Finite Element Analysis of Mechanical Properties of Extended End-Plate Joints Under the Combined Action of Tension and Bending During the Entire Fire Process

Yuguan Gao; Yiqun Tang; Erfeng Du

doi:10.13206/j.gjgS24103101

Volume 39 Issue 12

Dec. 2024

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Article Navigation > STEEL CONSTRUCTION(Chinese & English) > 2024 > 39(12): 95-102

Yuguan Gao, Yiqun Tang, Erfeng Du. Finite Element Analysis of Mechanical Properties of Extended End-Plate Joints Under the Combined Action of Tension and Bending During the Entire Fire Process[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(12): 95-102. doi: 10.13206/j.gjgS24103101

Citation:

Yuguan Gao, Yiqun Tang, Erfeng Du. Finite Element Analysis of Mechanical Properties of Extended End-Plate Joints Under the Combined Action of Tension and Bending During the Entire Fire Process[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(12): 95-102. doi: 10.13206/j.gjgS24103101

Citation:

Yuguan Gao, Yiqun Tang, Erfeng Du. Finite Element Analysis of Mechanical Properties of Extended End-Plate Joints Under the Combined Action of Tension and Bending During the Entire Fire Process[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(12): 95-102. doi: 10.13206/j.gjgS24103101

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Finite Element Analysis of Mechanical Properties of Extended End-Plate Joints Under the Combined Action of Tension and Bending During the Entire Fire Process

doi: 10.13206/j.gjgS24103101

School of Civil Engineering, Southeast University, Nanjing 210096, China

Received Date: 2024-10-31
Available Online: 2025-01-25

Abstract

Abstract

The extended end-plate joint is mainly used to transfer gravity and seismic effects. However, in extreme states, connecting joints also have a significant impact on the overall performance of the structure and the prevention of continuous collapse. Among various disasters, fire is still one of the disasters with the highest frequency and the widest range of influence. At present, research on fire resistance performance mainly focuses on the heating stage of a fire, but materials, components, and structures may exhibit different characteristics during the cooling stage compared to the heating stage. During the entire process of a fire, steel joints will be subjected to the tension generated by the "catenary effect" caused by the large deflection of the beam span, as well as the tension generated by the cold shrinkage of the steel. Under the combined action of tension and bending, the steel joints will be damaged, leading to the collapse of the entire steel frame structure. At present, there is relatively little research on the mechanical properties of extended end-plate joints of steel frames during the entire fire process, both domestically and internationally. Therefore, it is urgent to conduct in-depth research on them to provide technical supports for performance-based fire protection design. This ensures that the main structural components are not damaged within a certain period of time after a fire, allowing sufficient time for personnel in the building to escape and for firefighters to carry out their rescue operations.
In the present study, nonlinear thermal-mechanical coupling analysis of extended end-plate joints under the combined action of tension and bending was conducted by using the ABAQUS finite element software. Firstly, a three-dimensional thermal analysis and structural response nonlinear analysis model was established for the extended end-plate joint in the fire heating stage. The accuracy of the modeling method was verified by using the results of heating tests under constant bending effect in existing literature. On this basis, the joints’ temperature field distribution during the entire temperature rise and fall process in a fire was obtained through transient thermal analysis. The thermal-structure coupling analysis were performed to obtain the mechanical properties of joints under the combined action of tension and bending, while the parametric analysis was conducted on the influence of factors such as the fire’s temperature rise and fall history and the magnitude of tensile loads on the mechanical behavior of joints. The results indicated that throughout the entire fire process, the deflection of joints would continue to increase during the cooling stage due to the influence of temperature hysteresis, leading to their failure in the early stage of cooling. At the same time, due to the influence of the catenary effect and the tensile force generated by the cold shrinkage deformation of steel beams, bolt tension was detrimental to the fire resistance time and residual deformation of the joint. In addition, parameter analysis of different tensile forces on joints showsed that when the bending moment of the joint remained constant, the tensile force would have a significant impact on the mechanical behavior of the joint. When the tensile for increased, the deformation and residual strain of the joint gradually increased during the cooling stage, eventually leading to joint failure. Therefore, in fire analysis, the entire process of the fire and the influence of tensile forces on the mechanical behavior of joints should be comprehensively considered, and a rational assessment and detailed calculation analysis of the additional tensile forces exerted on these joints should be conducted.
- extended end-plate joint,
- entire process of fire,
- finite element,
- fire resistance performance,
- bolt connection

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References(24)

References

[1]	中华人民共和国公安部. 建筑钢结构防火技术规范:GB 51249—2017[S]. 北京: 中国计划出版社, 2017.
[2]	Leston-Jones L C, Burgess I W, Lennon T, et al. Elevated-temperature moment-rotation testson steelwork connections[J]. Proceedings of the Institution of Civil Engineers-Structures and Buildings, 1997, 122(4): 410-419.
[3]	Al-Jabri K S, Lennon T, Burgess I W, et al. Behaviour of steel and composite beam-column connections in fire[J]. Journal of Constructional Steel Research, 1998, 46(1/2/3): 308-309.
[4]	楼国彪. 钢结构高强度螺栓外伸式端板连接抗火性能研究[D]. 上海: 同济大学, 2005.
[5]	郝淑英, 董金浩, 叶金铎. 火灾下加劲肋对梁柱外伸端板连接性能的影响[J]. 工程力学, 2010, 27(8): 152-163.
[6]	李国强, 李侥婷, 楼国彪. 梁端受框架约束的平端板连接组合节点抗火性能试验研究[J]. 建筑结构学报,2011,32(4):125-133.
[7]	高义奇, 余红霞, 施刚. 火灾下拉剪组合作用对高强螺栓节点性能影响的试验研究[J]. 工程力学, 2014, 31(9): 97-103.
[8]	Wang W Y, Chen Z H, Zhang L B. Numerical studies and practical design suggestions on fire resistance of unprotected high-strength steel extended end-plate connections[J].Fire Technology, 2023, 59(4): 1585-1612.
[9]	Shaheen M A, Cunningham L S, Foster A S J. Bolt stripping failure and ductility of end plate beam-column connections at ambient and elevated temperatures[J]. Journal of Structural Fire Engineering, 2023, 14(2): 167-184.
[10]	Qiang X, Jiang X, Bijlaard S F, et al.Post-fire behaviour of high strength steel endplate connections-part 1: experimental study[J]. Journal of Constructional Steel Research,2014,108:82-93.
[11]	刘链波,周明,王新堂.H型钢梁-柱节点火灾后力学性能试验及有限元分析[J].工业建筑,2022,52(12):107-112.
[12]	尤洋,王培军,孙乐乐,等.单边螺栓连接T形件-钢管节点高温下及高温后受拉性能[J].浙江大学学报(工学版),2023,57(12):2489-2500.
[13]	李国强,郭士雄.受火约束钢梁在升温段和降温段行为的理论分析(Ⅰ)[J].防灾减灾工程学报,2006(3):241-250.
[14]	郭士雄,李国强.受火约束钢梁在升温段和降温段行为的理论分析(Ⅱ)[J].防灾减灾工程学报,2006(4):359-368.
[15]	Bailey C, Burgess I, Plank R. Analyses of the effects of cooling and fire spread on steel-framed buildings[J]. Fire Safety Journal, 1996, 26(4):273-293.
[16]	姜健,陆尧亮,李国强,等.火灾全过程中高层钢框架结构抗连续性倒塌性能及控制措施[J].建筑结构学报,2021,42(增刊):174-185.
[17]	杨占兴.火灾下钢框架半刚性节点性能的试验研究及有限元分析[D]. 南京:东南大学,2008.
[18]	International Organization for Standardization. Fire-resistance tests elements of building construction,amendment l, amendment 2:International Standard ISO-834[S]. Switzerland: ISO Technical Committees, 1980.
[19]	BSI. Eurocode 3: design of steel structures, part 1.2: general rules-structural fire design:BS EN 1993-1-2[S]. London: British Standards Institution, 2005.
[20]	European Committee for Standardization. Eurocode 4: design of composite steel and concrete structures. part 1-2: general rules-structural fire design:EN 1994-1-2∶2005[S]. London: British Standards Institution, 2005.
[21]	陈桥,姜健,蔡文玉,等.火灾全过程下10.9级高强螺栓断裂性能试验研究[J].土木工程学报,2023,56(7):55-68.
[22]	Yang H, Han L H, Wang Y C. Effects of heating and loading histories on post-fire cooling behavior of concrete-filled steel tubular columns[J]. Journal of Constructional Steel Research, 2008, 64(5):556-570.
[23]	Kumar S M, Darunkumar K S, Arul S J. Tensile and shear strength of 10.9 grade bolts in heating and cooling fire[J].Journal of Constructional Steel Research,2022,197:245-254.
[24]	全国消防标准化技术委员会建筑构件耐火性能分技术委员会.建筑构件耐火试验方法:GB/T 9978.6—2008[S]. 北京: 中国标准出版社, 2008.

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