committee 318, "BuildingCode Requirements for ReinforcedConcrete (ACI 318-71)," AmericanConcrete Institute, Detroit, 1971.
2. PCI Design Handbook, PrestressedConcrete Institute, 1971.
3. Mast, R. F., "Auxiliary Reinforce-ment in Concrete Connections,"Journal of the Structural Division,American Society of Civil Engineers,V. 94, ST 6, June 1968, pp. 1485-1504.
4. Mattock, A. H., "Effect of AggregateType on Single Direction ShearTransfer Strength in MonolithicConcrete," Report SM74-2, Depart-ment of Civil Engineering, Univer-sity of Washington, Seattle, Wash-ington, August 1974.
5. Mattock, A. H., and Hawkins, N. M.,"Research on Shear Transfer inReinforced Concrete," PCI JOUR-NAL, V. 17, No. 2, March-April,1972, pp. 55-75.
6. Mattock, A. H., "Shear Transfer inConcrete Having Reinforcement atan Angle to the Shear Plane," Pub-lication SP-42, Shear in ReinforcedConcrete, American Concrete Insti-tute, 1974, pp. 17-42.
Acknowledgment
This study was carried out in the Struc-tural Research Laboratory of the Uni-versity of Washington. It was supportedby the National Science Foundation,through Grant No. GK-33842X. Light-weight aggregate was supplied bymembers of the Expanded Shale, Clayard Slate Institute.