Since the coefficients of thermal expansion (CTE) between concrete and GFRP, steel and GFRP are quite different, GFRP laminates with different laminas stacking-sequence present different thermal behavior and currently there is no specification on mechanical properties of GFRP laminates, it is necessary to investigate the thermal influence on composite girder with stay-in-place (SIP) bridge deck at different levels and on different scales. This paper experimentally and theoretically investigated the CTE of GFRP at lamina's and laminate's level on micro-mechanics scales. The theoretical CTE values of laminas and laminates agreed well with test results, indicating that designers could obtain thermal properties of GFRP laminates with different lamina stacking-sequence through micro-mechanics methods. On the basis of the CTE tests and theoretical analysis, the thermal behaviors of composite girder with hybrid GFRP-concrete deck were studied numerically and theoretically on macro-mechanics scales. The theoretical results of concrete and steel components of composite girder agreed well with FE results, but the theoretical results of GFRP profiles were slightly larger than FE and tended to be conservative at a safety level.

1 Kong, B., "Thermal property analysis and applications of GFRP panels to integral abutment bridges" 76 : 1-9, 2014

2 Kong, B., "Thermal field distributions of girder bridges with GFRP panel deck versus concrete deck" 19 (19): 04014046-, 2014

3 Schapery, R. A., "Thermal expansion coefficients of composite materials based on energy principles" 2 (2): 380-404, 1968

4 Kong, B., "Thermal behaviors of concrete and steel bridges after slab replacements with GFRP honeycomb sandwich panels" 56 : 2041-2051, 2013

5 Nelson, M., "The effects of splices and bond on performance of bridge deck with FRP stay-in-place forms at various boundary conditions" 56 : 509-516, 2013

6 Vinson, J. R., "The Behavior of Sandwich Structures of Isotropic and Composite Materials" Technomic Publishing Co 1999

7 Standardization Administration of the People’s Republic of China, "Test method for resin content of glass fiber reinforced plastics"

8 Ringelstetter, T. E., "Structural stay-in-place formwork system of fiber - Reinforced polymer for accelerated and durable bridge deck construction" 1976 : 219-226, 2006

9 Kitane, Y., "Static and fatigue testing of hybrid fiber-reinforced polymer-concrete bridge superstructure" 8 (8): 182-190, 2004

10 ANSYS, "Release 11.0; ANSYS University Advanced"

11 Matta, F., "Prefabricated FRP reinforcement for concrete bridge deck and railing: Design, laboratory validation and field implementation" 2007

12 Reising, R. M., "Performance comparison of four fiber-reinforced polymer deck panels" 8 (8): 265-274, 2004

13 Fam, A., "New bridge deck cast onto corrugated GFRP stay-in-place structural forms with interlocking connections" 16 (16): 110-117, 2011

14 Jones, R. M., "Mechanics of Composite Materials" Taylor & Francis Inc 1998

15 Xin, H.H., "Material tests on pultruded glass fiber reinforced polymer (GFRP) profiles for bridge structures" Civil Engineering between Tongji university and Tokyo Institute of Technology 4550-, 2014

16 Soden, P. D., "Lamina properties, lay-up configurations and loading conditions for a range of fibre-reinforced composite laminates" 58 (58): 1011-1022, 1998

17 Nelson, M., "Full bridge testing at scale constructed with novel FRP stay-in-place structural forms for concrete deck" 50 : 368-376, 2006

18 Keller, T., "Flexural behavior of a hybrid FRP and lightweight concrete sandwich bridge deck" 38 (38): 879-889, 2007

19 Bakis, C. E., "Fiber-reinforced polymer composites for concstruction – state-of-artreview" 6 (6): 73-88, 2002

20 Standardization Administration of the People’s Republic of China, "Fiber-reinforced plastics composites — Determination for mean coefficient of linear expansion"

21 Haohui Xin, "Fatigue behavior of hybrid GFRP-concrete bridge decks under sagging moment" 국제구조공학회 18 (18): 925-946, 2015

22 Ouyang, G. N., "Experimental study on the coefficient of thermal expansion for several fibers" 04 : 48-53, 1988

23 He, J., "Experimental investigation of movable hybrid GFRP and concrete bridge deck" 26 (26): 49-64, 2012

24 He, Y.X., "Effect of core-shell polymer particles on the coefficient of thermal expansion epoxy resin" 27 (27): 5-8, 2012

25 Bank, L. C., "Double-layer prefabricated FRP grids for rapid bridge deck construction: Case study" 10 (10): 204-212, 2006

26 Schaumann, E., "Direct load transmission in hybrid FRP and lightweight concrete sandwich bridge deck" 39 (39): 478-487, 2008

27 Berg, A. C., "Construction and cost analysis of an FRP reinforced concrete bridge deck" 20 (20): 515-526, 2006

28 Dieter, D. A., "Concrete bridge decks constructed with fiber-reinforced polymer stay-in-place forms and grid reinforcing" 1814 : 183-189, 2002

29 Hanus. J. P., "Combined loading of a bridge deck reinforced with a structural FRP stay-in-place form" 23 (23): 605-1619, 2008

30 Ministry of Transport of the People’s Republic of China, "Code for design of highway reinforced concrete and prestressed concrete bridges and culverts"

31 Lin, Z. F., "Behavior of stud connectors under combined shear and tension loads" 81 : 362-376, 2014

32 Bank, L. C., "A model specification for fiber reinforced non-participating permanent formwork panels for concrete bridge deck construction" 23 (23): 2664-2677, 2009