«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

¡¶½¨Öþ¿ÆѧÓ빤³Ìѧ±¨¡·[ISSN:1673-2049/CN:61-1442/TU]

¾í:

40¾í

ÆÚÊý:

2023Äê02ÆÚ

Ò³Âë:

50-58

À¸Ä¿:

½¨Öþ½á¹¹

³ö°æÈÕÆÚ:

2023-03-30

ÎÄÕÂÐÅÏ¢/Info

Title:

Prediction procedures for long-term behavior of double-span steel-concrete continuous composite beams considering shrinkage and creep effects

ÎÄÕ±àºÅ:

1673-2049(2023)02-0050-09

×÷Õß:

ÍõÇìºØ^1,2,ÍõÊËÆæ¹,¹È ·²¹,ÓȹãµÏ¹,´÷Èïºê¹

(1. ÉòÑô½¨Öþ´óѧ ÍÁľ¹¤³ÌѧԺ,ÁÉÄþ ÉòÑô 110168; 2. ¹þ¶û±õ¹¤Òµ´óѧ ½á¹¹¹¤³ÌÔÖ±äÓë¿ØÖƽÌÓý²¿ÖصãʵÑéÊÒ,ºÚÁú½­ ¹þ¶û±õ 150090)

Author(s):

WANG Qinghe^1,2, WANG Shiqi¹, GU Fan¹, YOU Guangdi¹, DAI Ruihong¹

(1. School of Civil Engineering, Shenyang Jianzhu University, Shenyang 110168, Liaoning, China; 2. Key Lab of Structures Dynamic Behaviour and Control of the Ministry of Education, Harbin Institute of Technology, Harbin 150090, Heilongjiang, China)

¹Ø¼ü´Ê:

¸Ö-»ìÄýÍÁ×éºÏÁº;  ³¤ÆÚÐÔÄÜ;  Ô¤²â·½·¨;  ÊÕËõ;  Ðì±ä

Keywords:

steel-concrete composite beam;  long-term behavior;  prediction procedure;  shrinkage;  creep

·ÖÀàºÅ:

TU398.9

DOI:

10.19815/j.jace.2021.10033

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

ΪÁ¿»¯»ìÄýÍÁÒí°åÊÕËõÐì±ä¶Ô¶à¿ç¸Ö-»ìÄýÍÁÁ¬Ðø×éºÏÁº³¤ÆÚÐÔÄܵÄÓ°Ïì,Ìá³öÏàÓ¦µÄÔ¤²â·½·¨,»ùÓÚÏÖÓÐÁ½¿çÁ¬Ðø×éºÏÁº³¤ÆÚÊÔÑé½á¹û¶ÔµäÐ͵Ä×éºÏÁºÉè¼Æ·½·¨½øÐÐÊÊÓÃÐÔÆÀÊö; ÔÚ´Ë»ù´¡ÉÏ,»ùÓÚÁäÆÚµ÷ÕûµÄÓÐЧģÁ¿·¨²¢¿¼ÂÇ»ìÄýÍÁµÄÊÕËõÐì±ä¡¢¿ªÁѼ°×éºÏÁº½çÃæÏà¶Ô»¬ÒƵÄ×ÛºÏÓ°Ïì,Ìá³öÁ½¿çÁ¬Ðø×éºÏÁº³¤ÆÚÖÐÖ§×ùÍä¾ØÓë¿çÖÐÄӶȵļÆË㹫ʽ,²¢²ÉÓó¤ÆÚÊÔÑé½á¹ûÑéÖ¤Ô¤²â·½·¨µÄ¿É¿¿ÐÔ; ½øÒ»²½¶Ô±È²»Í¬»ìÄýÍÁÒí°åÀàÐÍ(ÊÕËõÐì±ä·Ö²¼Ä£ÐÍ)¶Ô×éºÏÁº³¤ÆÚÐÔÄܵÄÓ°Ïì¡£½á¹û±íÃ÷:²ÉÓÃÁäÆÚµ÷ÕûµÄÓÐЧģÁ¿·¨Ä£Äâ»ìÄýÍÁÐì±äÌØÕ÷,¿¼ÂÇÊÕËõ²úÉúµÄ¸½¼ÓÍä¾Ø,²ÉÓÃÕÛ¼õ¸Õ¶È¿¼ÂÇ»ìÄýÍÁ¿ªÁÑÓë½çÃ滬ÒƵÄÓ°Ïì,Ìá³öµÄÁ½¿çÁ¬Ðø×éºÏÁº³¤ÆÚÐÔÄܼÆË㹫ʽ,¿ÉÓÐЧԤ²â×éºÏÁº³¤ÆÚÖÐÖ§×ùÍä¾Ø·Ö²¼Óë¿çÖÐÄÓ¶È,¼ÆËã½á¹ûÓëÊÔÑé½á¹û×î´óÏà²î25.3%; »ìÄýÍÁµÄÊÕËõ±äÐζÔ×éºÏÁº³¤ÆÚÐÔÄÜÓ°ÏìÏÔÖø,µ±²»¿¼ÂÇ»ìÄýÍÁÊÕËõ±äÐÎʱ,×éºÏÁºÖÐÖ§×ùÍä¾ØÓë¿çÖÐÄӶȽö·Ö±ðΪÊÔÑéÖµµÄ41.1%ºÍ60.6%; ×éºÏÁº³¤ÆÚÐÔÄÜÉè¼Æʱ,Ó¦¸ù¾ÝÂ¥°åÀàÐͲÉÓò»Í¬µÄÊÕËõÐì±äÄ£ÐÍ,Õë¶Ô¸Ö½î»ìÄýÍÁÂ¥°å²ÉÓþùÔÈÊÕËõ¡¢¾ùÔÈÐì±äÄ£ÐÍ,Õë¶Ô×éºÏÂ¥°å²ÉÓ÷ǾùÔÈÊÕËõ¡¢·Ç¾ùÔÈÐì±äÄ£ÐÍ¡£

Abstract:

To investigate the influence of concrete shrinkage and creep on the long-term behavior of multi-span steel-concrete continuous composite beams and propose the corresponding prediction procedures, the applicability of typical composite beam design procedures was evaluated based on the existing long-term test results of two-span continuous composite beams. On this basis, considering the comprehensive effects of concrete shrinkage and creep based on the age-adjusted effective modulus(AEMM)method, cracking and relative slip at the interface of composite beams, formulas for calculating the mid-span support bending moment and deflection of two-span continuous composite beams were proposed. The reliability of the prediction procedure was verified by the long-term test results. Furthermore, the effects of different concrete flange slab types(shrinkage and creep distribution models)on the long-term behavior of composite beams were compared. The results show that the proposed long-term behavior calculation formula for two-span continuous composite beams can effectively predict the mid-span support bending moment distribution and deflection of composite beams with the maximum error between the calculated and measured results of 25.3%, which considers the features of concrete creep by AEMM method, the additional bending moment caused by shrinkage, and the effects of concrete cracking and interface slip by reduction stiffness. The shrinkage deformation of concrete has a significant impact on the long-term behavior of composite beams. When the shrinkage deformation of concrete is not considered, the mid-span support bending moment and deflection of composite beams are only 41.1% and 60.6% of the test values, respectively. Different shrinkage and creep models should be used according to the type of floor slab when designing the long-term behavior of composite beams. The uniform shrinkage and creep models should be used for reinforced concrete floor slabs, and the non-uniform shrinkage and creep models should be used for composite floor slabs.

²Î¿¼ÎÄÏ×/References:

[1] Îé ¿­,Ðì ³¬,²ÜƽÖÜ,µÈ.Ð͸Ö-¸ÖÏËά»ìÄýÍÁ×éºÏÁº¿¹ÍäÐÔÄÜÊÔÑéÑо¿[J].ÍÁľ¹¤³Ìѧ±¨,2019,52(9):41-52.
WU Kai,XU Chao,CAO Pingzhou,et al.Experimental study on the flexural behavior of profile steel-steel fiber reinforced concrete composite beams[J].China Civil Engineering Journal,2019,52(9):41-52.
[2]Äô½¨¹ú,ÕÔ ½à.¸Ö°å-»ìÄýÍÁ×éºÏÁº¼°×éºÏ¿¹Íä¼Ó¹ÌÖÐ˨¶¤µÄÐÔÄܼ°¿¹¼ô³ÐÔØÁ¦Ñо¿[J].½¨Öþ½á¹¹,2010,40(6):39-43.
NIE Jianguo,ZHAO Jie.Shear resistance of stud shear connectors in steel plate-concrete composite beams and RC beams flexurally strengthened using steel plate-concrete composite technique[J].Building Structure,2010,40(6):39-43.
[3]Eurocode 2:design of concrete structures:EN 1992-1-1[S].Brussels:European Committee for Standardization,2004.
[4]Concrete steel-concrete construction in buildings:AS/NZS 2327:2017[S].Sydney:Standards New Zealand,2017.
[5]»ìÄýÍÁ½á¹¹Éè¼Æ¹æ·¶:GB 50010¡ª2010[S].±±¾©:Öйú½¨Öþ¹¤Òµ³ö°æÉç,2011.
Code for design of concrete structures:GB 50010¡ª2010[S].Beijing:China Architecture & Building Press,2011.
[6]¸Ö½á¹¹Éè¼Æ±ê×¼:GB 50017¡ª2017[S].±±¾©:Öйú½¨Öþ¹¤Òµ³ö°æÉç,2017.
Standard for design of steel structure:GB 50017¡ª2017[S].Beijing:China Architecture & Building Press,2017.
[7]Eurocode 4:design of composite steel and concrete structures:EN 1994-1-1[S].Brussels:European Committee for Standardization,2000.
[8]WANG Y Y,WANG Q H,GENG Y,et al.Long-term behaviour of simply supported composite slabs with recycled coarse aggregate[J].Magazine of Concrete Research,2016,68(24):1278-1293.
[9]WANG Q H,RANZI G,WANG Y Y,et al.Long-term behaviour of simply-supported steel-bars truss slabs with recycled coarse aggregate[J].Construction and Building Materials,2016,116:335-346.
[10]ÍõÇìºØ,ÁºÓÀÔó,ÕÅ »¶,µÈ.¿¼ÂǺÉÔØ·Ö²¼µÄ¶à¿çÁ¬Ðø¸Ö-ÔÙÉú»ìÄýÍÁ×éºÏ°å³¤ÆÚÐÔÄÜÑо¿[J].¹¤³ÌÁ¦Ñ§,2021,38(2):198-210.
WANG Qinghe,LIANG Yongze,ZHANG Huan,et al.Time-dependent behavior of multi-span continuous steel-RAC composite slabs considering the loading distribution effects[J].Engineering Mechanics,2021,38(2):198-210.
[11]GILBERT R I,BRADFORD M A,GHOLAMHOSEINI A,et al.Effects of shrinkage on the long-term stresses and deformations of composite concrete slabs[J].Engineering Structures,2012,40:9-19.
[12]RANZI G,AL-DEEN S,AMBROGI L,et al.Long-term behaviour of simply-supported post-tensioned composite slabs[J].Journal of Constructional Steel Research,2013,88:172-180.
[13]RANZI G,LEONI G,ZANDONINI R.State of the art on the time-dependent behaviour of composite steel-concrete structures[J].Journal of Constructional Steel Research,2013,80:252-263.
[14]AL-DEEN S,RANZI G,UY B.Non-uniform shrinkage in simply-supported composite steel-concrete slabs[J].Steel and Composite Structures,2015,18(2):375-394.
[15]Ñî½ðʤ.¸Ö-ÔÙÉú»ìÄýÍÁ×éºÏÁº³¤ÆÚÐÔÄÜÁÓ»¯»úÀíÓëÉè¼Æ·½·¨Ñо¿[D].ÉòÑô:ÉòÑô½¨Öþ´óѧ,2021.
YANG Jinsheng.Deterioration mechanism and design procedures of long-term behavior of steel-RAC composite beams[D].Shenyang:Shenyang Jianzhu University,2021.
[16]¼½ ΰ,Ëï ±ó,°× Ù»,µÈ.³¤ÆÚºÉÔØ×÷ÓÃϸÖ-»ìÄýÍÁ×éºÏÁºµÄÄӶȼÆËãÓë·ÖÎö[J/OL].ºþÄÏ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ):1-10.https://doi.org/ 10.16339/ j.cnki.hdxbzkb.2021.07.007.
JI Wei,SUN Bin,BAI Qian,et al.Calculation and analysis of long-term deflection for steel-concrete composite girder[J/OL].Journal of Hunan University(Natural Sciences):1-10.https:// doi.org/10.16339/j.cnki.hdxbzkb.2021.07.007.
[17]GILBERT R I,BRADFORD M A.Time-dependent behavior of continuous composite beams at service loads[J].Journal of Structural Engineering,1995,121(2):319-327.
[18]AL-DEEN S,RANZI G,VRCELJ Z.Long-term experiments of composite steel-concrete beams[J].Procedia Engineering,2011,14:2807-2814.
[19]ÍõÇìºØ,¶­¹úÃ÷,¹È ·²,µÈ.·Ç¾ùÔÈÊÕËõ±äÐζÔÁ½¿çÁ¬Ðø¸Ö-»ìÄýÍÁ×éºÏ°å³¤ÆÚÐÔÄܵÄÓ°ÏìÑо¿[J].½¨Öþ½á¹¹Ñ§±¨,2020,41(Ôö1):179-187.
WANG Qinghe,DONG Guoming,GU Fan,et al.Influence of non-uniform shrinkage on long-term behavior of double-span composite steel-concrete slabs[J].Journal of Building Structures,2020,41(S1):179-187.
[20]WANG Q H,YANG J S,LIANG Y Z,et al.Prediction of time-dependent behaviour of steel-recycled aggregate concrete(RAC)composite slabs via thermo-mechanical finite element modelling[J].Journal of Building Engineering,2020,29:101191.
[21]CHIEN E Y L,RITCHIE J K.Composite floor systems-a mature design option[J].Journal of Constructional Steel Research,1993,25(1/2):107-139.

ÏàËÆÎÄÏ×/References:

[1]ÖÜÓ³¬,Àî³£ÀÖ,ËïÌú¾ü,µÈ.¸Ö-»ìÄýÍÁ×éºÏÁº½çÃ滬ÒÆÓë¼ôÁ¦ÖÍñîºÏЧӦ·ÖÎö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2013,30(02):114.
¡¡ZHOU Yong-chao,LI Chang-le,SUN Tie-jun,et al.[J].Journal of Architecture and Civil Engineering,2013,30(02):114.
[2]ʯÆôÓ¡,ÁõÑó,ÀȺ,µÈ.¸Ö-»ìÄýÍÁ×éºÏÁº´¿Å¤¼°¸´ºÏÊÜŤÐÔÄÜ[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2009,26(01):94.
¡¡SHI Qi-yin,LIU Yang,LI Ai-qun,et al.Pure Torsion and Combined Torsion Behaviors of Steel-concrete Composite Beams[J].Journal of Architecture and Civil Engineering,2009,26(02):94.
[3]ʯÆôÓ¡,½Ãù,ÀȺ,µÈ.¸Ö-»ìÄýÍÁ×éºÏÁºÓë¸Ö¹Ü»ìÄýÍÁÖù½ÚµãµÄ·ÇÏßÐÔÓÐÏÞÔª·ÖÎö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2009,26(04):73.
¡¡SHI Qi-yin,LU Ming,LI Ai-qun,et al.Nonlinear Finite Element Analysis of Steel-concrete Composite Beam to Concrete-filled Steel Tubular Column Joints[J].Journal of Architecture and Civil Engineering,2009,26(02):73.
[4]Ñîè´,ÍõÔªÇå,ʯÓÀ¾Ã,µÈ.Öйú¡¢Å·ÖÞ¸Öª²»ìÄýÍÁ×éºÏÁºµÄÉè¼Æ¹æ·¶±È½Ï[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2006,23(04):34.
¡¡YANG Lu,WANG Yuan-qing,SHI Yong-jiu,et al.Design Code Comparison of Steel-Concrete Composite Beam of China and Europe[J].Journal of Architecture and Civil Engineering,2006,23(02):34.

±¸×¢/Memo

±¸×¢/Memo:

ÊÕ¸åÈÕÆÚ:2021-10-12
»ù½ðÏîÄ¿:¹ú¼Ò×ÔÈ»¿Æѧ»ù½ðÏîÄ¿(51808351); ÁÉÄþÊ¡²©Ê¿¿ÆÑÐÆô¶¯ÏîÄ¿(2019-BS-193); ÁÉÄþÊ¡½ÌÓýÌüÃæÉÏÏîÄ¿(lnjc202007,lnqn202024);
ÉòÑôÊÐÇàÄê¿Æ¼¼È˲ÅÏîÄ¿(RC200143); ס·¿ºÍ³ÇÏ罨É貿¿Æѧ¼¼Êõ¼Æ»®ÏîÄ¿(2019-K-054)
×÷Õß¼ò½é:ÍõÇìºØ(1987-),ÄÐ,¹¤Ñ§²©Ê¿,¸±½ÌÊÚ,˶ʿÉúµ¼Ê¦,E-mail:wangqinghe@sjzu.edu.cn¡£

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2023-03-20