北美黄杉和云杉-松木-冷杉平行弦木桁架承载性能比较

doi:10.11707/j.1001-7488.LYKX20220388

Abstract

Abstract:

Objective: The bearing performance of Pseudotsuga menziesii and SPF(spruce-pine-fir) parallel chord wood trusses under different web angles was compared to explore the influence of web angles and structural materials on the bearing performance of wood trusses, providing theoretical basis for the structural design of parallel chord wood trusses. Method: Using Smsolver structural mechanics solver, the internal force variation and deformation of each member of parallel chord wooden truss were quantitatively analyzed with bearing capacity and stability as checking indexes, and the upper and lower critical values and optimal web angles values of parallel chord wooden truss were obtained. ABAQUS finite element software was used to analyze and verify the finite element models of Pseudotsuga menziesii and SPF parallel chord wooden trusses with three different web angles. The internal force variation rule of the parallel chord wood trusses with different base materials under different web angles was obtained, and the possible failure mode and stress mechanism were determined. On this basis, with Pseudotsuga menziesii and SPF as base material, respectively, making three web angle parallel chord wood truss, bearing capacity for bending static test, explore parallel chord wood truss of the ultimate load, stress distribution and the main failure mode, and is contrasted with the results of finite element simulation, to verify the exactness of the parallel chord wood truss finite element model analysis and applicability. Result: 1) The optimal web angle of the warren type parallel chord wooden trusses was 47°, the critical value of the lower limit web angle was 34°, and the upper limit web angle was 60°. 2) The ultimate load range of Pseudotsuga menziesii parallel chord wooden trusses was 26.53?40.83 kN and the mid-span deflection range was 30.57?31.01 mm. The ultimate load range of the SPF parallel chord wooden trusses was 23.48?34.16 kN and the mid-span deflection range was 31.85?32.05 mm. 3) The ultimate load of Pseudotsuga menziesii and SPF parallel chord wooden trusses with 34°, 47° and 60° web angle was 26.53 and 23.48 kN, 35.10 and 30.06 kN, 40.83 and 34.16 kN, respectively. The corresponding mid-span deflections were 31.85 and 31.01 mm, 30.72 and 32.05 mm, 30.57 and 31.97 mm, respectively. 4) The failure mode of Pseudotsuga menziesii parallel chord wooden trusses was mainly manifested as the crack in the web member near the truss support and the toothed plate pulling out at the truss end or the load applying point, while the failure mode of SPF parallel chord wooden truss was mainly manifested as the toothed plate pulling out at the truss end and the load applying point. 5) Through ABAQUS finite element simulation and experimental verification, it was found that the chord member axial force at the middle part of the two truss spans is the largest, decreasing gradually on both sides, while the web member force at the middle part of the truss spans is the smallest, increasing gradually on both sides, The chord member axial force was larger than the chord axial force. Conclusion: The bearing capacity of Pseudotsuga menziesii parallel chord wooden trusses is better than SPF parallel chord wooden trusses. The bearing capacity of the parallel chord wood truss increases with the increase of the web angle. Comprehensive analysis shows that the weak points of the two parallel chord wooden trusses are the toothed plate joints at the end of the truss and the loading point. The ABAQUS finite element model can effectively reflect the stress distribution and deformation trend of the whole structure.

Key words: parallel chord wood truss, Pseudotsuga menziesii, spruce-pine-fir (SPF), web angle, bearing performance, ABAQUS finite element simulation

CLC Number:

S781.2

Mingli Qiang,Peng Xiao,Zhe Yuan,Yanwei Su,Lang Zhu,Xinyue Qin,Guanben Du. Comparative Study on Bearing Performance of Pseudotsuga menziesii and SPF (Spruce-Pine-Fir) Parallel Chord Wood Truss[J]. Scientia Silvae Sinicae, 2024, 60(4): 147-156.

Figures/Tables 13

Fig.1

Table 1

Fig.2

Fig.3

Table 2

Table 3

Fig.4

Fig.5

Fig.6

Table 4

Fig.7

Fig.8

Fig.9

References 0

	郭　伟, 费本华, 赵荣军, 等. 木桁架齿板接合节点连接性能的影响因子. 木材工业, 2010, 24 (5): 1- 4.
	Guo W, Fei B H, Zhao R J, et al. Factors affecting metal-plate connected wood joint tension performance. China Wood Industry, 2010, 24 (5): 1- 4.
	黄　浩, 何敏娟. 轻型木桁架体系结构性能试验研究. 佳木斯大学学报(自然科学版), 2009, 27 (4): 481- 485,492.
	Huang H, He M J. Experimental study on light-frame wood truss assemblies. Journal of Jiamusi University (Natural Science Edition), 2009, 27 (4): 481- 485,492.
	强明礼, 韩善宇, 赵子宇, 等. 腹杆角度对平行弦木桁架受力性能的影响. 建筑结构学报, 2022, 43 (3): 188- 196.
	Qiang M L, Han S Y, Zhao Z Y, et al. Effect of web angle on mechanical performance of parallel chord truss. Journal of Building Structures, 2022, 43 (3): 188- 196.
	王菲彬, 滕启城, 高一帆, 等. 多榀木桁架的静载试验及其承载能力. 土木与环境工程学报(中英文), 2019, 41 (2): 86- 92.
	Wang F B, Teng Q C, Gao Y F, et al. Static load test and bearing capacity of timber girder truss. Journal of Civil and Environmental Engineering, 2019, 41 (2): 86- 92.
	王亚典, 蔡荣芳, 高　颖, 等. 木结构建材流通链和生态链的共生关系. 西北林学院学报, 2017, 32 (3): 238- 244.
	Wang Y D, Cai R F, Gao Y, et al. Symbiosis system of circulation chain and ecology chain of wooden building materials. Journal of Northwest Forestry University, 2017, 32 (3): 238- 244.
	王　滋, 周贤武, 武国芳, 等. 国产落叶松平行弦轻型木桁架静力承载性能. 林业科学, 2018, 54 (2): 137- 144.
	Wang Z, Zhou X W, Wu G F, et al. Load-carrying capacity of Larix kaempferi light wood trusses. Scientia Silvae Sinicae, 2018, 54 (2): 137- 144.
	武国芳, 任海青, 周海宾, 等. 轻型木结构用材料和构件制造技术研究进展. 木材工业, 2017a, 31 (1): 5- 8.
	Wu G F, Ren H Q, Zhou H B, et al. Review of manufacturing technology of materials and members for light wood frame construction. China Wood Industry, 2017a, 31 (1): 5- 8.
	武国芳, 王　滋, 王　丽, 等. 轻型木桁架受力性能的有限元模拟. 木材工业, 2017b, 31 (5): 5- 8,26.
	Wu G F, Wang Z, Wang L, et al. Structural behavior evaluation of light wood trusses by finite element method analysis. China Wood Industry, 2017b, 31 (5): 5- 8,26.
	徐　明, 龚迎春, 李霞镇, 等. 我国结构用规格材研究现状及开展产品认证初探. 世界林业研究, 2018, 31 (2): 72- 76.
	Xu M, Gong Y C, Li X Z, et al. Research status and product certification of structural dimension lumber in China. World Forestry Research, 2018, 31 (2): 72- 76.
	许晓梁, 马人乐, 何敏娟. 轻型木桁架静力试验及承载能力分析. 特种结构, 2006, 23 (1): 1- 4. doi: 10.3969/j.issn.1001-3598.2006.01.001
	Xu X L, Ma R L, He M J. Static test and bearing capacity analysis of light timber truss. Special Structures, 2006, 23 (1): 1- 4. doi: 10.3969/j.issn.1001-3598.2006.01.001
	薛　硕, 张占宜, 周海宾. 轻型木楼盖用平行弦木桁架的荷载试验研究. 木材工业, 2019, 33 (6): 1- 5.
	Xue S, Zhang Z Y, Zhou H B. Load bearing test of parallel chord truss of light wooden covering. China Wood Industry, 2019, 33 (6): 1- 5.
	赵子宇, 任海青, 强明礼, 等. 腹杆节间间距对平行弦木桁架承载性能的影响. 西北林学院学报, 2020, 35 (2): 235- 243.
	Zhao Z Y, Ren H Q, Qiang M L, et al. Influence of the spacing between webs on the bearing capacity of parallel string truss. Journal of Northwest Forestry University, 2020, 35 (2): 235- 243.
	周海宾, 任海青, 吕建雄, 等. 木结构用杉木规格材抗弯强度的长度尺寸效应. 建筑材料学报, 2009, 12 (4): 501- 504.
	Zhou H B, Ren H Q, Lü J X, et al. Size effect of length on flexural strength of Chinese fir dimension lumber used in wood structure. Journal of Building Materials, 2009, 12 (4): 501- 504.
	Via B, Zink-Sharp A, Woeste F, et al. Relationship between tooth withdrawal strength and specific gravity for metal plate truss connections. Forest Products Journal, 1999, 49 (7): 56- 63.
	Wood Handbook. 2010. wood as an engineering material, general technical report. Madison, Wisconsin: Forest products laboratory, United States Department of Agriculture, Forest Service.

材料Material	$ {E}_{1} $	$ {E}_{2} $	$ {E}_{3} $	$ {G}_{12} $	$ {G}_{13} $	$ {G}_{23} $	$ {v}_{12} $	$ {v}_{13} $	$ {v}_{23} $
北美黄杉Pseudotsuga menziesii	16 400	1 300	900	910	1 180	79	0.43	0.22	0.37
SPF	11 000	500	500	650	650	60	0.35	0.05	0.40

材料 Material	顺纹抗拉强度 Tensile strength parallel to the grain $ {f}_{\mathrm{t}} $/MPa	顺纹抗压强度Compression strength parallel to the grain $ {f}_{\mathrm{c}} $/MPa	抗弯强度Bending strength $ {f}_{\mathrm{m}} $/MPa
北美黄杉Pseudotsuga menziesii	9.2	14	12
SPF	5.8	11	9.5

编号 No.	极限荷载 Ultimate load/kN		数值来源 Numerical source	挠度Deflection/mm
编号 No.	极限荷载 Ultimate load/kN		数值来源 Numerical source	①点Point①	②点Point②		③点Point③
Ⅰ-1-34°	24.93		模拟值Simulation value	2.80	3.36（31.01）		2.82
Ⅰ-1-34°	26.69	26.53	试验值Test value	2.64	2.75（31.15）	2.85（31.01）	2.58
Ⅰ-2-34°	25.48			2.43	2.87（29.75）		2.48
Ⅰ-3-34°	27.42			2.65	2.93（32.13）		2.72
Ⅰ-1-47°	33.48		模拟值Simulation value	2.25	2.48（30.72）		2.25
Ⅰ-1-47°	35.38	35.10	试验值Test value	1.58	1.84（31.12）	1.82（30.72）	1.65
Ⅰ-2-47°	33.87			1.63	1.79（29.54）		1.57
Ⅰ-3-47°	36.05			1.65	1.83（31.50）		1.71
Ⅰ-1-60°	39.91		模拟值Simulation value	1.60	1.77（30.68）		1.65
Ⅰ-1-60°	39.46	40.83	试验值Test value	1.32	1.41（30.41）	1.51（30.57）	1.32
Ⅰ-2-60°	41.06			1.42	1.59（29.87）		1.47
Ⅰ-3-60°	41.97			1.38	1.54（31.43）		1.44
Ⅱ-1-34°	22.75		模拟值Simulation value	3.23	3.78（31.85）		3.23
Ⅱ-1-34°	22.66	23.48	试验值Test value	2.90	3.22（31.56）	3.41（31.85）	2.85
Ⅱ-2-34°	23.65			3.13	3.47（31.68）		3.12
Ⅱ-3-34°	24.13			2.81	3.54（32.31）		2.94
Ⅱ-1-47°	28.50		模拟值Simulation value	2.38	2.97（32.05）		2.38
Ⅱ-1-47°	31.32	30.06	试验值Test value	2.33	2.49（33.41）	2.61（32.05）	2.54
Ⅱ-2-47°	29.83			2.56	2.83（32.28）		2.37
Ⅱ-3-47°	29.03			2.27	2.51（30.46）		2.54
Ⅱ-1-60°	33.09		模拟值Simulation value	2.37	2.47（31.97）		2.37
Ⅱ-1-60°	34.48	34.16	试验值Test value	2.12	2.38（32.62）	2.41（31.97）	2.03
Ⅱ-2-60°	32.88			2.23	2.56（30.14）		2.16
Ⅱ-3-60°	35.12			2.33	2.62（33.15）		2.22

Comparative Study on Bearing Performance of Pseudotsuga menziesii and SPF (Spruce-Pine-Fir) Parallel Chord Wood Truss

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 13

References 0

Related Articles 1

Recommended Articles

Metrics

Comments

腹杆角度 Web angle/(°)	桁架构造尺寸 Truss construction dimensions/mm	腹杆尺寸 Web member dimensions/mm
34
47
60