A precast bottom slab with additional stiffener of composite slab connected without gaps: Design approach and experimental investigation

Abstract

Concrete composite slabs are extensively employed in assembled structures, due to their combined benefits from both assembled and cast-in-place slabs. Addressing concerns regarding the cumbersome fabrication, inconvenient transportation, and high cost associated with current composite slabs, this study proposes a new approach: integrating additional steel-tube-truss stiffeners (ASTTSs) into the precast bottom slab of composite slabs. Stiffeners are positioned beneath the bottom slab to enhance its stiffness during transportation and construction. This not only enhances the crack resistance of the slab, but also minimizes the need for bracing during construction. A design method for the precast bottom slab with ASTTSs is developed, and three bottom slabs with their corresponding stiffeners are designed, customized for different spans. Test results demonstrate that the precast bottom slab with additional stiffeners meets the construction stage requirements. The subsequent analysis of the test results not only validates the feasibility of the design method proposed in this study, but also elucidates the relationship between the additional stiffener and the equivalent stiffness of the specimen. The findings of this study offer a reference for enhancing the industrialization of composite slabs.

Keywords

assembled structure concrete composite slabs additional stiffener steel tube truss mechanical performance

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References

CECS 722-2020 (2020) Technical Specification for Prestressed Concrete Composite Slab with Grouted Steel Pipe Lattice Girders. China Architecture & Building Press, (in Chinese).

Ding

Zhang

(2012) Study on composite slab structure. Applied Mechanics and Materials 214: 311–314.

Feng

Chen

Tian

, (2024) Summary of classification and research on concrete composite slab. Building Structure 54(01): 138–144, (in Chinese).

GB 50009-2012 (2012) Load Code for the Design of Building Structures. China Architecture & Building Press, (in Chinese).

GB 50010-2010 (2015) Code for Design of Concrete Structures. China Architecture & Building Press, (in Chinese).

GB/T 228-2010 (2010) Metallic materials-tensile Testing at Ambient Temperature. Beijing: China Architecture & Building Press, (in Chinese).

GB/T 50152-2012 (2010) The Standard for the Test Method of Concrete Structures. China Architecture & Building Press, (in Chinese).

JGJ/T 23-2011 (2011) Technical Regulations for Testing Concrete Compressive Strength by Rebound Method. China Architecture & Building Press, (in Chinese).

Kim

Jeong

(2006) Experimental investigation on behaviour of steel–concrete composite bridge decks with perfobond ribs. Journal of Constructional Steel Research 62(5): 463–471.

10.

Lasheen

Shaat

Khalil

(2016) Behaviour of lightweight concrete slabs acting compositely with steel I-sections. Construction and Building Materials 124: 967–981.

11.

Sun

Zhao

, et al. (2012) Research progress on reinforced concrete laminated slab in China. Applied Mechanics and Materials 174-177: 263–267.

12.

Liu

Cui

Liu

, et al. (2020b) Experimental and theoretical study on the flexural performance of prestressed concrete steel truss composite slab. Journal of Building Structures 11: 1–13, (in Chinese).

13.

Liu

Cui

Liu

, et al. (2021) Experimental and theoretical study on bending behavior of prestressed concrete composite slabs with steel trusses. Journal of Building Structures 42(8): 95–106.

14.

Liu

, et al. (2020a) Flexural behavior of prestressed concrete composite slab with precast inverted T-shaped ribbed panels. Engineering Structures 215: 110687.

15.

Liu

Huang

Chong

, et al. (2021) Experimental investigation on flexural performance of semi‐precast reinforced concrete one‐way slab with joint. Structural Concrete 22(4): 2243–2257.

16.

Lundgren

(2007) Lap splice over a grouted joint in a lattice girder system. Magazine of Concrete Research 59(10): 713–727.

17.

Lundgren

Helgesson

Sylvén

(2005) Joints in Lattice Girder Structures. Chalmers University of Technology.

18.

Newell

Goggins

(2019) Experimental study of hybrid precast concrete lattice girder floor at construction stage. Structures 20: 866–885.

19.

Nie

Jiang

Nie

, et al. (2021) Effect of truss reinforcement on mechanical properties of prefabricated slabs. Journal of Building Structures 42: 151–158, (in Chinese).

20.

Precast/Prestressed Concrete Institute (1992) PCI design handbook: precast and prestressed concrete.

21.

Yang

(2021) Improvement of a truss-reinforced, half-concrete slab floor system for construction sustainability. Sustainability 13(7): 3731.

22.

Mansour

Bakar

Ibrahim

, et al. (2015) Flexural performance of a precast concrete slab with steel fiber concrete topping. Construction and Building Materials 75: 112–120.

23.

Said

Razak

Othman

(2015) Flexural behavior of engineered cementitious composite (ECC) slabs with polyvinyl alcohol fibers. Construction and Building Materials 75: 176–188.

24.

Stehle

Kanellopoulos

Karihaloo

(2011) Performance of joints in reinforced concrete slabs for two-way spanning action. Proceedings of the Institution of Civil Engineers-Structures and Buildings 164(3): 197–209.

25.

Wang

Zhang

(2013) Summary of study on composite concrete slabs. Applied Mechanics and Materials 351-352: 695–698.

26.

Song

Zhu

, et al. (2022) Design method for prestressed concrete laminated slab with grouted steel-tube trusses. Building Structure 52(01): 109-114+126, (in Chinese).

27.

Qiao

, et al. (2023) Experimental and theoretical research on flexural performance of truss reinforced concrete two-way composite slab with prefabricated baseplate. Structures 58: 105470.

28.

Yang

Liu

Huo

, et al. (2018) Static experiment on mechanical behavior of innovative flat steel plate-concrete composite slabs. International Journal of Steel Structures 18: 473–485.

29.

Yardim

Waleed

AMT

Jaafar

, et al. (2013) AAC-concrete light weight precast composite floor slab. Construction and Building Materials 40: 405–410.

30.

Zhai

Reed

Mills

(2014) Factors impeding the offsite production of housing construction in China: an investigation of current practice. Construction Management & Economics 32(1-2): 40–52.

31.

Zhou

Zhang

(2008) Application of the New Type Single-Direction-Prestress Double-Direction-Tendoning Concrete Floor System in Post-Earthquake Reconstruction. China Architect & Building Press, pp. 448–454, (in Chinese).

32.

Zhou

Zhang

Wang

, et al. (2020) Research on short-term stiffness of prestressed concrete steel tube truss composite slab during construction stage. Building Structure 50(06): 21–24, (in Chinese).