Xix introduction to prestressed concrete1. T.Chhay NPIC
XVIII. esckþIENnaMBIebtugkugRtaMg
Introduction to Prestressed Concrete
1> ebtugeRbkugRtaMg Prestressed Concrete
k> eKalkarN_énkareFVIeRbkugRtaMg Principles of Prestressing
karGnuvtþeRbkugRtaMgeTAelIGgát;eRKOgbgáúMKWCakarbegáItkugRtaMgGciéRnþy_xagkñúgEdlmanGMeBI
RbqaMgnwgkugRtaMgTajenAkñúgebtugEdl)anbnÞúkxageRkA. karGnuvtþeRbkugRtaMgenHbegáItCaEdnkug
RtaMgEdlGgát;GacTb;Tl;)any:agmansuvtßiPaB. eKGacGnuvtþkMlaMgeRbkugRtaMgmun b¤kñúgeBldMNal
KñaénkarGnuvtþbnÞúkxageRkA. kugRtaMgenAkñúgGgát;eRKOgbgÁúMRtUvEtenAsl; ¬RKb;TIkEnøg nigsMrab;RKb;
sßanPaBénkardak;bnÞúk¦ enAkñúgEdnkMNt;rbs;kugRtaMgEdlsMPar³ GacRTRTg;)anKμanTIkMNt;. CaTU
eTA karGnuvtþkugRtaMg ¬PaKeRcInCakugRtaMgsgát;¦ RtUv)anbegáIteLIgeday high-strength steel
tendon EdlrgkarTaj nig anchor eTAnwgGgát;ebtug. kugRtaMgRtUv)anepÞreTAebtugeday bond
tamépÞrbs; tendon b¤eday anchorage enAxagcugrbs; tendon.
edIm,IgayRsYlkñúgkarBnül; cUrBicarNaFñwmmYyEdleFVIBIebtugsuT§ ehIyFñwmenaHRtUvRTnUv
bnÞúkTMnajxageRkA (external gravity load) dUcbgðajkñúgrUbTI 19>1 a. muxkat;FñwmRtUv)aneRCIs
erIsCamYynwg tensile flexural stress EdlCalkçxNÐeRKaHfñak;sMrab;karKNna dUcenHeKTTYl)an
muxkat;EdlminmanlkçN³esdækic©. mUlehtuKWedaysarebtugxøaMgkñúgkarsgát;CagkarTaj. flexural
tensile strength b¤m:UDuldac; (module of rupture) rbs;ebtug f r esμInwg 0.62 f 'c ¬rUbTI 19>1a¦.
kñúgkarKNnaebtugGarem:Fmμta eKminKit tensile strength rbs;ebtugeT ehIyEdksrés
RtUv)andak;enAkñúgtMbn;Tajrbs;ebtugedIm,ITb;Tl;nwgkugRtaMgTaj b:uEnþebtugTb;Tl;nwgkugRtaMgsgát;
¬rUbTI 19>1 b¦.
kñúgkarKNnaebtugeRbkugRtaMg kugRtaMgsgát;dMbUgRtUv)anGnuvtþeTAkñúgFñwmedIm,IeGaymanGMeBI
Tb;nwgkugRtaMgTajEdlekIteLIgedaysarbnÞúkxageRkA ¬rUbTI 19>1 c¦. RbsinebIkugRtaMgEdldak;
dMbUgenHesμInwgkugRtaMgTajenAsréseRkambMput enaHkugRtaMgTaMgBIrRtUv)anlubecal b:uEnþkugRtaMg
sgát;enAsrésEpñkxagelIbMputnwgmantMélDub. kñúgkrNIenH muxkat;Ggát;TaMgmUlrgkarsgát;. Rb
esckþIENnaMBIebtugeRbkugRtaMg 560
2. T.Chhay NPIC
sinebIkugRtaMgsgát;EdlGnuvtþdMbUgtUcCagkugRtaMgTajenAsrésEpñkxageRkambMput enaHsrésenA
EpñkxageRkamenHrgkarTaj ÉsrésEpñkxagelIbMputrgkarsgát;.
esckþIENnaMBIebtugeRbkugRtaMg 561
3. T.Chhay NPIC
kñúgkarGnuvtþ Ggát;ebtugGacrgeRbkugRtaMgtamviFImYykñúgcMeNamviFIxageRkam³
!> karTajeRkay (Posttensioning): kñúgkareFVI posttensioning, eKTaj steel tendon
eRkayeBlebtugRtUv)ancak; nigkkrwg. kareFVI posttensioning RtUv)aneFVIeLIgtamviFI
saRsþdUcteTA³ dMbUgeKeRbI hydraulic jack Taj steel wire b¤ strand eGaylUt bnÞab;
mkCMnYs jack eday anchorage EdlGacrkSaeGay steel strand enAEtrgkarTaj. CaTU
eTA tendon RtUv)aneFVIeLIgBI wire, strand b¤ bar. eKGacTaj wire nig strand CaRkum)an
EteKTaj bar mþg)anEtmYy. kñúgdMeNIrkareFVI posttensioning, eKdak; steel tendon
eTAkñúgBum<muneBlcak;ebtug ehIy tendon RtUv)ankarBarkars¥itCab;eTAnwgebtugeday
waterproof paper wrapping b¤ metal duct (sheath). tendon Edls¥itCab;eTAnwg
ebutgRtUv)aneKehAfa boded tendon. Unbonded tendon/ RtUv)andak;edayKμan grout
b¤RtUv)anlabeRbg.
@> karTajmun (pretensioning): kñúgkareFVI prettensioning eKTaj steel tendon muneBlcak;
ebtug. eKTb; tendon CabeNþaHGasnñeday abutment ehIyeKkat;va bnÞab;ebtugRtUv)an
cak; nigkkrwg. kMlaMg prestessing RtUv)anepÞreTAebtugeday PaBs¥itenAtamRbEvgrbs;
tendon. CaTUeTA eKeRcIneFVI prettensioning enAkñúgkardæan b¤eragcRkpliteRKOgbgÁúMebtug
eRbkugRtaMgcak;eRsc EdlmankMralrwgmaMCaGciéRnþy_.
#> kareFVIeRbkugRtaMgxageRkA (external prestressing): kñúgkareFVI external pretessing, eK
GnuvtþkMlaMgeRbkugRtaMgeday flat jack EdlRtUv)andak;enAcenøaHcugGgát;ebtug nig
permanent rigid abutments. Ggát;minman prestressing tendon dUcviFITaMgBIrxagelI
EdleKGacehAfakareFVIeRbkugRtaMgxagkñúgeT. External prestressing mingayRsYlkñúg
karGnuvtþeT edaysar shrinkage nig creep enAkñúgebtugEdlnaMeGaymankarkat;bnßy
kugRtaMgsgát;EdlGnuvtþdMbUg.
Profile rbs; tenden GacRtg; ekag b¤ragrgVg;GaRs½yeTAelIkarKNnaGgát;eRKOgbgÁúM.
CaTUeTAeKeRbI straight tendon enAkñúg solid slab nig hollow-cored slab b:uEnþeKeRbI bent tendon
enAkñúgFñwm nigGgát;eRKOgbgÁúMPaKeRcIn. eKeRbI circular tendon enAkñúgeRKOgbgÁúMEdlmanTMrg;mUldUc
esckþIENnaMBIebtugeRbkugRtaMg 562
4. T.Chhay NPIC
Ca tank, silo nig pipe. eKGacGnuvtþkMlaMgeRbkugRtaMgEtkñúgmYydMNakkal b¤eRcIndMNakkaledIm,I
karBarebtugkMurGayrgkugRtaMgelIs.
eK)anbegáItnUvRbB½n§eRbkugRtaMgCaeRcIn EdlkñúgcMeNamenaHman Freyssinet, Magnel Blaton,
B.B.R.V., Dywidag, CCL, Morandi, VSL, Western Concrete, Prescon, nig INRYCO. eBlxøH
eKCYbnUvbBaðakñúgkareRCIserIsRbB½n§eRbkugRtaMgsMrab;kargarBiess.
visVkrKYrBicarNanUvktþacMbgbIEdlnaMdl;kareRCIserIsRbB½n§enH³
!> GaMgtg;sIueténkMlaMgeRbkugRtaMgEdlRtUvkar
@> ragFrNImaRtrbs;muxkat; nigKMlatEdlGacmansMrab; tendon
#> tMélénRbB½n§eRbkugRtaMg ¬sMPar³ nigkMlaMgBlkmμ¦
]TahrN_xageRkambgðajBIlkçN³Biessrbs;ebtugeRbkugRtaMg.
]TahrN_ 19>1³ sMrab;FñwmTMrsamBaØEdlbgðajenAkñúgrUbTI 19>2 cUrkMNt;kugRtaMgRtg;muxkat;
kNþalElVgEdlbNþalmkBITMgn;pÞal;xøÜnva nigkrNIénkardak;bnÞúk nigeRbkugRtaMg³
!> bnÞúkGefrBRgayesμI 13.15kN / m
@> bnÞúkGefrBRgayesμI 13.15kN / m nigkMlaMgsgát;tambeNþaycMp©it P = 1132kN
#> bnÞúkGefrBRgayesμI 30.61kN / m nigkMlaMgsgát;tambeNþaycakp©it P = 1132kN Edl
manGMeBIRtg;cMNakp©it e = 10cm
$> bnÞúkGefrBRgayesμI 39.28kN / m nigkMlaMgsgát;tambeNþaycakp©it P = 1132kN Edl
manGMeBIRtg;cMNakp©itGtibrmasMrab;muxkat; e = 15cm
%> bnÞúkGefrGtibrmaenAeBl P = 1132kN EdlmanGMeBIRtg; e = 15cm
eRbI b = 30cm / h = 60cm / f 'c = 31MPa nigkugRtaMgGnuBaØat f 'c = 14.14MPa
dMeNaHRsay³
!> kugRtaMgEdlbNþalmkEtBIbnÞúkefr nigbnÞúkGefr
bnÞúkpÞal;rbs;Fñwm = (0.3 × 0.6)24 = 4.32kN / m
wL2 4.32(7.2 )2
m:Um:g;bnÞúkefr M D.L. = 8 = 8 = 28kN .m
kugRtaMgenARtg;srésEpñkxageRkAbMputEdlbNþalBIbnÞúkefrKW
esckþIENnaMBIebtugeRbkugRtaMg 563
5. T.Chhay NPIC
Mc M (h / 2) 6 M
σ= = 3 =
I bh / 12 bh 2
6 × 28
σD = 10 − 3 = ±1.56MPa
0.3 × 0.6 2
m:Um:g;EdlbNþþalBIbnÞúkGefr L1 = 13.15kN / m KW
13.15 × 7.2 2
M L. L. = = 85.2kN .m
8
kugRtaMgEdlbNþalBIbnÞúkGefrKW
6M 6 × 85.2
σ L1 = = 10 − 3 = ±4.73MPa
bh 2
0.3 × 0.6 2
edayeFVIkarbUkbBa©ÚkkugRtaMgEdl)anBIbnÞúkefr nigbnÞúkGefr ¬rUbTI 19>2 a¦ eyIg)an
kugRtaMgxagelI = −1.56 − 4.73 = −6.29MPa ¬rgkarsgát;¦
kugRtaMgxageRkam = +1.56 + 4.73 = 6.29MPa ¬rgkarTaj¦
edaysarkugRtaMgTajFMCagm:UDuldac;rbs;ebtug f r = 0.62 31 = 3.45MPa dUcenHFñwmnwg)ak;.
@> kñúgkrNIEdlkugRtaMgbNþalBIeRbkugRtaMgesμI RbsinebIeKGnuvtþkMlaMgsgát; P = 1132KN
Rtg;TIRbCMuTMgn;rbs;muxkat; enaHmuxkat;tambeNþyFñwmnwgrgkugRtaMgesμI
P 1132
σp = = 10 − 3 = ±6.29MPa
area 0.3 × 0.6
kugRtaMgcugeRkayEdlbNþalBIbnÞúkGefr nigbnÞúkefrbUknwgbnÞúkeRbkugRtaMgenARtg;srés
xagelI nigxageRkambMputKW 12.58MPa nig 0 erogKña ¬rUbTI 19>2 b¦. kñúgkrNIenH kMlaMg
eRbkugRtaMg)anebgáInkugRtaMgsgát;enARtg;srésEpñkxagelIbMputeGaymantMélBIrdg nig)an
kat;bnßykugRtaMgTajenARtg;srésEpñkxageRkameGay esμInwg 0 . kugRtaMgsgát;Gtibrma
12.58MPa mantMéltUcCagkugRtaMgGnuBaØat f 'c = 14.14MPa .
#> sMrab;kugRtaMgEdlbNþalBIeRbkugRtaMgcMNakp©it ¬ e = 100mm ¦
RbsinebIeKGnuvtþkMlaMgeRbkugRtaMg P = 1132 KN enARtg;cMNakp©it e = 100mm BI eRkamTI
RbCMuTMgn;rbs;muxkat; kugRtaMgenARtg;srésEpñkxagelI nigEpñkxageRkambMputRtUv)ankMNt;
dUcxageRkam. m:Um:g;EdlbNþalBIeRbkugRtaMgcMNakp©itKW Pe
P (Pe )c P 6(Pe )
σp =− ± =− ±
A I A bh 2
1132 6(1132 × 0.1) − 3
=− 10 − 3 ± 10
0.3 × 0.6 0.3 × 0.6 2
esckþIENnaMBIebtugeRbkugRtaMg 564
6. T.Chhay NPIC
= −6.29 ± 6.29
enAsrésEpñkxageRkam σ p = −12.58MPa nig σ p = 0 enAsrésEpñkxageRkambMput.
BicarNaGMBIkardak;bnÞúkGefr L2 = 30.61kN / m
30.61× 7.2 2
M L. L. = = 198.36kN .m
8
6(198.36) − 3
σ L2 = 10 = ±11.02MPa
0.3 × 0.6 2
kugRtaMgcugeRkayEdlbNþalBIbnÞúkefr/ bnÞúkGefr nigkMlaMgeRbkugRtaMgenAsrésEpñkxagelI
nigEpñkxageRkambMputKW 12.58MPa nig 0 erogKña ¬rUbTI 19>2 c¦. cMNaMfa kugRtaMgcug
eRkaydUcKñanwgkrNIelIkmunenAeBlEdlbnÞúkGefresμInwg 13.15kN / m . edayGnuvtþkMlaMg
eRbkugRtaMgenARtg;cMNalp©it 10cm FñwmenHGacRTbnÞúkGefrEfm eTot ¬17.46kN / m ¦.
esckþIENnaMBIebtugeRbkugRtaMg 565
7. T.Chhay NPIC
$> sMrab;kugRtaMgEdlbNþalBIeRbkugRtaMgcakp©itRtg;cMNakp©itGtibrma
snμt;facMNakp©itGtibrmasMrab;muxkat;enHKW e = 15cm .
m:Um:g;Bt;EdlekItedaysarkMlaMgeRbkugRtaMgcakp©itKW Pe = 1132 × 0.15 = 169.8kN .m
esckþIENnaMBIebtugeRbkugRtaMg 566
8. T.Chhay NPIC
kugRtaMgEdlbNþalBIkMlaMgeRbkugRtaMgKW
1132 6(169.8) − 3
σp =− 10 − 3 ± 10
0.3 × 0.6 0.3 × 0.6 2
= −6.29 ± 9.41
= −15.7 MPa nig + 3.12
begáInbnÞúkGefrdl; L3 = 39.28kN / m . m:Um:g;Edl)anBIbnÞúkenHKW
39.28 × 7.2 2
M L. L. = = 254.5kN .m
8
kugRtaMgEdlbNþalmkBIbnÞúkGefrKW
6(254.5)
σ L3 = 10 − 3 = ±14.14MPa
0.3 × 0.6 2
kugRtaMgcugeRkayenAsrésEpñkxagelI nigEpñkxageRkambMputEdlbNþalBIbnÞúkefr nigbnÞúk
GefrKW 12.58MPa nig 0 erogKña ¬rUbTI 19>2 d¦. cMNaMfa kugRtaMgcugeRkaydUcKñanwgkrNI
mun²Edr b:uEnþbnÞúkGefr)anekIneLIgdl; 39.28kN / m . kugRtaMgTaj 1.56MPa RtUv)an
begáIteLIgenAsrésEpñkxagelIbMput enAeBlEdleKGnuvtþkMlaMgeRbkugRtaMg. kugRtaMgenH
mantMéltUcCagm:UDuldac;rbs;ebtug f r = 3.45MPa dUcenHvaminekItmansñameRbHenAelIFñwm
eT.
%> eKkMNt;bnÞúkGefrGtibrmaenAeBlkMlaMgeRbkugRtaMgcakp©iteFVIGMeBIenARtg; e = 15cm dUct
eTA. kñúgkrNImun² kugRtaMgsgát;cugeRkayesμInwg 12.58MPa EdltUcCagkugRtaMg GnuBaØat
f 'c = 14.14MPa . dUcenH bnÞúkGefrGacekIneLIgdl; L4 = 43.6kN / m .
43.6 × 7.2 2
M L. L. = = 282.5kN .m
8
6 × 282.5 − 3
σ L4 = 10 = 15.7 MPa
0.3 × 0.6 2
kugRtaMgcugeRkayEdlbNþalBIbnÞúkefr nigbnÞúkGefr L4 ehIynigkMlaMgeRbkugRtaMg KW
− 14.14 MPa nig + 1.56 MPa ¬rUbTI 19>2 e¦. kugRtaMgsgát;KWesμInwgkugRtaMgGnuBaØat
14.14 MPa ehIykugRtaMgTajKWtUcCag modulus of rupture rbs;ebtug 3.45MPa . kñúg
krNIenH eKGacKNnabnÞúkGefrBRgayEdlesμμInwg 43.6kN / m dUcteTA³ bUkkugRtaMgsgát;
GnuBaØatGtibrma 14.14MPa CamYynwgkugRtaMgTajdMbUgenARtg;srésEpñkxagelIbMput
esckþIENnaMBIebtugeRbkugRtaMg 567
9. T.Chhay NPIC
1.56 MPa edIm,ITTYl)an 15.7MPa . m:Um:g;EdlnwgbegáItkugRtaMgenAsrésEpñkxagelIbMput
15.7 MPa esμInwg
⎛ bh 2 ⎞
M =σ⎜ ⎟
⎜ 6 ⎟
⎝ ⎠
=
15.7
(0.3)(0.6)2 ⋅103 = 282.6kN.m
6
W L2
M= L
8
eyIgTTYl)an
8 × 282.6
WL = = 43.6kN / m
7.2 2
cMNaMfa³
!> muxkat;ebtugTaMgmUlKWskmμkñúgkarTb;Tl;CamYykMlaMgxageRkA
@> kugRtaMgTajcugRkayenAkñúgmuxkat;tUcCag modulus of rupture rbs;ebtug Edlbgðaj
famuxkat;ebtugminmansñameRbHeRkamGMeBIrbs;bnÞúkGtibrma
#> bnÞúkGnuBaØatenAelIFñwmekIneLIgeRcInKYrsmedaysarkarGnuvtþrbs;kMlaMgeRbkugRtaMg
$> karekIneLIgnUvcMNakp©itrbs;kMlaMgeRbkugRtaMgk¾begáInkMlaMgGnuvtþn_GnuBaØat EdleFVIeGay
kugRtaMgenAelImuxkat;minFMCagkugRtaMgGnuBaØat.
x> karGnuvtþeRbkugRtaMgedayEpñk Partial Prestressing
eKkMNt;Ggát;ebtugeRbkugRtaMgedayEpñk (partially prestressed concrete member) CaGgát;
Edl³
- kugRtaMgxagkñúgEdlmanGMeBITb;EpñkénkugRtaMgEdlekItBIbnÞúkxageRkA
- kugRtaMgTajekItmanenAkñúgebtugeRkamGMeBIbnÞúkeFVIkar (service load)
- EdkBRgwgminEmnCaEdkeRbkugRtaMgRtUv)andak;bEnßmedIm,IbegáInlT§PaBrbs;Ggát; edIm,ITb;
nwgm:Um:g;
eKGacBicarNa partially prestressed concrete tamBIrkrNI³
!> eKeRbIEdkeRbkugRtaMg nigEdkminEmneRbkugRtaMgenAkñúgmuxkat;EtmYy. ExSkabeRbkugRtaMg
begáItkugRtaMgxagkñúgRtUv)anKNnaedIm,ITTYl)an ultimate capacity rbs;muxkat;ebtugEt
mYyEpñkb:ueNÑaH. cMENkÉ capacity EdlenAsl;RtUv)anTTYlBIEdkminEmneRbkugRtaMg
esckþIENnaMBIebtugeRbkugRtaMg 568
10. T.Chhay NPIC
Edldak;tamTisdUcKñanwgkabeRbkugRtaMg. EdkEdleRbICaEdkminEmneRbkugRtaMgGacCaRb
ePTEdkFmμta dUcCaEdk carbon steel b¤CaEdk high-tensile-strength. kabeRbkugRtaMgk¾
CaRbePTEdkFmμtadUcEdkminEmneRbkugRtaMgEdr Etvaman ultimate strength esμInwg
1725MPa ¬ 250ksi ¦. kareRCIserIsGaRs½ynwgktþacMbgBIrKW³ PaBdabGnuBaØat nigTMhM
sñameRbHGnuBaØat. dUcKña ACI Code kMNt;nUvpleFobGtibrmaénRbEvgElVgelIkkMBs;én
Ggát;ebtugGarem: sMrab;PaBdab. eKminGnuBaØateGaymanPaBdabFMelIslubCamYynwg
kMBs;rbs;muxkat;ebtugeRbkugRtaMgtUc nigedaysarkareRbIPaKryEdktic. sñameRbHekIt
manenAtMbn;rgkarTajrbs;muxkat;ebtug b¤enARtg;nIv:UEdkedaysareKGnuBaØateGaykug
RtaMgTajekItmaneRkamGMeBI working load. eKGnuBaØatsñameRbHGtibrmaRtwm 0.016in.
(0.41mm) sMrab;Ggát;xagkñúg nig 0.013in. (0.33mm) sMrab;Ggát;xagkñúg.
@> kugRtaMgxagkñúgEdleFVIGMeBIelIGgát;)anEtBI prestrssed steel b:ueNÑaH b:uEnþvaRtUv)anTajCa
mYynwgEdnkMNt;TabCag. kñúgkrNIenHsñameRbHekItmanelOnCagGgát;rgeRbkugRtaMgeBj
eljeRkambnÞúkdUcCaKña.
eKGacBicarNa partially prestresssed concrete kñúgTMrg;kNþalrvagebtugGarem: nigebtug
eRbkugRtaMgeBj (fully prestressed concrete). enAkñúgGgát;ebtugGarem: sñameRbHekItmaneRkamGMeBI
bnÞúkeFVIkar dUcenHeKdak;EdkBRgwgenAkñúgtMbn;Taj. CaTUeTAenAkñúgGgát;ebtugeRbkugRtaMg sñameRbH
minekItmaneRkamGMeBIbnÞúkeFVIkareT. kugRtaMgsgát;EdlbNþalBIkMlaMgeRbkugRtaMgGacesμI b¤elIsBI
kugRtaMgTajEdlbNþalBIbnÞúkxageRkA. dUcenHeKGacBicarNaGgát; partially prestressed concrete
CaGgát;ebtugGarem:EdlkugRtaMgxagkñúgrbs;vamanGMeBITb;nwgEpñkxøH rbs;kugRtaMgEdl)anBIbnÞúkxag
eRkA dUcenHkugRtaMgTajenAkñúgebtugminRtUvFMCagtMélkMNt;eRkambnÞúkeFVIkareT. eKKitvaCaebtug
Garem:enAeBlNaEdlminmankugRtaMgxagkñúgeFVIGMeBIelIGgát;. ebtugeRbkugRtaMgeBjCakMritx<s;bMput
rbs;ebtugeRbkugRtaMgedayEpñk EdlenAkñúgenaHEdkminEmneRbkugRtaMgRtUv)ankat;bnßydl;sUnü.
enAcenøaHGgát;ebtugGarem:EdlmaneRbH nigGgát;ebtugeRbkugRtaMgeBjEdlminmaneRbH eK
manEdnd¾FMsMrab;KNnaebtugeRbkugRtaMgedayEpñk ¬rUbTI 19>3¦. kareRCIserIskMriténkareFVIeRbkug
RtaMgd¾l¥ nwgbegáItnUveRKOgbgÁúMEdlmansuvtßiPaB nigmanlkçN³esdækic©.
esckþIENnaMBIebtugeRbkugRtaMg 569
11. T.Chhay NPIC
rUbTI 19>3 bgðajBIExSekagPaBdab-bnÞúkrbs;FñwmebtugGarem:EdlmanbrimaNEdk nigRbePT
EdkxusKña. ExSekag a bgðajBIFñwmebtugGarem: EdlmansñameRbHFmμtaeRkambnÞúktUc Wcr . eKGackM
Nt;m:Um:g;EdleFVIeGayeRbH (cracking moment) dUcxageRkam³
fr I
M cr =
c
Edl m:UDuldac;rbs;ebtug = 0.62 f 'c
fr =
I = m:Um:g;niclPaBén gross concrete section
c = cMgayBIG½kSNWteTAsrésrgkarTajxageRkAbMput
eKGackMNt;ebtugEdleFVIeGayeRbH (cracking load) BI cracking moment enAeBlRbEvg
ElVg nigRbePTénkardak;bnÞúkRtUv)ankMNt;. sMrab;FñwmTMrsamBaØEdlrgbnÞúkcMcMnugenAkNþalElVg
Wcr = (4M cr ) / L .
esckþIENnaMBIebtugeRbkugRtaMg 570
12. T.Chhay NPIC
ExSekag e nig f bgðajBIFñwmebtugeRbkugRtaMgeBjEdlmanEdktic nigEdkeRcIn erogKña. Fñwm
ebtugGarem:EdlmanbrimaNEdkeRcIn)ak;edaysarkarEbkebtugmunnwgEdkeTAdl; yield strength b¤
proof stress rbs;va. FñwmmanPaBdabtUc nwgrgkar)ak;edayPaBRsYy (brittle failure). FñwmEdlman
brimaNEdktic)ak;edaysarEdkeFVIkardl; yield nig ultimate strength rbs;va. vabgðajnUv)abdab
nigsñameRbHEdlbNþalBIkarlUtsac;rbs;EdkmuneBlebtugEbkCabnþbnÞab; ehIyFñwm)ak;rlM.
enAcenøaHExSekag a nig e CaEdnd¾FMrbs;FñwmebtugCamYynwgbrimaNERbRbYlrbs;Edk nigrg
nUvbrimaNERbRbYlrbs;kMlaMgeRbkugRtaMg. FñwmEdlrgkMlaMgeRbkugRtaMgtUcenAEk,rExSekag a ehIy
FñwmEdlmaneRbkugRtaMgFMenAEk,rExSekag e . eKeRCIserIsbnSMEdkeRbkugRtaMg nigEdkminEmneRbkug
RtaMgsMrab;karKNnaKWGaRs½yelIkugRtaMgebtugGnuBaØat PaBdab nigTMhMsñameRbHGtibrma.
ExSekag b tMNageGayFñwmEdlnwgeRbHeRkamGMeBIénbnÞúkeFVIkareBjelj. RbsinebIEtEpñk
xøHrbs;bnÞúkGefrekItmanenAelIeRKOgbgÁúMCaerOy² enaH W1 tMNageGaybnÞúkefrsrub nigEpñkxøHrbs;
bnÞúkGefr L1 .
ExSekag c tMNageGayFñwmcab;epþImeRbHeRkamGMeBI working load. kugRtaMgTajGtibrmaenA
kñúgebtug = f r = 0.62 f 'c .
ExSekag d tMNageGayFñwmEdlmankMlaMgeRbkugRtaMgkMNt;. muxkat;eRKaHfñak;rbs;Fñwmnwg
mineRbHeRkambnÞúkeFVIkareBjeljeT b:uEnþvanwgmankugRtaMgTajGtibrma 0 < f r < 0.62 f 'c . ACI
Code GnuBaØatkugRtaMgTajGtibrmaenAkúñgebtugRtwm 0.5 f 'c .
ExSekag e nig e' tMNageGayFwñmebtugeRbkugRtaMgeBjeljEdlminmankugRtaMgTajeRkam
bnÞúkeFVIkar ¬emIlrUbTI 19>4¦.
sar³RbeyaCn_d¾sMxan;bMputrbs;kMlaMgeRbkugRtaMgedayEpñkKWlT§PaBkúñgkarRKb;RKgkMeNag
(camber). edaykat;bnßykMlaMgeRbkugRtaMg camber nwgRtUv)ankat;bnßy ehIysnSMnUvbrimaNEdk
eRbkugRtaMg brimaNkargarkúñgkarTaj nigcMnYn end anchorage.
GaRs½ynwgGaMgtg;sIueténkMlaMgeRbkugRtaMg sñameRbHenAkñúg partially prestressed member
ekIteLIgelOnCagenAkñúg fully prestressed concrete member eRkamGMeBIrbs; service load. enA
eBlEdlsñameRbHekItman m:Um:g;niclPaBRbsiT§PaBrbs;muxkat;eRKaHfñak;RtUv)ankat;bnßy ehIyeK
nwgTTYl)anPaBdabFMCagmun. b:uEnþ kareRbIkMlaMgeRbkugRtaMgedayEpñkKWeKTTYl)anlT§plKYrCaTU
eBjcitþ ehIyvaTTYl)ankareBjniym.
esckþIENnaMBIebtugeRbkugRtaMg 571
13. T.Chhay NPIC
K> karcat;cMNat;fñak;Ggát;rgkarBt;ebtugeRbkugRtaMg
Classification of Prestressed Concrete Flexural Members
ACI Code, Section 18.3 )anEckGgát;ebtugeRbkugRtaMgCabIfñak;edayQrelIkugRtaMgTaj
enAelIsrésxageRkAbMput f t enAkñúgtMbn;TajeRkamGMeBIbnÞúkeFVIkardUcxageRkam³
!> fñak; U (uncracked section) Edlman f t ≤ 0.62 f 'c . enAkñúgmuxkat;ebtugEdlKμansñam
eRbHenH eKeRbIlkçN³én gross section edIm,IRtYtBinitüPaBdabeRkamGMeBIbnÞúkeFVIkar.
KμansñameRbHekItmanenAkñúgmuxkat; nigeKminRtUvkar skin reinforcement eT.
@> fñak; T (muxkat;enAkñúg transition zone) Edlman 0.62 f 'c < ft ≤ f 'c . muxkat;
RbePTenHmankugRtaMgTajenAkñúgebtugFMCagm:UDuldac; (modulus of rupture) rbs;ebtug
f r = 0.62 f 'c EdlbegáItnUvkrNIcenøaHmuxkat;eRbH nigmuxkat;Gt;eRbH. enAkñúgkrNIenH
eKeRbIlkçN³én gross section edIm,IRtYtBinitükugRtaMg ehIyeKeRbI bilinear section rbs;
muxkat;eRbHedIm,IKNnaPaBdab. eKmincaM)ac;eRbI skin reinforcement enAkñúgtMbn;TajeT.
#> fñak; C (cracked section) Edlman f t > f 'c . kugRtaMgTajenAkúñgmuxkat;FMCag
modulus of rupture rbs;ebtug 1.6 dg. dUcenH sñameRbHnwgekItmandUckñúgkrNIGgát;eb
tugeRbkugRtaMgedayEpñk. enAkñúgkrNIenH eKeRbIlkçN³énmuxkat;eRbHedIm,IRtYtBinitükug
esckþIENnaMBIebtugeRbkugRtaMg 572
14. T.Chhay NPIC
RtaMg sñameRbH nigPaBdab. eKKYreRbIkarpþl;eGayedIm,IRKb;RKgsñameRbH nigeRbI skin
reinforcement dUckarBnül;enAkñúgEpñk 6>7 sMrab;Ggát;ebtugGarem:EdlmankMBs;RbsiT§-
PaB d > 915mm .
2> sMPar³ nigtMrUvkarsMrab;bMerIbMras; Material and Serviceability Requirement
k> ebtug Concrete
lkçN³rbs;ebtugRtUv)anbgðajenAkñúgCMBUk 2. eTaHbICaerOy² Ggát;ebtugGarem:RtUv)anplit
BIebtugEdlmanersIusþg;sgát; 21MPa eTA 35MPa k¾eday k¾Ggát;ebtugeRbkugRtaMgRtUv)anplitBI
sMPar³EdlmanersIusþg;x<s;Cag CaTUeTAsßitenAcenøaH 28MPa eTA 56MPa . eKeRbIebtugersIusþg;x<s;
sMrab;Ggát;ebtugcak;eRsc nigGgát;ebtugeRbHkugRtaMg Edlkarlay karcak; karbgðab; nigkarEfTaMeb
tugsßiteRkamkarRtYtBinitüy:agm:t;ct;.
kugRtaMgGnuBaØatenAkñúgebtugEdleyagtam ACI Code, Section 18.4 mandUcxageRkam³
!> kugRtaMgeRkayeBlepÞreRbkugRtaMg (prestress transfer) nigmuneBl)at;bg;eRbkugRtaMg
(prestress losses):
a. kugRtaMgsgát;GtibrmaesμInwg 0.6 f ci
b. kugRtaMgTajGtibrma ¬elIkElgGVIEdl)anGnuBaØatdUcxageRkam¦ esμInwg 0.25 f ci
c. kugRtaMgTajGtibrmaenARtg;cugénGgát;TMrsamBaØesμInwg 0.5 f ci
Edl f ci CaersIusþg;rbs;ebtugenAeBlepÞr
RbsinebIkugRtaMgTajmantMélFMCagenH eKRtUvdak;EdkenAtMbn;sgát;edIm,ITb;Tl;kMlaMgTaj
srubenAkñúgebtug ¬edayQrelI uncracked gross section¦.
@> kugRtaMgeRkamGMeBIbnÞúkeFVIkareRkayeBlkMhatbg; (loss) TaMgGs; ¬sMrab;fñak; U nigfñak; T ¦
mandUcteTA³ kugRtaMgsgát;Gtibrma 0.45 f 'c EdlbNþalBIkMlaMgeRbkugRtaMgbUknwgbnÞúkefr
nigkugRtaMg 0.05 f 'c EdlbNþalBIkMlaMgeRbkugRtaMgbUknwgbnÞúksrub.
#> kugRtaMgTaMgenHGacmantMélFMCagenH RbsinebIkarBiesaF nigkarviPaKbgðajfakaRbRBwtþeTA
rbs;vaRKb;RKan;.
esckþIENnaMBIebtugeRbkugRtaMg 573
15. T.Chhay NPIC
x> EdkeRbkugRtaMg Prestressing Steel
Edk tendon EdleKniymeRbICageKenAkñúgebtugeRbkugRtaMgCa strands ¬b¤kab¦ Edlplit
eLIgCamYynwglYssrésr (wire) CaeRcIn CaTUeTAmancMnYn 7 b¤ 19 . Wire nig bar k¾RtUv)aneKeRbI
R)as;pgEdr. Stand nig wire RtUv)anpliteLIgedayeKarBtam ASTM Standard A421 sMrab;
uncoated stress-relieved wire nig A416 sMrab; uncoated seven-wire stress-relieved strand.
lkçN³rbs;EdkeRbkugRtaMgRtUv)aneGayenAkñúgtarag 19>1.
tarag 19>1
Diameter Area Mass
Type
(mm) (mm2) (kg/m)
Seven-wire strand (grade 250) 6.350 23.2 0.179
7.950 37.4 0.298
9.525 51.6 0.402
11.125 69.7 0.551
12.700 92.9 0.729
15.240 139.4 1.101
Seven-wire strand (grade 270) 9.525 54.8 0.432
11.125 74.2 0.595
12.700 98.7 0.789
15.250 138.7 1.101
Prestressing wire grades (250) 4.877 18.7 0.146
(250) 4.978 19.4 0.149
(240) 6.350 31.6 0.253
(235) 7.010 38.7 0.298
Prestressing bars (smooth) 19.050 283.9 2.232
(grade 145 or 160) 22.225 387.1 3.036
25.400 503.2 3.973
28.575 638.7 5.030
31.750 793.5 6.206
34.925 954.8 7.515
Prestressing bars (deformed) 15.875 180.6 1.458
(grade 150-160) 19.050 271.0 2.218
25.400 548.4 4.480
31.750 806.5 6.535
34.925 1006 8.274
EdkeRbkugRtaMgEdleRbIenAkñúgebtugeRbkugRtaMgRtUvEtmanersIusþg;x<s; CaTUeTAman
ultimate strength f puenAcenøaH 1730MPa eTA 1860MPa . eKcaM)ac;GnuBaØateGayEdkersIusþg;
x<s;mansac;lUtFM nigrkSakugRtaMgenAkñúgebtugeGayRKb;RKan; nigGciéRnþy_bnÞab;BI inelastic
shortening rbs;ebtug.
esckþIENnaMBIebtugeRbkugRtaMg 574
16. T.Chhay NPIC
kugRtaMgGnuBaØatenAkñúgEdkeRbkugRtaMgeyagtam ACI Code, Section 18.5 mandUcxageRkam³
!> kugRtaMgGtibrmaEdlbNþalBI tendon jacking force minRtUvFMCagtMélEdltUcCageKkñú
gcMeNam 0.8 f pu nig 0.94 f py . tMélEdltUcCagminRtUvFMCagkugRtaMgEdlENnaMedayGñk
plit tendon b¤ anchorage eT.
@> kugRtaMgGtibrmaenAkñúg pretensioned tendon Pøam²eRkayeBlepÞrminRtUvFMCagtMéltUc
CageKkñúgcMeNam 0.74 f pu nig 0.82 f py .
#> kugRtaMgGtibrmaenAkñúg postensioned tendon eRkayeBl tendon RtUv)an anchor KW
0.70 f pu .
K> EdkBRgwg Reinforcing Steel
CaTUeTA eKeRbIEdkBRgwgminEmneRbkugRtaMgenAkúñgGgát;eRKOgbgÁúMebtugeRbkugRtaMg
CaBiessenAkñúgsMNg;ebtugeRbkugRtaMgcak;eRsc. eKeRbIEdkBRgwgCaEdkkMlaMgkat;TTwg Ca
EdkbEnßmsMrab;kardwkCBa¢Ún nigkarelIkdak;Ggát;cak;eRsc ehIynigeRbIenAkñúgGgát;ebtugeRb
kugRtaMgedayEpñkEdlcUlrYmCamYynwgEdkeRbkugRtaMg. RbePT nigkugRtaMgGnuBaØatrbs;Edk
RtUvENnaMenAkñúgCMBUk 2 nigCMBUk 5 rYcehIy.
3> kMhatbg;eRbkugRtaMg Loss of Prestress
k> Lump-sum losses
kMhatbg;énkMlaMgeRbkugRtaMgCabnþbnÞab;ekItmaneRkayeBlkMlaMgeRbkugRtaMgRtUv)an
epÞrBI jack eTaGgát;ebtug. kMhatbg;eRbkugRtaMgCakarkat;bnßykMlaMgeRbkugRtaMgkñúgmYy
CIviténeRKOgbgÁúM. brimaNkMhatbg;enAkñμúg tendon ERbRbYlcenøaHBI 15% eTA 30% énkugRtaMg
edIm edayGaRs½ynwgktþaCaeRcIn. sMrab;eRKOgbgÁúMebtugGarem:TMgn;FmμtaPaKeRcInEdlsagsg;eday
standard method, tendon stress loss bNþalmkBI elastic shortening, shrinkage, creep nig
relaxation rbs;EdkKWmantMélRbEhlnwg 35ksi(241MPa ) sMrab; pretensioned member nigsMrab;
esckþIENnaMBIebtugeRbkugRtaMg 575
17. T.Chhay NPIC
posttensioned member KWRbEhlbwg 25ksi(172MPa) . kMlaMgkkit nig anchorage slip minRtUv)an
rab;bBa©ÚleT.
karENnaMBIrsMrab;kar)a:n;sμankMhatbg;srubenAkñúgGgát;ebtugeRbkugRtaMgRtUv)anbgðajeday
AASTHO nig Posttensioning Institute (PTI). AASTHO ENnaMeGayykkMhatbg;srub
(edayminKitkMlaMgkkit) 45ksi(310 MPa ) sMrab; pretensioned strand nig 33ksi(228MPa ) sMrab;
postentioned strand nig wire enAeBlEdleKeRbIersIusþg;sgát;ebtug f 'c = 35MPa . PTI ENnaM
lump-sum prestress loss sMrab; posttensioned member 35ksi(241MPa ) sMrab;Fñwm nig
30ksi(207 MPa ) sMrab;kMralxNÐ ¬edayminKitkMlaMgkkit¦. eKGaceRbItMélTaMgGs;enH)anluHRta
EteK)aneFVIkar)a:n;RbmaNkMhatbg;eRbkugRtaMgedayRbPBénkMhatbg;nImYy²dac;edayELkBIKña)an
l¥ dUcEdl)anENnaMy:agsegçb.
CaTUeTA RbPBénkMhatbg;eRbkugRtaMgKW
- Elastic shortening rbs;ebtug
- Shrinkage rbs;ebtug
- Creep rbs;ebtug
- Relaxation rbs;Edk tendon
- kMlaMgkkit
- Anchorage set
x> kMhatbg;edaysar Elastic Shortening of Concrete
kar)a:n;RbmaNkMhatbg; elastic shortening rbs;ebtugenAkñúg pretensioned member
RtUv)aneFVIeLIgdUcteTA. BicarNa pretensioned concrete member énmuxkat;efr nigkugRtaMgBRgay
esμItambeNþayG½kSTIRbCMuTMgn;rbs;vaedaysarkMlaMg Fo . eRkayBIkarepÞrkMlaMgeRbkugRtaMgFñwmebtug
nig prestressing tendon rYjxøIedaybrimaNesμIKña edaysarPaBs¥itrvagsMPar³TaMgBIr. dUcenH kMlaMg
eRbkugRtaMgEdlcab;epþIm Fo Føak;mkRtwm Fi ehIykMhatbg;kMlaMgeRbkugRtaMgKW Fo − Fi . dUcKña
strain enAkñúgebtug ε c RtUvEtesμInwgbMErbMrYl strain rbs; tendon Δε s . dUcenH ε c = Δε s b¤
( f c / Ec ) = (Δf s / E s ) ehIykMhatbg;kugRtaMgEdlbNþalBI elastic shortening KW
esckþIENnaMBIebtugeRbkugRtaMg 576
18. T.Chhay NPIC
Es nF nF
Δf s = × f c = nf c = i ≈ o (19.1)
Ec Ac Ac
Edl RkLaépÞrbs;muxkat;ebtug
Ac =
n = E s / Ec = pleFobm:UDul (modular ratio)
f c = kugRtaMgrbs;ebtugenARtg;TIRbCMuTMgn;rbs;EdkeRbkugRtaMg
KuNkugRtaMgnwgRkLaépÞrbs;EdkeRbkugRtaMg Asp edIm,ITTYl)ankMlaMgsrub . Elastic loss KW
⎛ nF ⎞
ES = Fo − Fi = Δf s Asp = (nf c )Asp ≈ ⎜ o
⎜ A ⎟ Asp
⎟ (19.2)
⎝ c ⎠
Fi = Fo − (nf c )Asp (19.3)
sMrab;karKNnaGnuvtþn_ kMhatbg;kugRtaMgénkMlaMgeRbkugRtaMg ¬ Δf s kñúgmYyktþaépÞ Asp ¦ mantMél
Rbhak;RbEhlnwg nFo / Ac . RbsinebI kMlaMg Fo manGMeBIRtg;cMNakp©it e enaH elastic loss Edl
bNþalBIvtþmanén Fo nigbnÞúkefrGnuvtþn_enAeBlepÞrKW
ES = −(nf c )Asp ¬EdlbNþalBIeRbkugRtaMg¦ + (nf c )Asp ¬bnÞúkefr¦
⎛ F F e2 ⎞ ⎛M e⎞
ES = Fo − Fi = −⎜ i + i ⎟nAsp + ⎜ D ⎟nAsp (19.4)
⎜ A ⎟
I ⎠ ⎝ I ⎠
⎝
eKGaceRbItMélRbhak;RbEhlén Fi = (0.63 f pu )Asp enAkñúgsmIkarxagelI.
⎡ ⎛ 1 e 2 ⎞⎤
Fo + f c (D.L.)nAsp = Fi ⎢1 + nAsp ⎜ + ⎟⎥ (19.5)
⎜A I ⎟
⎢
⎣ ⎝ ⎠⎥
⎦
Fi =
( )
Fo + nAsp f c (D.L.)
⎛ 1 e2 ⎞
( )
1 + nAsp ⎜ + ⎟
⎜A I ⎟
⎝ ⎠
sMrab; posttensioned member Edl tendon nig individual strand minrgkugRtaMgdMNalKña enaHeK
GackMhatbg;eRbkugRtaMgesμInwgBak;kNþaléntMél ES sMrab; prestensioned member.
dUcKña eKGacyk elastic shortening loss enAkñúgkMralxNÐesμInwgmYyPaKbYnéntMél ES
sMrab; prestensioned member edaysarkarlUtrbs; tendon mYymanT§iBltictYceTAelIkugRtaMgén
tendon d¾éTeTot.
K> kMhatbg;edaysarkarrYmmaD Loss Due to Shrinkage
kMhatbg;eRbkugRtaMgEdlbNþalBIkarrYmmaDKWGaRs½ynwgeBl. eKGac)a:n;RbmaNvadUcxag
eRkam³
esckþIENnaMBIebtugeRbkugRtaMg 577
19. T.Chhay NPIC
SH = Δf s (shrinkage) = ε sh E s (19.6)
Edl Es = 2 ⋅105 MPa nig ε sh = shrinkage strain enAkñúgebtug
eKGacsnμt; Strain mFümEdlbNþalBIkarrYmmaDmantMéldUcxageRkam³
- ε sh1 = 0.0003 sMrab; pretensioned member
- ε sh2 = 0.0002 sMrab; posttentioned member
RbsinebIeKGnuvtþ posttensioning kñúgcenøaH 5 eTA 7 éf¶eRkayBIcak;ebtug/ eKGacyk shrin-
kage strain esμInwg 0.8ε sh1 . RbsinebIeKGnuvtþ posttensioning kñúgcenøaH 1 s)aþh_eTA 2 s)aþh_ eK
GaceRbI ε sh = 0.7ε sh1 nigRbsinebIeKGnuvtþ posttensioning eRkayeBlcak;ebtugeRcInCag 2 s)aþh_
enaHeKGacyk ε sh = ε sh2 . eKk¾Gac)a:n;RbmaNkMhatbg;edaykarrYmmaD SH dUcxageRkam³
⎛ 0.06V ⎞
SH = 8.2 × 10 − 6 K sh E s ⎜1 − ⎟(100 − RH )
⎝ S ⎠
Edl V / S = pleFobmaDelIépÞ nig RH = average relative humidity. K sh = 1.0 sMrab; pretensioned
member nigesμInwg 0.8 / 0.73 / 0.64 nig 0.58 sMrab; posttensioned member RbsinebIeKGnuvtþ
posttensioning eRkayeBlcak;ebtug 5 / 10 / 20 nig 30 éf¶ erogKña.
X> kMhatbg;edaysar creep rbs;ebtug
CakMhUcRTg;RTayGaRs½ynwgeBlEdlekIteLIgenAkñúgebtugeRkamGMeBIbnÞúkefr. kMhUc
Creep
RTg;RTayEdlekIteLIgedaysar creep eFVIeGay)at;bg;kMlaMgeRbkugRtaMgBI 5% eTA 7% .
Creep strain ERbRbYlCamYynwgGaMgtg;sIueténkugRtaMgedImenAkñúgebtug relative humidity
nigeBl. eKGackMNt;kMhatbg;kugRtaMgEdlbNþalBI creep dUcxageRkam³
CR = Δf s (creep) = Cc (nf c ) = Cc (ε cr E s ) (19>7)
creepstrain, ε cp
Edl emKuN
Cc = creep =
initial elastic strain, εi
eKGacyktMél Cc dUcxageRkam³
ersIusþg;ebtug f 'c ≤ 28MPa f 'c > 28MPa
Relative humidity 100% 50% 100% 50%
Cc 1− 2 2−4 0.7 − 1.5 1 .5 − 3
esckþIENnaMBIebtugeRbkugRtaMg 578
20. T.Chhay NPIC
eKGaceFVI interpolation sMrab;tMélEdlenAcenøaHtMélEdlenAkñúgtaragxagenH. edayKitfa
creep EtBak;kNþalekIteLIgkñúgGMLúg 134 ExdMbUgén 6 ExdMbUgbnÞab;BIkarepÞreRbkugRtaMgeTAebtug
nigeRkamlkçxNÐsMeNImFmμta enaHeKGacsnμt; creep strain sMrab;karKNnaGnuvtþn_dUcxageRkam³
!> sMrab; pretensioned members, ε cr = 7 ⋅10−5 × kugRtaMgenAkñúgebtug
@> sMrab; postensioned members, ε cr = 5.2 ⋅10−5 × kugRtaMgenAkñúgebtug. eKeRbItMélenH
enAeBlEdleKGnuvtþ posttensionning kñúgGMLúg 2 eTA 3 s)aþh_. sMrab;karGnuvtþ posten-
sioning elOnCagenH eKGaceRbItMélkNþal.
eKeRbItMélTaMgenH enAeBlEdlersIusþg;rbs;ebtugenAeBlepÞrKW f 'c ≥ 28MPa . enAeBlEdl
f 'c < 28MPa creep strain KYrekIneLIgkñúgGRta 4 / ersIusþg;Cak;Esþg.
kMhatbg;eRbkugRtaMgsrubEdlbNþalBI creep = ε cr Es (19.8)
g> kMhatbg;edaysar Relaxation rbs;Edk
Relaxation rbs;EdkbNþaleGaymankMhatbg;enAkñúgEdkeRbkugRtaMgGaRs½ynwgeBl Edl
RsedogKñanwg creep enAkñúgebtugEdr. kMhatbg;edaysar relaxation ERbRbYleTAtamRbePTEdk.
CaTUeTA tMélrbs;vaRtUv)anpþl;eGayedayGñkplitEdk. CaFmμta eKsnμt;kMbaatbg;enHesμInwg 3%
énkugRtaMgedImrbs;EdksMrab; posttensioned member nig 2% eTA 3% sMrab; pretensioned
members. RbsinebIeKminmanB½t’manBIkarBiesaFeT eKGacPaKrykMhatbg;sMrab; relaxation enA
1000h dUcxageRkam³
!> enAkñúg low-relaxation strands, enAeBlEdleRbkugRtaMgedImesμInwg 0.7 f pu nig 0.8 f pu /
relaxation (RE) KW 2.5% nig 3.5% erogKña.
@> enAkñúg stress-relieved strand b¤ wire, enAeBlEdleRbkugRtaMgedImesμInwg 0.7 f pu nig
0.8 f pu / relaxation (RE) KW 8% nig 12% erogKña.
c> kMhatbg;edaysarkMlaMgkkit Loss Due to Friction
CamYynwgEdkrg pretensioning kMhatbg;edaysarkMlaMgkkitekItmanenAeBlEdl wires b¤
strand dabtam diaphragm. CaFmμtakMhatbg;enHmantMéltUc ehIyeKGacecalva)an.
esckþIENnaMBIebtugeRbkugRtaMg 579
21. T.Chhay NPIC
enAeBlEdl strand dabtam concordant profile enaHkMhatbg;edaysarkMlaMgkkitGacmantMélFM.
enAkrNIEbbenH CaFmμtaeKeRbI]brkrN_Edlvas;bnÞúkCak;EsþgedIm,IkMNt;kMlaMgenAkñúg tendon.
CamYynwgEdkrg posttensioning, T§iBlénkMlaMgkkitmantMélFMedaysarktþacMbgBIrKW
kMeNagrbs; tendon nigkar)at;bg;PaBRtg;rbs;bMBg; (wobble). RbsinebIeKTb;cugbgáb;mçagrbs;
tendon edaykMlaMg P2 nigeKTajcugTMenrmçageTotrbs; tendon edaykMlaMg P edIm,IeGay tendon
1
enaHrGiltamTisrbs;kMlaMg P1 )anluHRtaEt
μα px
P = P2 e
1 (19.9)
Edl μ = emKuNmMukkitsþaTic nig α px = mMurvag P1 nig P2 . CaTUeTAeKKit wobble effect tamviFI
RsedogKña
Px = Ps e −(μα + Kl x )
Ppj = Ppx e
(
+ Kl px + μ pα px )
Ppx = Ppj e
(
− Kl px + μ pα px ) (19.10)
Edl kMlaMgeRbkugRtaMgenARtg;cMnuc x
Ppj =
Ppx = kMlaMgeRbkugRtaMgenARtg; jacking end
μ p = emKuNkMlaMgkkitedaysarkMeNag
α px = bMErbMrYlmMusrubénragtambeNþayrbs;EdkeRbkugRtaMgBI jacking end eTAdl;cMnuc x
KitCara:düg;
=
RbEvgkMeNag
kaMkMeNag
K = emKuNkMlaMgkkit wobble kñúgmYyÉktþaRbEvgrbs; tendon
CakarsMrYl ACI Code eGaynUvsmIkarxageRkamsMrab;krNI (μ pα px + Kl x ) ≤ 0.30 . lT§plEdl
TTYl)anBIsmIkarCatMélRbEhl
(
Ppx = Ppj 1 + Kl px + μ pα px )−1 (AIC Code, eq. 18.2) (19.11)
emKuNkMlaMgkkit μ nig K GaRs½ynwgRbePTén strand b¤ wire, RbePTbMBg; niglkçxNÐépÞ
b:H. ACI Commentaru, Sectin 18.6 nigenAkñúgtarag 19.2 eGaynUvtMélRbhak;RbEhlrbs; μ nig
K.
kMhatbg;edaysarkMlaMgkkitenAkñúg jack ERbRbYl nigGaRs½ynwgktþaCaeRcIn edayrab;
bBa©ÚlTaMgRbEvgrbs; tendon. eKENnaMeGayeRbI accurate load ceel edIm,Ivas;kMlaMgedaypÞal;.
esckþIENnaMBIebtugeRbkugRtaMg 580
22. T.Chhay NPIC
kareRbI pressure gauge pþl;nUvlT§plminsuRkit luHRtaEteKeFVIkarEktMrUveTAtamkMlaMgEdleKsÁal;
enAkúñúg tendon.
kMhatbg;edaysarkMlaMgkkitenAkñúg cnchorage KWGaRs½ynwgRbePT anchorage nigbrimaN
én deviation rbs; tendon Edlqøgkat; anchorage. CaFmμtakMhatbg;enHmantMéltUcEdlGac
ecal)an. karENnaMkñúgkrNIBiessKYrTTYl)anBIplitkr.
tarag 19>2 emKuNkMlaMgkkitsMrab; posttensioned tendon
emKuNkMlaMgkkit wobble K emKuNkMlaMgkMlaMgkkit
RbePT tendon
kñúgmYyÉktþaRbEvg (10 −3 ) edaysarkMeNag μ
Tendon in flexible metal sheathing
(grouted)
Wire tendon
3.33 − 5.0 0.15 − 0.25
Seven-wire strand
1.67 − 6.67 0.15 − 0.25
High-strength bars
0.33 − 2 0.08 − 0.30
Pregreased unbonded tendon
Wire tendon and seven-wire strand
1 − 6.67 0.05 − 0.15
Mastic-coated unbonded tendon
Wire tendon and seven-wire strand
0.33 − 0.67 0.05 − 0.15
q> kMhatbg;edaysar Anchor set
enAeBlkMlaMgenAkñúg tendon RtUv)anepÞrBI jack eTA anchorage unit, clnart;cUlkñúgbnþic
rbs; tendon ekIteLIgedaysarkardak; gripping device b¤ wedge. karrGilenHbNþaleGayman
tendon rYjxøI EdleFVIeGay)at;bg;kMlaMgeRbkugRtaMg. RbEvgrGilERbRbYlBI 2.5mm eTA 6mm ehIy
CaTUeTARtUv)ankMNt;edayplitkr. eKGacKNnakMhtbg; anchor set edayrUbmnþxageRkam³
ΔL
Δf s = ΔεE s = × Es (19.12)
L
Edl Δε = GaMgtg;sIueténkarrGil anchor
E s = 2 ⋅10 5 MPa
esckþIENnaMBIebtugeRbkugRtaMg 581
23. T.Chhay NPIC
RbEvgrbs; tendon
L=
edaysarkMhatbg;eRbkugRtaMgCacMras;smamaRteTAnwgRbEvgrbs; tendon ¬b¤RbEhlCaBak;kNþal
énRbEvgrbs; tendon RbsinebIvargkugRtaMgBIcugsgxagkñgeBlEtmYy¦PaKrykMhatbg;enAkñúgkug
ú
RtaMgEdknwgRtUv)ankat;bnßyenAeBlEdlRbEvgrbs; tendon ekIneLIg. RbsinebI tendon lUteday
Δε enAeBlepÞr enaHeKecalkMhatbg;eRbkugRtaMgedaysarkarrGil.
]TahrN_ 19>2³ FñwmTMrsamBaØrg pretensionning RbEvg 11m manmuxkat;ctuekaNEkgCamYynwg
b = 45cm nig h = 80cm . KNnakMhatbg;eGLasÞic nigkMhatbg;EdlGaRs½ynwgeBlTaMgGs;. eK
eGay³ kMlaMgeRbkugRtaMgenAeBlepÞrKW Fi = 1935kN / RkLaépÞrbs;EdkeRbkugRtaMgKW Aps =
1935mm 2 / f 'c = 35MPa / Ec = 34500MPa / E s = 2 ⋅105 MPa / profile rbs; tendon manrag
Ca)a:ra:bUl/ cMNakp©itenAkNþalElVg = 15cm nigcMNakp©itenAcug = 0 .
dMeNaHRsay³
!> kMhatbg;edaysar elastic shortening: kugRtaMgEdl)anBIkMlaMgeRbkugRtaMgenAeBlepÞrKW
Fi 1935 3
= 10 = 1000MPa
A ps 1935
f
rbs;EdkeRbkugRtaMg = Es = 210005 = 5 ⋅10 −3
strain
⋅10
s
edayeRbIsmIkar 19>1
E 2 ⋅10 5
n= s = = 5.8 yk 6
E 34500
c
nFi 6 × 1935 3
Δf s = = 10 = 32.25MPa
Ac 450 × 800
edayKitbMErbMrYlcMNakp©ittambeNþayFñwm
Fi
strain enAmuxkat;xagcug =
1935
= 10 3 = 1.56 ⋅10 − 4
AE 450 × 800 × 34500
c c
Fi e 2
strain enAkNþalElVg = AFE
i
+
IEc
c c
bh 3
450(800 )3
I= = = 1.92 ⋅1010 mm 4
12 12
1935 × 150 2
strain = 1.56 ⋅10 − 4 + 10 3 = 2.22 ⋅10 − 4
1.92 ⋅10 × 34500
10
esckþIENnaMBIebtugeRbkugRtaMg 582
24. T.Chhay NPIC
mFüm = 1 (1.56 + 2.22)10 − 4 = 1.89 ⋅10− 4
strain
2
kMhatbg;eRbkugRtaMg = strain × Es = 1.89 ⋅10−4 × 2 ⋅105 = 37.8MPa
PaKrykMhatbg; = 1000 = 3.78%
37.8
@> kMhatbg;edaysar shrinkage:
shrinkage strain = 0.0003
Δf s = ε sh E s = 0.0003 × 200000 = 60MPa
PaKrykMhatbg; =
60
1000
= 6%
#> kMhatbg;edaysar creep rbs;ebtug³ edaysnμt; Cc = 2.0 enaH Δf s = Cc (ε cr Es )
Fi
Elastic strain = = 1.56 ⋅10 − 4
Ac Ec
( )
Δf s = 2 1.56 ⋅10 −4 × 200000 = 62.4MPa
PaKrykMhatbg; =
62.4
1000
= 6.24%
b¤edaytMélRbhak;RbEhl eyIgyk ε cr = 7 ⋅10−5 × kugRtaMgenAkñúgebtug
⎛ 1935 ⎞
ε cr = 7 ⋅10 − 5 ⎜ 103 ⎟ = 3.76 ⋅10 − 4
⎝ 450 × 800 ⎠
Δf s = ε cr E s = 3.76 ⋅10 −4 × 200000 = 75.2MPa
PaKrykMhatbg; =
75.2
1000
= 7.52%
vaCatMélEdlmansuvtßiPaB ehIyeKnwgTTYl)anGRtadUcKñasMrab;karKNnaxagelIRbsinebIeKyk
Cc = 2.41 .
$> kMhatbg;edaysar relaxation rbs;Edk³ sMrab; low-relaxation strand eKsnμt;ykkMhatbg;
esμInwg 2.5%
Δf s = 1000 × 2.5% = 25MPa
%> snμt;kMhatbg;edaysarkarBt; kMlaMgkkitrbs; cable spacer nigbøúkxagcugrbs;RbB½n§
pretensioning KW 2% .
Δf s = 0.02 × 1000 = 20MPa
^> kMhatbg;edaysarkMlaMgkkitenAkñúg tendon KWsUnü.
&> kMhatbg;srubmandUcxageRkam
esckþIENnaMBIebtugeRbkugRtaMg 583
25. T.Chhay NPIC
Elastic Shortening 37.8MPa 3.78%
Shrinkage loss 60.0MPa 6.00%
Creep of concrete loss 62.4MPa 6.24%
Relaxation of steel loss 25.0MPa 2.50%
Other loss 20.0MPa 2.00%
Total loss 205.2MPa 20.52%
eRbkugRtaMgRbsiT§PaB = 1000 − 167.4 = 832.6MPa
kMlaMgeRbkugRtaMgRbsiT§PaB F = 832.6 ×1935 ⋅10 −3 = 1611kN
F = (1 − 0.167 )Fi = 0.833Fi
sMrab; F = ηFi
dUcenH η = 0.833
]TahrN_ 19>3³ KNnakMhatbg;TaMgGs;én posttensioned beam EdlmanRbEvg 36m . RkLaépÞ
rbs;muxkat;ebtug ( Ac ) = 49 ⋅104 mm 2 / m:Um:g;niclPaB (I g ) = 6.83 ⋅1010 mm 4 / kMlaMgeRbkugRtaMg
enAeBlepÞr (Fi ) = 4950kN / RkLaépÞEdkeRbkugRtaMg (Aps ) = 4840mm 2 / f 'c = 35MPa /
Ec = 34500MPa / nig E s = 2 ⋅10 5 MPa . Profile rbs; tendon manragCa)a:ra:bUl/ cMNakp©itenA
kNþalElVg = 50cm nigcMNakp©itenAxagcug = 0 .
dMeNaHRsay³
!> kMhatbg;eday elastic shortening:
kugRtaMgEdkenAeBlepÞr = AFi =
4950 3
4840
10 = 1022.7 MPa
ps
kugRtaMgenAkúñgebtugRtg;muxkat;xagcug = 49 ⋅104 103 = 10.1MPa
4950
2
kugRtaMgenAkúñgebtugRtg;muxkat;kNþalElVg = Ai + FiIe − MID e
F
c
TMgn;rbs;Fñwm = 49 ⋅10 −2 × 25 = 12.25kN / m
36 2
M D = 12.25 = 1984.5kN .m
8
4950 × 500 2 3 1982.5 × 500 6
kugRtaMgenAkNþalElVg =
4950
49 ⋅10 4
10 3 +
6.83 ⋅1010
10 −
6.83 ⋅1010
10
= 10.1 + 18.12 − 14.5 = 13.72 MPa
10.1 + 13.72
kugRtaMgmFüm =
2
= 11.9MPa
esckþIENnaMBIebtugeRbkugRtaMg 584
26. T.Chhay NPIC
mFüm = 11.9 = 34500 = 3.45 ⋅10− 4
strain
Ec
11.9
kMhatbg;eGLasÞicKW Δf s = ε c Es = 3.45 ⋅10 −4 × 2 ⋅105 = 69MPa edaysnμt;faeKTaj tendon
mþgBIrkñúgeBlEtmYy. KUrTImYynwgmankMhatbg;FMCageK b:uEnþKUrcugeRkaynwgmankMhatbg;esμIsUnü.
dUcenH kMhatbg;eGLasÞicmFüm Δf s = 69 / 2 = 34.5MPa .
PaKrykMhatbg; = 10225.7 = 3.37%
34.
@> kMhatbg;edaysarkarrYmmaDrbs;ebtug
Δf s (shrinkage) = 0.0002 E s = 0.0002 × 200000 = 40MPa
PaKrykMhatbg; =
40
1022.7
= 3.91%
#> kMhatbg;;edaysar creep rbs;ebtug³ snμt; Cc = 1.5
Fi 4950
elastic strain = = 10 3 = 2.93 ⋅10 − 4
Ac Ec 49 ⋅ 10 × 34500
4
( )
Δf s (creep) = Cc (ε cr E s ) = 1.5 2.93 ⋅10 −4 × 200000 = 87.9MPa
PaKrykMhatbg; =
87.9
1022.7
= 8.59%
$> kMhatbg;edaysar relaxation rbs;Edk³ sMrab; low-relaxation strand, kMhatbg;KW 2.5%
Δf s = 0.025 × 1022.7 = 25.6MPa
%> karrGilrbs; anchorage: sMrab;karTajEtBIcugmçag snμt;RbEvgrGil 3.8mm
ΔL 3.8
Δf s = Es = 200000 = 21.1MPa
L 36000
edIm,IGnuBaØateGaymankarrGilrbs; anchorage eKRtUvkMNt;kugRtaMgkñúgkarTaj 1022.7 + 21.1
= 1043.8MPa enAelI pressure gauge edIm,ITTYl net stress 1022.7 MPa enAkñúg tendon.
^> kMhatbg;EdlbNþalBIkMlaMgkit³ smIkar parabolic profile KW
e x = 2 (Lx − x 2 )
4e
L
Edl ex = cMNakp©itenARtg;cMgay x Edlvas;BITMr nig e = cMNakp©itenAkNþalElVg
d (e x ) 4e
= 2 (L − 2 x )
dx L
CaCMerl (slope) rbs; tendon enARKb;cMnucTaMgGs;. enARtg;TMr e = 0 eyIgTTYl)an slop
d (e x ) 4e 4 × 500
= = = 0.056
dx L 36000
esckþIENnaMBIebtugeRbkugRtaMg 585
27. T.Chhay NPIC
slope enAkNþalElVgesμIsUnü. dUcenH α px = 0.056 . edayeRbI flexible metallic sheath,
μ p = 0.5 nig K = 0.00333 . enAkNþalElVg x = 18m . RtYtBinitüfaetI (μ pα px + Kl x ) ≤ 0.30
μ pα px + Kl x = 0.5 × 0.056 + 0.00333 × 18 = 0.088 < 0.3
(
Ppx = Ppj 1 + Kl px + μ pα px )
= Px (1 + 0.088) = 1.088 Px
= 1.088 × 1022.7 = 1112.7 MPa ¬kMlaMgenAcug jacking¦
Δf s = 1112.7 − 1022.7 = 90MPa
PaKrykMhatbg; =
90
1022.7
= 8.8%
&> kMhatbg;srub
Elastic Shortening 34.5MPa 3.37%
Shrinkage loss 40.0MPa 3.91%
Creep of concrete loss 87.9MPa 8.59%
Relaxation of steel loss 25.6MPa 2.50%
Friction loss 90.0MPa 8.80%
Total loss 278.0MPa 27.17%
eRbkugRtaMgRbsiT§PaB = 1022.9 − 243.5 = 779.2MPa
kMlaMgeRbkugRtaMgRbsiT§PaB (F ) = (1 − 0.238)Fi = 0.762Fi
F = 0.762 × 4950 = 3772kN
sMrab; F = ηFi
dUcenH η = 0.762
4> viPaKGgát;rgkarBt;begáag Analysis of Flexural Members
k> kugRtaMgEdlbNþalBIlkçxNÐmanbnÞúk niglkçxNÐKμanbnÞúk
Stresses Due to Loaded and Unloaded condition
enAkñúgkarviPaKFñwmebtugeRbkugRtaMg CaTUeTAkardak;bnÞúkBIrmaneRKaHfñak;CageK. TImYyKWekIt
manenAeBlepÞr KWenAeBlFñwmrgkMlaMgeRbkugRtaMg Fi ehIyTMgn;rbs;Fñwm b¤bnÞúkefrGnuvtþn_enAxN³én
karepÞrkMlaMgkugRtaMg. eKminKitlkçxNÐbnÞúkefrbEnßm b¤bnÞúkGefreT. kñúglkçxNÐKμanbnÞúkenH kug
RtaMgenAsrésEpñkxagelIbMput nigEpñkxageRkambMputénmuxkat;eRKaHfñak;minRtUvFMCagkugRtaMgenA
eBlepÞr f ci nig f ti sMrab;kugRtaMgrgkarsgát; nigkugRtaMgrgkarTajrbs;ebtugerogKña.
esckþIENnaMBIebtugeRbkugRtaMg 586
28. T.Chhay NPIC
krNITIBIrénkardak;bnÞúkekIteLIgenAeBlEdlFñwmrgkMlaMgeRbkugRtaMgeRkayBIekItmankMhat
bg;TaMgGs; nigrgnUvbnÞúkefr nigGefr. enAkñúglkçxNÐmanbnÞúkenH kugRtaMgenAsrésEpñkxagelIbM
put nigEpñkxageRkambMputénmuxkat;eRKaHfñak;dac;xatminRtUvFMCagkugRtaMgGnuBaØat f c nig f t sMrab;
kugRtaMgrgkarsgát; nigkugRtaMgrgkarTajrbs;ebtugerogKña.
lkçxNÐTaMgenHGacsresrCaTMrg;KNitviTüadUcxageRkam³
!> sMrab;lkçxNÐKμanbnÞúk ¬enAeBlepÞr¦
- enAsrésEpñkxagelIbMput
Fi (Fi e ) yt M D yt
α ti = − + − ≤ f ti (19.14)
A I I
- enAsrésEpñkxageRkambMput
Fi (Fi e ) yb M D yb
α bi = − − − ≥ − f ci (19.15)
A I I
@> sMrab;lkçxNÐmanbnÞúk ¬bnÞúkTaMgGs;RtUv)andak;eRkayBIkMhatbg;eRbkugRtaMg¦
- enAsrésEpñkxagelIbMput
- σ t = − F + (FeI)yt − M D yt − M IL yt ≥ − f c
A I
(19.16)
- enasrésEpñkxageRkambMput
- σ b = − F − (FeI)yb − M D yb − M LI yb ≤ f t
A I
(19.17)
Edl Fi nig F = kMlaMgeRbkugRtaMgenAeBlepÞr nigeRkayBIkMhatbg;
f ti nig f t = kugRtaMgrgkarTajenAkñúgebtugenAeBlepÞr nigeRkayBIkMhatbg;
f ci nig f c = kugRtaMgrgkarsgát;enAkúñgebtugenAeBlepÞr nigeRkayBIkMhatbg;
M D nig M L = m:Um:g;EdlbNþalBIbnÞúkefr nigbnÞúkGefr
yt nig yb = cMgayBIG½kSNWteTAsrésEpñkxagelIbMput nigEpñkxageRkambMput
enAkúñgkarviPaK eKsnμt;fasMPar³manlkçN³eGLasÞicenAkúñgEdneFVIkarénkugRtaMgEdlGnuvtþ.
x> EdnkMNt;sñÚl Kern Limits
RbsinebIeKGnuvtþkMlaMgeRbkugRtaMgenARtg;TIRbCMuTMgn;rbs;muxkat; vanwgekItmankugRtaMg
BRgayesμI. RbsinebIGnuvtþkMlaMgeRbkugRtaMgenARtg;cMNakp©it e BIeRkamTIRbCMuTMgn; EdleFVIy:agNa
eGaykugRtaMgenAsrésEpñkxagelIbMputesμIsUnü enaHeKcat;TukkMlaMgeRbkugRtaMgenHmanGMeBIRtg;cMnug
esckþIENnaMBIebtugeRbkugRtaMg 587
29. T.Chhay NPIC
lower kern ¬rUbTI 19>5¦. enAkñúgkrNIenH e RtUv)ansMKal;eday K b ehIIykarBRgaykugRtaMgman
ragRtIekaN EdlmankugRtaMgsgát;GtibrmaenasréseRkameKbMput. kugRtaMgenAsrésxagelIbMputKW
Fi (Fi e ) yt
σt = − + =0
A I
I
e = K b = lower kern = (19.17)
Ayt
dUcKña RbsinebIeKGnuvtþkMlaMgeRbkugRtaMgenARtg;cMNap©it e' BIelITIRbCMuTMng; EdleFVIy:agNaeGaykug
RtaMgenAsrésEpñkxageRkambMputesμIsUnü enaHkMlaMgeRbkugRtaMgRtUv)aneKcat;TukfamanGMeBIRtg;cMnuc
upper lower ¬rUbTI 19>5¦. enAkñúgkrNIenHcMNap©it e' RtUv)ansMKal;eday K t ehIykarBRgaykug
RtaMgmanragRtIekaN EdlmankugRtaMgsgát;GtibrimaenAsrésEpñkxagelIbMput. kugRtaMgenAsrés
EpñkxageRkambMputKW
Fi (Fi e ) yb
σb = − + =0
A I
I
e' = K t = upper kern = (19.18)
Ayb
Kern limits énmuxkat;RtIekaNRtUv)anbgðajenArUbTI 19>5.
esckþIENnaMBIebtugeRbkugRtaMg 588
30. T.Chhay NPIC
K> karkMNt;tMéléncMNakp©it Limiting Values of Eccentricity
eKGacsresrsmIkarkugRtaMgTaMgbYn ¬BIsmIkar 19.13 dl; 19.16¦CaGnuKmn_éncMNakp©it e
sMrab;lkçxNÐénkardak;bnÞúkepSg². Ca]TahrN_ eKGacsresrsmIkar 19.13 dUcxageRkam
Fi (Fi e ) yt M D yt
σ ti = − + − ≤ f ti
A I I
(Fi e ) yt ≤ f + Fi + M D yt
ti
I A I
I ⎛ Fi M D yt ⎞
e≤ ⎜ + + f ti ⎟ (19.19)
Fi yt ⎝ A I ⎠
RbsinebIeKeRbI lower kern limit K b = I / Ayt / enaH
M D f ti AK b
e ≤ Kb + + (19.20)
Fi Fi
tMél e CacMNakp©itGtibrmaEdlQrelIsrésEpñkxagelIbMputsMrab;lkçxNÐKμanbnÞúk.
dUcKña BIsmIkar 19.14
I ⎛ Fi M D yb ⎞
e≤ ⎜− + + f ci ⎟ (19.21)
Fi yb ⎝ A I ⎠
M f AK
e ≤ − K t + D + ci t (19.22)
Fi Fi
tMél e CacMNakp©itGtibrmaEdlQrelIsrésEpñkxageRkambMputsMrab;lkçxNÐKμanbnÞúk. eKKNna
tMélGtibrma e BIsmIkarelITaMgBIredayyktMélEdltUcCagmkeRbI.
BIsmIkar 19.15
I ⎛ F M T yt ⎞
e≥ ⎜ + − fc ⎟ (19.23)
Fyt ⎝ A I ⎠
M f AK b
e ≥ Kb + T − c (19.24)
F F
Edl M T = m:Um:g;EdlbNþalBIbnÞúkefr nigbnÞúkGefr = (M D + M L ) . tMélenHCacMNakp©itGb,-
brma EdlQrelIsrésEpñkxagelIbMputsMrab;lkçxNÐRTbnÞúk. BIsmIkar 19.16
I ⎛ F M T yb ⎞
e≥ ⎜− + − ft ⎟ (19.25)
Fyb ⎝ A I ⎠
M f AK t
e ≥ Kt + T − t (19.26)
F F
esckþIENnaMBIebtugeRbkugRtaMg 589
31. T.Chhay NPIC
tMélenHCacMNakp©itGb,brmaEdlQrelIsrésEpñkxageRkambMput sMrab;lkçxNÐmanbnÞúk. eKKYr
KNnatMélGb,brma e TaMgBIrenHBIsmIkarTaMgBIrxagelI ehIyeKykcMNakp©itGb,brmaNaEdl
mantMélFMCageKmkeRbI.
X> tMélkMNt;émkMlaMgeRbkugRtaMgenAeBlepÞr
Limiting Values of the Prestessing Force at Transfer
edayKitfa F = ηFi Edl η CapleFobén net prestressing force eRkayBIkMhatbg; nig
sMrab;krNIepSg²énkardak;bnÞúk eKGacsresrsmIkar 19.20, 19.22, 19.24 nig 19.26 eLIgvijdUc
xageRkam³
(e − K b )Fi ≤ M D + f ti AK b (19.27)
(e + K t )Fi ≤ M D + f ci AK t (19.28)
(e − K b )Fi ≥ M D + M L − 1 ( f c AK b ) (19.29)
η η η
(e + K t )Fi ≥ M D +
ML
−
1
( f t AK t ) (19.30)
η η η
CMnYsmIkar 19.27 eTAkñúgsmIkar 19.30 eKTTYl)an
⎛1 ⎞ M f AK t
Fi (K b + K t ) ≥ M D ⎜ − 1⎟ + L − t
⎜η ⎟ η − f ti AK t
⎝ ⎠ η
⎡⎛ 1 ⎞ M L ⎛ f t AK t ⎞ ⎤
b¤ Fi ≥
1
⎢⎜ − 1⎟ M D +
⎜η ⎟
(K b + K t ) ⎣⎝ η ⎝
−⎜⎜ η ⎟ − ( f ti AK b )⎥
⎟ (19.31)
⎠ ⎠ ⎦
tMél Fi CatMélGb,brmaénkMlaMgeRbkugRtaMgenAeBlepÞredaymineGayFMCagkugRtaMgGnuBaØateRkam
lkçxNÐmanbnÞúk nigKμanbnÞúk. CMnYssmIkar 19.29 eTAkñúgsmIkar 19.28 edIm,ITTYl)an
⎡⎛ 1 ⎞ M L ⎛ f c AK b ⎞ ⎤
⎜ η ⎟ + ( f ci AK t )⎥
1
Fi ≤ ⎢⎜1 − ⎟ M D −
⎜ η⎟ +⎜ ⎟ (19.32)
(K b + K t ) ⎣⎝ ⎠ η ⎝ ⎠ ⎦
tMél Fi CatMélGtibrmaénkMlaMgeRbkugRtaMgenAeBlepÞredaymineGayelIskugRtaMgGnuBaØateRkam
lkçxNÐmanbnÞúk nigKμanbnÞúk. edayCMnYssmIkar 19.31 eTAkñúgsmIkar 19.32
⎛ 1⎞ 2M L ⎛ f ⎞ ⎛ f ⎞
⎜1 − ⎟ 2 M D −
⎜ η⎟ + ⎜ fti + c ⎟ AKb + ⎜ f ci + t ⎟ AKt ≥ 0
⎜ ⎟ ⎜ (19.33)
⎝ ⎠ η ⎝ η ⎠ ⎝ η⎟ ⎠
smIkarenHbgðajfa Fi max − Fi min ≥ 0 . eKeRbIsmIkarenHsMrab;bgðajfamuxkat;NamYymanlkçN³
RKb;RKan;.
esckþIENnaMBIebtugeRbkugRtaMg 590
32. T.Chhay NPIC
]TahrN_ 19>4³ FñwmTMrsamBaØEdlrgeRbkugRtaMgmunEdlmanRbEvg 14.4m manmuxkat;dUcbgðajenA
kñúgrUbTI 19>6 a. FñwmenHRTnUvbnÞúkefr 13.15kN / m ¬edayminrYmbBa©ÚlTMgn;pÞal;¦ nigrgnUvbnÞúk
Gefr 16kN / m . edaysnμt;faEdkeRbkugRtaMgpSMeLIgeday tendon 20 Edl tendon mYymanGgát;
p©it 11.125mm CamYynwg Es = 2 ⋅105 MPa / Fo = 1200MPa nig ultimate strength
f pu = 1725MPa .
!> kMNt;TItaMgEdnkMNt;xagelI nigEdnkMNt;xageRkamrbs; tendon profile ¬TIRbCMuTMgn;rbs;
EdkeRbkugRtaMg¦ sMrab;muxkat;enAkNþalElVg nigsMrab;muxkat;bIepSgeTotenAcenøaHmux
kat;kNþalElVg nigcugFñwm.
esckþIENnaMBIebtugeRbkugRtaMg 591
33. T.Chhay NPIC
@> dak; tendon cMTItaMgedIm,IbMeBjEdnkMNt;TaMgenH edayeGay tendon xøHegIbeLIgcab;BI
cMnucmYyPaKbIénRbEvgElVg. RtYtBinitütMélkMNt;énkMlaMgeRbkugRtaMgenAeBlepÞr.
#> RtYtBinitüeLIgvijnUvkMhatbg; edayKit tendon profile Edl)aneRCIserIs nigbMErbMrYlcM
Nakp©it e .
eRbI fci ¬enAeBlepÞr¦ = 28MPa / f 'c = 35MPa / Ec = 27600MPa nig Eci = 24800MPa .
dMeNaHRsay³
!> kMNt;lkçN³rbs;muxkat;
RkLaépÞ = 600 × 150 + 450 × 150 + 300 × 250 = 23.25 ⋅104 mm2
esckþIENnaMBIebtugeRbkugRtaMg 592
34. T.Chhay NPIC
kMNt;TIRbCMuTMgn;rbs;muxkat;edayKitm:Um:g;eFob)atrbs;muxkat;
yb =
1
23.25 ⋅ 10 4
(75 ⋅103 ×125 + 90 ⋅103 × 550 + 67.5 ⋅103 × 925) = 522mm
yt = 1000 − 522 = 478mm
KNna gross moment of inertia I g
⎡ 450(150 )3 ⎤ ⎡150(600)3 ⎤
Ig = ⎢ + (450)(150)(403)2 ⎥ + ⎢ + (150)(600 )(28)2 ⎥
⎢
⎣ 12 ⎥ ⎢
⎦ ⎣ 12 ⎥
⎦
⎡ 300(250)3 ⎤
+⎢ + (300 )(250)(397 )2 ⎥
⎢
⎣ 12 ⎥
⎦
= 2.607 ⋅ 1010 mm 4
I 2.607 ⋅ 1010
Kb = = = 235.6mm
Ayt 23.25 ⋅ 10 4 × 478
I 2.607 ⋅ 1010
Kt = = = 214.8mm
Ayb 23.25 ⋅ 10 4 × 522
@> )a:n;RbmaNkMhatbg;eRbkugRtaMg eday Fo = 1200MPa
a. snμt; elastic loss esμI 4% b¤ 0.04 × 1200 = 48MPa
b. kMhatbg;edaysarkarrYmmaDKW 0.0003Es = 0.0003 × 2 ⋅ 105 = 60MPa
c. kMhat;bg;edaysar creep rbs;ebtug ³ kar)a:n;RbmaNdMbUgd¾l¥bMputénkMhatbg;eday
sar creep KW 1.67 dgén elastic loss
1.67 × 48 ≈ 80 MPa
d. kMhatbg;edaysar relaxation énEdkKW 4% ³ 0.04 ×1200 = 48MPa
kMhatbg;GaRs½ynwgeBlKW 60 + 80 + 48 = 188MPa
PaKrykMhatbg; = 1200 = 15.7%
188
e. kMhatbg;srubKW 188 + 48 = 236MPa
PaKryénkMhatbg;srubKW
236
= 19.7%
1200
f. kugRtaMgkMlaMgeRbkugRtaMg
Fi = 1200 − 48 = 1152MPa ¬enAeBlepÞr¦
F = 1200 − 236 = 964 MPa
esckþIENnaMBIebtugeRbkugRtaMg 593
35. T.Chhay NPIC
F = ηFi
η = 1− pleFobkMhatbg;GaRs½ynwgeBl
964
= = 0.837
1152
#> EdnkMNt;éncMNakp©it e Rtg;kNþalElVg³ kMNt;kugRtaMgGnuBaØat nigm:Um:g;. enAeBlepÞr
f 'ci = 28MPa / f ci = 0.6 × 28 = 16.8MPa nig f ti = 0.25 f 'ci = 1.32MPa . enAeBlrgbnÞúk
eFVIkar f 'c = 35MPa / fc = 0.45 f 'c = 15.75MPa nig ft = 0.5 f 'c = 2.96MPa .
bnÞúkpÞal;rbs;Fñwm = 23.25 ⋅10−2 × 25 = 5.81kN / m
5.81(14.4 )2
M D ¬bnÞúkpÞal;¦ = = 150.6kN .m
8
2
Ma ¬bnÞúkbEnßm nigbnÞúkGefr¦ = wa8L
=
(13.15 + 16)14.4 2 = 755.6kN.m
8
m:Um:g;srub (M T ) = M D + M L = 906.2kN .m
Fi = kugRtaMgenAeBlepÞr × RkLaépÞEdkeRbkugRtaMg
RkLaépÞrbs; tendon 20 Edl tendon nImYy²manGgát;p©it 11.125mm KW
20 × 69.7 = 1394mm 2
Fi = 1394 × 1152 ⋅ 10 −3 = 1606kN
F = 1394 × 964 ⋅ 10 −3 = 1344kN
a. BicarNamuxkat;enAkNþalElVg
srésxagelIbMput kñúglkçxNÐminrgbnÞúk
M D f ti AK b
e ≤ Kb + +
Fi Fi
≤ 235.6 + 10 +
( )
150.6 3 1.32 23.25 ⋅ 10 4 (235.6) − 3
10 ≤ 374.4mm
1606 1606
srésxageRkambMput kñúglkçxNÐKμanbnÞúk
M D f ci AK t
e ≤ −Kt + +
Fi Fi
≤ −214.8 + 10 +
( )
150.6 3 16.8 23.25 ⋅ 10 4 214.8 − 3
10 ≤ 401.4mm
1606 1606
yktMél e EdltUcCageKkñúgcMeNamlT§plTaMgBIrxagelICatMélGtibrma.
esckþIENnaMBIebtugeRbkugRtaMg 594
36. T.Chhay NPIC
dUcenH tMélGtibrmarbs; e = 374mm
srésxagelIbMput kñúglkçxNÐrgbnÞúk
M T f c AK b
e ≥ Kb + −
F F
≥ 235.6 + 10 −
( )
906.2 3 15.75 23.25 ⋅ 10 4 235.6 − 3
10 ≥ 268mm
1344 1344
srésxageRkambMput kñúglkçxNÐmanbnÞúk
M T f t AK t
e ≥ −Kt + −
F F
≥ −214.8 + 10 −
( )
906.2 3 2.96 23.25 ⋅ 10 4 214.8 − 3
10 ≥ 349.5mm
1344 1344
tMélGb,brmarbs; e CatMéltUcCageKkñúgcMeNamlT§plTaMgBIrxagelI.
dUcenH tMélGb,brmarbs; e = 350mm
b. BicarNamuxkat;EdlenAcMgay 2.4m BIkNþalElVg ¬muxkat;elx @ kñúgrUbTI 19>6 a¦³
w
M D ¬bnÞúkpÞal;¦ = R A (4.8) − D (4.8)2
2
= (5.81)(7.2)(4.8) − (4.8)2 = 133.9kN.m
5.81
2
M a = (29.15)(7.2)(4.8) − (4.8)2 = 671.6kN .m
29.15
2
M T = 133.9 + 671.6 = 805.5kN .m
srésxagelIbMput sMrab;lkçxNÐminrgbnÞúk³
133.9 3 1.32(23.25 ⋅ 10 4 )(235.6) − 3
e ≤ 235.6 + 10 + 10 ≤ 364mm
1606 1606
srésxageRkambMput sMrab;lkçxNÐminrgbnÞúk
133.9 3 16.8(23.25 ⋅ 10 4 )214.8 − 3
e ≤ −214.8 + 10 + 10 ≤ 391mm
1606 1606
tMélGtibrmarbs; e = 364mm
srésxagelIbMput sMrab;lkçxNÐRTbnÞúk
805.5 3 15.75(23.25 ⋅ 10 4 )235.6 − 3
e ≥ 235.6 + 10 − 10 ≥ 193mm
1344 1344
sésrxageRkambMput sMrab;lkçxNÐRTbnÞúk
805.5 3 2.96(23.25 ⋅ 10 4 )214.8 − 3
e ≥ −214.8 + 10 − 10 ≥ 274.5mm
1344 1344
esckþIENnaMBIebtugeRbkugRtaMg 595
37. T.Chhay NPIC
tMélGb,brmarbs; e = 274.5mm
c. BicarNamuxkat;Rtg;cMgay 4.8m BIkNþalElVg ¬muxkat;elx # kñúgrUbTI 19>6 a¦³
M D ¬bnÞúkpÞal;¦ = 83.7 kN .m
M a = 419.8kN .m
M T = 503.5kN .m
- srésxagelIbMput sMrab;lkçxNÐKμanbnÞúk e ≤ 333mm ¬Gtibrma¦
- srésxageRkambMput sMrab;lkçxNÐKμanbnÞúk e ≤ 360mm
- srésxagelIbMput sMrab;lkçxNÐrgbnÞúk e ≥ −32mm
- srésxageRkambMput sMrab;lkçxNÐrgbnÞúk e ≥ 50mm ¬Gb,brma¦
d. BicarNamuxkat;Rtg;cMgay 0.9m BIcugFñwm ¬RbEvg anchorage¦³
M D ¬bnÞúkpÞal;¦ = 35.3kN .m / M a = 177.1kN .m nig M T = 212.4kN .m
- srésxagelIbMput sMrab;lkçxNÐKμanbnÞúk e ≤ 303mm ¬Gtibrma¦
- srésxageRkambMput sMrab;lkçxNÐKμanbnÞúk e ≤ 330mm
- srésxagelIbMput sMrab;lkçxNÐrgbnÞúk e ≥ −248mm
- srésxageRkambMput sMrab;lkçxNÐrgbnÞúk e ≥ −167mm ¬Gb,brma¦
$> Tendon profile RtUv)anbgðajenAkñúgrUbTI 19>6 b. cMNakp©itEdl)aneRCIserIsenAkNþalElVgKW
e = 364mm EdlvaRKb;RKan;sMrab;muxkat; B enAcMgay 2.4m BIkNþalElVg. TIRbCMuTMgn;énEdk
eRbkugRtaMgmanlkçN³edkcenøaH A nig B nigbnÞb;mkeTreLIgEdlmanlkçN³CabnÞat;cenøaHBI B
eTA E . cMNakp©itenARtg;muxkat; C nig D RtUv)anKNnaedayeRbIbnÞat;eRTt BE EdlmanCMerl
364 / 4.8 = 75.83mm / m . cMNakp©itRtg; C KW 182mm nigRtg; D KW 68mm . Tendon profile
Edl)aneRCIserIsbMeBjlkçxNÐEdnkMNt;xagelI nigEdnkMNt;xageRkamrbs;cMNakp©itenARKb;
muxkat;TaMgGs;.
karelIk tendon eLIgRtUv)aneFVIdUcxageRkam³
a. dak; tendon TaMg 20 ¬Ggát;p©it 11.125mm ¦
enAmYyPaKbIénkNþalElVgrbs;FñwmedaymanKMlat 50mm BIKñadUcbgðajenAkñúgrUbTI 19>6 a.
edIm,IKNnacMNakp©itCak;EsþgenARtg;muxkat;kNþalElVg Kitm:Um:g;sMrab; tendon eFobnwg)at
rbs;muxkat;³
esckþIENnaMBIebtugeRbkugRtaMg 596
38. T.Chhay NPIC
cMgayBI)at = 20 (16 × 125 + 4 × 275) = 155mm
1
e ¬kNþalElVg¦ = yb − 155 = 522 − 155 = 367 mm
EdlvaEk,rnwg 364mm Edl)ansnμt;. RbsinebIebIeKdak; tendon BIrenAcMgay 75mm BI
tendon EdlenAxageRkam enaHcMgayBI)atkøayeTACa
1
(16 × 125 + 2 × 250 + 2 × 325) = 158mm
20
enaHcMNakp©itnwgkøayeTACa 522 − 158 = 364mm EdlesμIweTAnwgcMNakp©itEdl)ansnμt;. Ca
karGnuvtþ eKdak; tendon TaMgGs;edaymanKMlatBIKña 50mm .
b. elIkEt tendon EdlenAkNþalcMnYn 12 eGayegIbeLIg. karBRgay tendon enAmuxkat;xag
cugRtUv)anbgðajenAkñúgrUbTI 19>6 a. RtYtBinitücMNakp©itrbs; tendon edayKitm:Um:g;eFobTI
RbCMuTMgn;rbs;muxkat;ebtugsMrab; tendon 12 enAxagelI nig tendon 8 eTotEdlRtUv)andak;
enAxageRkam³
e=
1
(8 × 364 − 12 × 226) = 10mm
20
tMél e enHtUc nigRKb;RKan;. cMNakp©itCak;EsþgenAcMgay 0.9m BImuxkat;xagcug
e=
0.9
(364 − 10) + 10 = 76mm
4.8
cMNakp©itCak;EsþgenAcMgay 2.4m BImuxkat;xagcugKW
e=
1
(364 − 10) + 10 = 187mm
2
%> tMélkMNt;rbs; Fi ³ tMélrbs; Fi EdleRbIsMrab;karKNnaBIxagelIKW Fi = 1606kN .
RtYtBinitü Fi Gb,brmaedayeRbIsmIkar 19.31:
⎡⎛ 1 ⎞ M L ( f t AK t ) ⎤
− ( f ti AK b )⎥
1
Fi min = ⎢⎜ − 1⎟ M D +
⎜η ⎟ −
(K b + K t ) ⎣⎝ ⎠ η η ⎦
10 −3
⎡⎛ 1
⎢⎜
⎞
− 1⎟150.6 ⋅ 106 + −
( )
755.6 ⋅ 106 2.96 × 23.25 ⋅ 10 4 214.8 ⎤
⎥
= ⎢⎝ 0.837 ⎠ 0.837 0.837 ⎥
(235.6 + 214.8) ⎢
(
⎣− 1.32 × 23.25 ⋅ 10 × 235.6
4
) ⎥
⎦
= 1516.8kN
vamantMéltUcCag Fi EdleRbI. RtYtBinitü Fi GtibrmaedayeRbIsmIkar 19.32:
1 ⎡⎛ 1 ⎞ M L f c AK b ⎤
Fi max = ⎢⎜1 − ⎟ M D −
⎜ η⎟ + + f ci AK t ⎥
(K b + K t ) ⎣⎝ ⎠ η η ⎦
esckþIENnaMBIebtugeRbkugRtaMg 597
39. T.Chhay NPIC
10 −3
⎡⎛
⎢⎜1 −
1 ⎞ 6 755.6 ⋅ 10
⎟150.6 ⋅ 10 −
6
+
( )
15.75 23.25 ⋅ 10 4 235.6 ⎤
⎥
= ⎢⎝ 0.837 ⎠ 0.837 0.837 ⎥
(235.6 + 214.8) ⎢
(
⎣+ 16.8 23.25 ⋅ 10 214.8
4
) ⎥
⎦
= 2081.9kN
vamantMélFMCag Fi EdleRbI. dUcenHmuxkat;eRKaHfñak;enAkNþalElVgKWRKb;RKan;.
^> RtYtBinitükMhatbg;eRbkugRtaMg edayeyIgman Fo = 1200MPa nig Aps = 1394mm2
kMlaMg Fo srub = 1200 × 1394 × 10−3 = 1672.8kN
Ec = 27600MPa
E
n= s =
Ec
200000
27600
= 7.25 yk n = 7
MD enAkNþalElVg = 150.6kN .m
Fo + nAps f c (D.L.) ×
2
Fi = 3
⎛1 e 2⎞
(
1 + nAps )⎜ + ⎟
⎜A I ⎟
⎝ ⎠
tMélrbs; fc Edl)anBIkarBRgaybnÞúkefrRtUvKuNnwg 2 / 3 edIm,IbgðajBIbMErbMrYlrag)a:ra:bUl
rbs;kugRtaMgbnÞúkefrtambeNþayFñwm Edlpþl;eGaynUvtMélRbhak;RbEhlrbs; Fi )an
RbesIrCag.
a. kMNt;tMélmFümrbs; e2 EdlTTYlenAkñúgFñwm. ExSekagtMNageGay e2 RtUv)anbgðajenA
kñúgrUbTI 19>6 c³
⎡1 ⎤
1 ⎢ (5776 × 0.9) + (5776 × 3.9) + (126720 × 3.9)⎥
1
e 2
¬mFüm¦ =
7.2 ⎢
3 3
⎥
⎣+ (2.4 × 132496 ) ⎦
= 70414.7mm 2
e = 265mm
RkLaépÞrbs;)a:ra:bUlesμInwgRkLaépÞrbs;ctuekaNEkg.
b. kugRtaMgEdlbNþalBIbnÞúkefrenARtg;nIv:Urbs; tendon KW
150.6 × 265
f c (D.L.) = 10 6 = 1.53MPa
2.607 ⋅ 10 10
esckþIENnaMBIebtugeRbkugRtaMg 598
40. T.Chhay NPIC
1672.8 ⋅ 103 + 7(1394) × 1.53 ×
2
dUcenH Fi =
⎛
3
70414.7 ⎞
10 − 3 = 1575.1kN
1 + 7(1394 )⎜
1
+ ⎟
⎝ 23.25 ⋅ 10 4
2.607 ⋅ 1010 ⎠
elastic loss KW 1672.8 − 1575.1 = 97.7kN = 5.8% . tMélenHKWFMCag elastic loss Edl)an
snμt; 4% .
kñúgmYyÉktþaRkLaépÞEdk = 1394 103 = 70MPa
elastic loss
97.7
Fi kñúgmYyÉktþaRkLaépÞ =
1575.1 3
10 = 1130MPa
1394
c. kMhatbg;GaRs½ynwgeBl
kMhat;bg;edaysarkarrYmmaDebtug = 60MPa ¬dUcelIkmun¦
kMhatbg;edaysar creep
Fi 1575.1
elastic strain = = 103 = 2.45 ⋅ 10 − 4
Ac Ec ( )
23.25 ⋅ 10 27600
4
Δf s = Cc (ε cr Es )
yk Cc = 1.5 enaH
( )
Δf s = 1.5 2.45 ⋅ 10 −4 200000 = 73.5MPa
PaKrykMhatbg; =
73.5
1130
= 6.5%
kMhatbg;edaysar relaxation rbs;EdkKW 48MPa ¬dUcelIkmun¦. kMhatbg;GaRs½ynwgeBl
esμInwg 60 + 73.5 + 48 = 181.5MPa ehIyPaKrykMhatbg;KW 181.5 / 1130 = 16% Edlman
tMélEk,rnwgtMélEdl)ansnμt; 15.7% .
F = ηFi = (1 − 0.16)Fi = 0.84 Fi
η = 0.84
5> KNnaGgát;rgkarBt;begáag Design of Flexural Members
k> sBaØaNTUeTA General
EpñkBIedIm)anbBa¢ak;fakugRtaMgenAsrésxagelIbMput nigsrésxageRkambMputénmuxkat;eRKaH
fñak;rbs;Ggát;ebtugeRbkugRtaMgminRtUvFMCagkugRtaMgGnuBaØatsMrab;RKb;krNITaMgGs; b¤dMNak;kalén
esckþIENnaMBIebtugeRbkugRtaMg 599
41. T.Chhay NPIC
kardak;bnÞúk. bEnßmBIelIlkçxNÐTaMgenH eKRtUvKNnaGgát;ebtugeRbkugRtaMgCamYynwgemKuNsuvtßi-
PaBRKb;RKan;edIm,IRbqaMgnwgkar)ak;. ACI Code tMrUveGaym:Um:g;Edl)anBIbnÞúkemKuN M u minRtUvFM
CagersIusþg;rgkarBt; φM n énmuxkat;Edl)anKNna.
sMrab;krNI tension-controlled section, FñwmebtugeRbkugRtaMgcab;epþIm)ak;enAeBlEdlkug
RtaMgEdkFMCag yield strength rbs;EdkEdleRbIenAkñúgmuxkat;ebtug. EdkeRbkugRtaMgersIusþg;nwgmin
bgðajcMnuc yield c,as;las;dUcEdkFmμtaEdleRbIenAkñúgebtugGarem:eT. b:uEnþeRkamkarbEnßmbnÞúk
strain enAkñúgEdkekIneLIgedayGRtay:agelOn ehIykar)ak;ekIteLIgenAeBl compressice strain
Gtibrmarbs;ebtugmantMélesμInwg 0.003 ¬rUbTI 19>7¦.
EdnkMNt;sMrab;EdkBRgwgrbs;Ggát;rgkarBt;ebtugeRbkugRtaMgEdlGaRs½yeTAtam ACI Code,
Section 18.8 KWQrelI net tensile strain sMrab; tension-controlled, transition b¤ compression-
esckþIENnaMBIebtugeRbkugRtaMg 600
42. T.Chhay NPIC
edayeKarBtam ACI Code, Section 10.3 dUcEdl)anBnül;enAkñúgCMBUk 3. em
controlled section
KuNkat;bnßyersIusþg; φ RtUv)aneGayenAkñúgCMBUkTI 3 edayQrelI ACI Code, Section 9.3.
x> muxkat;ctuekaN Rectangular Sections
eKGackMNt; Nominal moment capacity rbs;muxkat;ctuekaNdUcxageRkam ¬eyagtamrUb
TI 19>7¦³
⎛ a⎞ ⎛ a⎞
M n = C⎜ d − ⎟ = T ⎜ d − ⎟ (19.34)
⎝ 2⎠ ⎝ 2⎠
Edl T = Aps f s nig C = 0.85 f 'c ab . sMrab; C = T
Aps f ps ρ p f ps
a= = d (19.35|
0.85 f 'c b 0.85 f 'c
EdlpleFobEdkeRbkugRtaMgKW ρ p = Aps / bd ehIy Aps nig f ps CaRkLaépÞ nigkugRtaMgTajrbs;
EdkeRbkugRtaMg. yk
⎛ f ps ⎞
ωp = ρp⎜
⎜ ⎟ ≤ 0.32 β1
⎟
⎝ f 'c ⎠
ωp
bnÞab;mk a=
0.85
d (19.36)
tMél ω p CakMlaMgenAkñúg tendon EdlRtUv)anvas;edaypÞal;. edIm,IFananUv tesion-controlled
behavior, ACI Code, Section 18.8.1 kMNt;fa ω p minRtUvFMCag 0.32β1 EdkRtUvKñanwg net tensile
strain ε t = 0.005 . cMNaMfa β1 = 0.85 sMrab; f 'c ≤ 28MPa nwgkat;bnßyeday 0.05 sMrab;ral;
7 MPa sMrab; 28MPa < f 'c < 56MPa ehIyesμInwg 0.65 sMrab; f 'c > 56MPa . eKk¾Gacsresr
⎛ a⎞
M n = Aps f ps ⎜ d − ⎟
⎝ 2⎠
⎛ ρ p f ps ⎞
⎜ 1 .7 f ' ⎟
M n = A ps f ps d ⎜1 − ⎟ (19.37)
⎝ c ⎠
⎛ ωp ⎞
⎜ 1 .7 ⎟
M n = A ps f ps d ⎜1 − ⎟ (19.38)
⎝ ⎠
nig M u = φM n
enAkúñgsmIkarBImun f ps CakugRtaMgenAkñúgEdkeRbkugRtaMgenAeBl)ak;. eKminGackMNt;tMél
Cak;Esþgrbs; f ps edaygayRsYleT. dUcenH ACI Code, Section 18.7.2 GnuBaØateGay)a:n;RbmaN
tMél f ps dUcxageRkam.
esckþIENnaMBIebtugeRbkugRtaMg 601
43. T.Chhay NPIC
sMrab; bonded tendons
⎡ γp ⎛ f ⎞⎤
f ps = f pu ⎢1 − ⎜ ρ p × pu ⎟⎥
⎜ (19.39)
⎢ β1
⎣ ⎝ f 'c ⎟ ⎥
⎠⎦
sMrab; unbonded tendon enAkñúgGgát;EdlmanpleFobElVgelIkMBs;tUcCag b¤esμI 35
⎛ f 'c ⎞
f ps = ⎜ f se + 69 + ⎟ ≤ f py (19.40)
⎜ 100 ρ p ⎟
⎝ ⎠
RbsinebI f se ≥ 0.5 f pu nigRbsinebI f ps sMrab; unbonded tendon minFMCag f py b¤ f se + 415MPa .
sMrab; unbonded tendon enAkñúgGgát;EdlmanpleFobElVgelIkMBs;FMCag 35
⎛ f 'c ⎞
f ps = ⎜ f se + 69 + ⎟ (19.41)
⎜ 300 ρ p ⎟
⎝ ⎠
b:uEnþminRtUvFMCag f py b¤ f se + 207MPa Edl
γ p = emKuNsMrab;RbePTrbs; tendon eRbkugRtaMg
= 0.55 sMrab; f py / f pu EdlmintUcCag 0.8
= 0.4 sMrab; f py / f pu EdlmintUcCag 0.85
= 0.28 sMrab; f py / f pu EdlmintUcCag 0.9
f pu = ersIusþg;TajEdlkMNt;rbs;EdkeRbkugRtaMg
f se = kugRtaMgRbsiT§PaBenAkñúgEdkeRbkugRtaMgeRkayeBlkMhatbg;TaMgGs;
f py = specified yield strength rbs;EdkeRbkugRtaMg
enAkñúgkrNIEdl ω p > 0.32β1 FñwmebtugeRbkugRtaMgCa compression-controlled section.
edIm,IFananUv ductile failure eKkMNt; ω p RtwmtMélGtibrma 0.32β1 . sMrab; ω = 0.32β1 nig
a = 0.377 β1d eyIgTTYl)an
⎛ 0.32 β1 ⎞
M n = Aps f ps d ⎜1 − ⎟
⎝ 1.7 ⎠
( )
= ρ p bd f ps d (1 − 0.188β1 )
= ω p f 'c (1 − 0.188β1 )bd 2
( )
= 0.32β1 − 0.06β12 f 'c bd 2 (19.42)
sMrab; f 'c = 35MPa / β = 0.8 . enaH
1
M n = 0.22 f 'c bd 2 = 1.09bd 2
dUcKña/ sMrab; /
f 'c = 28MPa M n = 0.915bd 2 nigsMrab; /
f 'c = 42 MPa M n = 1.238bd 2
esckþIENnaMBIebtugeRbkugRtaMg 602