Journal of Jilin University(Engineering and Technology Edition) ›› 2023, Vol. 53 ›› Issue (10): 2785-2794.doi: 10.13229/j.cnki.jdxbgxb.20211337

Previous Articles     Next Articles

Calculation method of anti-backward-tilting buffer force of luffing jib tower crane

Yang LIU()   

  1. College of Engineering and Design,Hunan Normal University,Changsha 410081,China
  • Received:2021-12-06 Online:2023-10-01 Published:2023-12-13

RICH HTML

 0   

PDF (PC)

106

Abstract:

To address accurately calculate the buffer force of anti-backward-tilting device (ABTD) of luffing jib tower crane, considering the influence of tower body elastic vibration and boom rigid body rotation on the dynamics of ABTD, a mathematical model describing the relative movement of buffer is established. Combined with the buffer characteristic model of ABTD, the mathematical relationship between the buffer force of ABTD and dynamic characteristics of luffing jib tower crane is established. Taking a luffing jib tower crane equipped with hydraulic ABTD as the research object, multiple parameters of the buffer force calculation model are identified, and the buffer force calculation model is verified by a series of anti-backward-tilting test. According to the experimental value of buffer force of ABTD, the dynamic load factor of unloading load is calculated, and the relevant requirements of dynamic load factor under sudden unloading condition in Design Rules for Cranes are corrected, which provides a reference for the revision of relevant national standards for the design of luffing jib tower crane.

Key words: mechanical design and theory, luffing jib tower crane, buffer force, non-parametric model, dynamic load factor

CLC Number: 

  • TH212

Fig.1

Model of luffing jib tower crane"

Fig.2

Dynamic model of buffer"

Fig.3

Boom tilt back model during unloading"

Fig.4

Test device for unloader"

Fig.5

Tension response and shock spectrum of unloader"

Fig.6

Prototype of ABTD"

Fig.7

Test device for hydraulic buffer characteristics"

Fig.8

Series actuation motion and force response"

Fig.9

Relationship between series operating speed andoperating force"

Fig.10

Prototype of luffing jib tower crane"

Fig.11

Bending vibration mode of luffing jib tower crane"

Fig.12

Structure deformation of luffing jib tower crane under loading"

Table 1

Deformation of tower body in series test"

吊重臂根横向变形门架横向变形缓冲杆与缓冲缸的相对位移
54%额定载荷173821
60%额定载荷183921
67%额定载荷204222
73%额定载荷184729
100%额定载荷296536

Fig.13

Dynamic response of ABTD in unloading test"

Fig.14

Hydraulic pressure of series unloading test"

Table 2

Peak value of damping force under series unloading test conditions"

卸载载荷阻尼力 实验值/kN阻尼力 计算值/kN误差/%
54%额定载荷24.022.17.9
60%额定载荷28.024.711.8
67%额定载荷28.526.47.4
73%额定载荷30.532.04.9

Table 3

Dynamic load factor in series test"

卸载载荷动载系数实验值1动载系数实验值2动载系数计算值误差/%
54%额定载荷0.410.420.402.4
60%额定载荷0.400.410.385.0
67%额定载荷0.360.370.352.8
73%额定载荷0.340.340.352.9
1 屈福政, 刘海涛. 履带起重机臂架后倾动力学仿真[J]. 起重运输机械, 2005(12): 40-43.
Qu Fu-zheng, Liu Hai-tao. Backward tilting dynamics simulation of crawler crane[J]. Hoisting and Conveying Machinery, 2005(12): 40-43.
2 王永新, 李鹏举. 动臂塔机防后倾装置的分析与应用[J]. 建筑机械化, 2011,32(3):33-36.
Wang Yong-xin, Li Peng-ju. Analysis and application of anti-backward-tipping device of luffing jib tower crane[J]. Construction Mechanization, 2011,32(3): 33-36.
3 . 塔式起重机设计规范 [S].
4 . 起重机设计规范 [S].
5 . Cranes-design principles for loads and load combinations-part 1: general(2nd ed) [S]. ISO: Geneva, Switzerland, 2012.
6 Ross Dieter K. The behaviour of a simple pendulum with uniformly shortening string length[J]. International Journal of Non-Linear Mechanics, 1979,14(3): 175-182.
7 Cveticanin L. Dynamic behavior of the lifting crane mechanism[J]. Mechanism and Machine Theory,1995, 30(1): 141-151.
8 付玲, 喻乐康, 刘洋, 等. 细长型桁架起重臂卸载冲击动力学研究[J]. 起重运输机械, 2013(1):56-60.
Fu Ling, Yu Le-kang, Liu Yang, et al. Study of unloading impact dynamics on slender truss crane with luffing boom[J]. Lifting the Transport Machinery, 2013(1):56-60.
9 Kang Zhong-yuan, Xu Ge-ning, Yang Heng, et al. Research on dynamic properties of crane boom under the condition of accidental unloading[J]. Advances in Engineering Research, 2016, 103: 576-584.
10 李伟, 杨晨, 王桂录, 等. 基于瞬态动力学强夯机臂架折弯事故分析[J].中国工程机械学报,2020,18(2):184-188.
Li Wei, Yang Chen, Wang Gui-lu, et al. Based on transient analysis of an accident of arm structure[J]. Chinese Journal of Construction Machinery, 2020, 18(2):184-188.
11 刘洋, 李宇力,付英雄,等. 基于缓冲力设计的变阻尼防后倾装置特性研究[J]. 中国工程机械学报, 2013, 11(1):83-87.
Liu Yang, Li Yu-li, Fu Ying-xiong, et al. Study of variable damping hydraulic buffer for crane boom anti-backward-tipping based on buffer force design[J]. Chinese Journal of Construction Machine, 2013, 11(1):83-87.
12 刘洋. 液压防后倾装置特性建模及起重机防后倾研究[J]. 振动工程学报,2022,35(4):912-919.
Liu Yang. Characteristic modeling of hydraulic anti-backward tilting device and research on anti-backward tilting of crane[J]. Journal of Vibration Engineering, 2022,35(4):912-919.
13 Dharankar Chandrashekhar S, Hada Mahesh Kumar, Sunil Chandel. Experimental identification of non-hysteresis algebraic force model of automotive hydraulic damper[J]. International Journal of Vehicle Performance, 2019, 5(2):213-231.
14 王欣, 王逢全, 王锡良. 基于ADAMS的新型液压脱钩器系统仿真[J].建筑机械, 2006(3):59-61.
Wang Xin, Wang Feng-quan, Wang Xi-liang. Dynamic simulation for hydraulic self-release mechanism based on ADASM[J]. Construction Machinery, 2006(3): 59-61.
15 Ju F, Choo Y S, Cui F S. Dynamic response of tower crane induced by the pendulum motion of the payload[J]. International Journal of Solids and Structures, 2006, 43(2):376-389.
16 Yang Qing-le, Qu Fu-zheng, Yu Zhi-yuan, et al. Stress and stability analysis of slewing motion for crawler crane[J]. Engineering Failure Analysis, 2019, 105: 817-827.
[1] Yang LIU. Unloading impact simulation and test of luffing jib tower crane [J]. Journal of Jilin University(Engineering and Technology Edition), 2022, 52(6): 1292-1300.
[2] Yang ZHAO,Yang XIAO,Hao SUN,Wen-hao HUO,Song FENG,Yong LIAO. Numerical simulation of micro pitting damage characteristics of lubricated contact gears based on contour integral [J]. Journal of Jilin University(Engineering and Technology Edition), 2022, 52(4): 799-810.
[3] Wei ZHENG,Jian-jun SUN,Chen-bo MA,Qiu-ping YU,Yu-yan ZHANG,Tao NIU. Research status and prospect of automobile wheel hub machining fixture [J]. Journal of Jilin University(Engineering and Technology Edition), 2022, 52(1): 25-36.
[4] Wei CHEN,Yu-long LEI,Xing-zhong LI,Yao FU,Jian-long HU,Li-guo HOU. Calculation of adhesive wear of involute cylindrical spur gear under low⁃speed conditions [J]. Journal of Jilin University(Engineering and Technology Edition), 2021, 51(5): 1628-1634.
[5] Zhen GUO,Hong-ying YU,Zhong-xin HUA,Di ZHAO. Kinematic analysis and simulation of folding process for rigid origami mechanisms [J]. Journal of Jilin University(Engineering and Technology Edition), 2020, 50(1): 66-76.
[6] ZHU Wei,WANG Chuan-wei,GU Kai-rong,SHEN Hui-ping,XU Ke,WANG Yuan. Stiffness and dynamics analysis of a new type of tensegrity parallel mechanism [J]. Journal of Jilin University(Engineering and Technology Edition), 2018, 48(6): 1777-1786.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Copyright © Journal of Jilin University(Engineering and Technology Edition), All Rights Reserved.
Tel: +86-431-85095297 Fax: +86-431-85094074 E-mail: xbgxb@jlu.edu.cn
Powered by Beijing Magtech Co. Ltd