斜螺钉连接的平行弦木桁架节点抗拔性能

doi:10.11707/j.1001-7488.20201216

摘要/Abstract

摘要：

目的: 制作一种节点采用自攻螺钉连接的平行弦木桁架，以不同角度钉入螺钉，探究螺钉钉入角度对平行弦木桁架受拉节点力学性能的影响，为新型桁架在实际工程中的应用提供基础数据，并完善木结构建筑设计标准。方法: 采用进口SPF规格材和自攻螺钉制作桁架受拉节点试件，改变螺钉钉入方向与桁架腹杆顺纹方向的夹角，参考美国标准ASTM D1761-12，对夹角为0°、15°、30°、45°、60°、75°和90°的7组试件以2.54 mm·min^-1的速率单调匀速进行抗拔试验，记录分析受拉节点的破坏形态并对比各组试件的荷载-位移曲线、极限承载力、屈服荷载和刚度。结果: 试件最终破坏形态主要有钉帽拉穿和螺钉拔出2种：夹角为0°和15°时，试件破坏主要是因为木材横纹抗压强度小于螺钉抗拔强度，钉帽最终剪断并拉穿弦杆；夹角为30°~90°时，试件失效主要是因为销槽承压形成的剪力达到螺钉屈服荷载；夹角为0°和15°时试件荷载-位移曲线在最大荷载附近保持较好，夹角为30°~60°时试件荷载-位移曲线下降缓慢，夹角为75°和90°时试件荷载-位移曲线存在明显屈服阶段；节点承载能力随角度变化受木材横纹局部抗压强度和螺钉抗弯强度的影响，夹角为60°时试件的平均承载力最大，达7.423 kN；夹角为0°时试件的屈服荷载最大，达4.859 kN；节点刚度随角度增大而减小。结论: 自攻螺钉倾斜角度在45°~60°范围内试件综合受力性能最好，倾斜角度为0°的试件适用于建筑中对刚度要求较高的部位。

关键词: 平行弦木桁架, 斜螺钉连接, 受拉节点, 抗拔性能

Abstract:

Objective: This study was conducted to evaluate the mechanical properties of the tensile joints of a paralleled string truss connected by self-tapping screws which were screwed from different angles, in order to provide basic scientific data for its practical engineering applications and improve the code for design timber structures. Method: The test pieces of the truss tensile joint were made by the imported SPF dimension lumber and self-tapping screws. By changing the angle between the axial direction of the screw and the grain direction of the web of the truss, the pull-out test was conducted on the 7 groups of tensile joints with angles of 0°, 15°, 30°, 45°, 60°, 75°, and 90°. The test was conducted according to the American specification ASTM D1761-12. Each specimen was pulled out at a constant rate of 2.54 mm·min^-1. The destructive form record, the failure mode analysis and, the comparison of the load-displacement curves, ultimate load-carrying capacity, yield load and stiffness of each group of specimens were implemented. Result: There were 2 types of failure modes:head pulled through the member and the screw pulled out from the tensile joint. When the angle were 0° and 15°, the failure of the test piece was mainly due to the fact that the compressive strength radical to the grain of the wood was less than the characteristic withdrawal strength of the screw, and the screw finally pulled through the chord of the specimen; when the angle was 30°-90°, the cause of failure of specimens was that the shear force formed by the embedment strength reached the yield load of the screw. When the angle were 0° and 15°, the load-displacement curves of specimens kept very well near the maximum load; when the angle ranged from 30° to 60°, the load-displacement curves decreased slowly; when the angle were 75° and 90°, the load-displacement curves all had a significant yield stage. The bearing capacity of the joint was affected by the yield strength of the screw and the compression strength perpendicular to the grain of the wood. When the angle was 60°, the average load-carrying capacity of the specimens was the highest, reaching 7.423 kN, and the yield load was the highest when the angle was 0°, which was 4.859 kN. The stiffness of the joints decreased when the angle between screw axis and grain direction increased. Conclusion: The mechanic behavior of the tensile joint might be the best when the inclined angle is between 45° and 60°. Specimens with an angle of inclination of 0° could be suitable for use in buildings where stiffness is critical.

Key words: parallel chords wood truss, connected with inclined screws, tensile joints, uplift resistant performance

中图分类号:

TU366.2

戈禧芸,蔡雨,陈志坚,侯同宇,刘义凡,阙泽利. 斜螺钉连接的平行弦木桁架节点抗拔性能[J]. 林业科学, 2020, 56(12): 136-144.

Xiyun Ge,Yu Cai,Zhijian Chen,Tongyu Hou,Yifan Liu,Zeli Que. Uplift Resistant Performance of the Joint of the Parallel Chords Wood Truss Connected with Inclined Screws[J]. Scientia Silvae Sinicae, 2020, 56(12): 136-144.

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组别Group	α/(°)	a_{1, CG}/mm	a_{2, CG}/mm	试件个数Number
N1	0	18.00	44.50	5
N2	15	31.00	44.50	5
N3	30	36.00	44.50	5
N4	45	41.00	44.50	5
N5	60	37.00	44.50	5
N6	75	33.00	44.50	5
N7	90	21.00	44.50	5

树种 Variety of tree	含水率 Moisture content(%)	密度 Density/(g·cm^-3)	局部横纹抗压强度 Compression strength perpendicular to grain(f_{c, 90})/MPa	销槽承压强度 Embedment strength(f_h)/MPa	抗拔强度 Withdrawal strength(f_ax)/MPa
SPF	13.9	0.47	4.96	23.82	9.09

型号Type	L/mm	S₁/mm	S₂/mm	S₃/mm	d_h/mm	d/mm	d₁/mm	d₂/mm	抗弯强度 Bending strength(f_m)/MPa
TCC 8×120	118.67	80.58	10.81	27.28	14.57	7.93	5.40	6.60	345.47

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