Design method for wall thickness of inner circular sleeve of rubber bushing of externally bias cab stabilizer bar

A technology of rubber bushing and design method, applied in the direction of calculation, special data processing applications, instruments, etc., can solve the problems of inability to realize analytical design, complex analysis and calculation, and failure to give

Inactive Publication Date: 2015-02-18
SHANDONG UNIV OF TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, since the externally biased cab stabilizer bar system is a coupled body composed of rigid body, elastic body and flexible body, and the torsion tube also has bending and torsional coupling, its analysis and calculation are very complicated. Therefore, For the design of the wall thickness of the inner circular sleeve of the rubber bushing of the outer offset cab stabilizer bar, no reliable analytical design method has been given at home and abroad.
At present, for the cab stabilizer bar system at home and abroad, most of them use ANSYS simulation software to simulate and verify the characteristics of the cab stabilizer bar system with a given structure through solid modeling. Although this method can obtain relatively reliable simulation values, however , because the ANSYS simulation analysis can only simulate and verify the characteristics of the stabilizer bar with given parameters, and cannot provide an accurate analytical design formula, it cannot realize the analytical design, let alone meet the requirements of CAD software development for the cab stabilizer bar system

Method used

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  • Design method for wall thickness of inner circular sleeve of rubber bushing of externally bias cab stabilizer bar
  • Design method for wall thickness of inner circular sleeve of rubber bushing of externally bias cab stabilizer bar
  • Design method for wall thickness of inner circular sleeve of rubber bushing of externally bias cab stabilizer bar

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Experimental program
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Effect test

Embodiment 1

[0062] Embodiment 1: The structure of an externally offset cab stabilizer bar system is symmetrical, as shown in figure 2 As shown, it includes: swing arm 1, suspension rubber bushing 2, torsion rubber bushing 3, torsion tube 4; wherein, the torsion tube 4 is not coaxial with the torsion rubber bushing 3, and the external offset of the torsion tube 4 is T =30mm; the distance L between the left and right swing arms 1 c =1550mm, that is, the suspension distance of the stabilizer bar; the distance between the suspension rubber bushing 2 and the torsion rubber bushing 3, that is, the length of the swing arm l 1 =380mm, the distance Δl from the suspension installation position C of the swing arm to the outermost end A 1 =47.5mm; the length L of the twisted tube 4 w =1500mm, inner diameter d=35mm, outer diameter D=50mm, elastic modulus E=200GPa, Poisson’s ratio μ=0.3; the structure and material properties of the left and right four rubber bushes are exactly the same, as image 3...

Embodiment 2

[0110] Embodiment 2: The structural form of a certain externally biased cab stabilizer bar system is the same as that of Embodiment 1, such as figure 2 As shown, the torsion tube 4 is not coaxial with the torsion rubber bushing 3, the external offset of the torsion tube 4 is T=30mm; the distance L between the left and right swing arms 1 c =1400mm, that is, the suspension distance of the stabilizer bar; the distance between the suspension rubber bushing 2 and the torsion rubber bushing 3, that is, the length of the swing arm l 1 =350mm, the distance Δl from the suspension installation position C of the swing arm to the outermost end A 1 =52.5mm; the length L of the torsion tube 4 w =1000mm, inner diameter d=42mm, outer diameter D=50mm; the structures of the left and right four rubber bushes are exactly the same, such as image 3 Shown, wherein, the inner circle diameter d of the inner circle sleeve 5 x =35mm, the wall thickness δ is the parameter to be designed; the length ...

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Abstract

The invention relates to a design method for wall thickness of an inner circular sleeve of a rubber bushing of an externally bias cab stabilizer bar and belongs to the technical field of automobile cab suspension. According to the invention, a design mathematic model for the wall thickness of the inner circular sleeve is established and a Matlab program is utilized to solve and design the wall thickness according to the structure and material characteristic parameters of a stabilizer bar system, by taking the wall thickness of the inner circular sleeve as a parameter and utilizing the relationship between the expressions of the equivalent line rigidity of a torsion pipe, a load coefficient and an equivalent combined line rigidity of the rubber bushing. Known from embodiment design and ANSYS simulation verification, according to the method, an accurate and reliable design value for the wall thickness of the inner circular sleeve is acquired, a reliable technical basis is supplied for the stabilizer bar system design and CAD software development, and under the condition of no increase in product cost, the performance of the cab stabilizer bar system is increased and the running smoothness and safety of the vehicle can be increased only through the adjusting design for the wall thickness of the inner circular sleeve, and meanwhile, the design and test costs can be reduced.

Description

technical field [0001] The invention relates to a vehicle cab suspension, in particular to a method for designing the wall thickness of an inner circular sleeve of a rubber bush of an outer offset cab stabilizing bar. Background technique [0002] The rubber bushing consists of an inner sleeve, a rubber sleeve and an outer sleeve. When the outer radius of the rubber sleeve is given, the inner radius and thickness of the rubber sleeve are related to the wall thickness of the inner sleeve. In the actual design of the cab stabilizer bar system, under the condition that the structure of the stabilizer bar remains unchanged, the adjustment design of the inner circle radius and thickness of the rubber sleeve can be achieved only through the adjustment design of the inner circle sleeve wall thickness, so as to realize the The adjustment design of the roll angle stiffness of the stabilizer bar system of the cab can meet the design requirements of the roll stiffness of the cab. How...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G06F17/50
Inventor 周长城周超孙重锋
Owner SHANDONG UNIV OF TECH
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