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Load checking calculation method when auxiliary spring of non-end-contact type few-piece variable cross section master and auxiliary springs works

A variable-section, contact-type technology, applied in calculations, special data processing applications, instruments, etc., can solve the non-end contact type few-piece parabolic variable-section primary and secondary spring action load checking requirements, cannot Satisfies the design and calculation requirements of the small-piece parabolic variable-section leaf spring with non-isomorphic ends, complex deformation calculations, etc.

Active Publication Date: 2016-08-03
WM MOTOR TECH GRP CO LTD
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  • Summary
  • Abstract
  • Description
  • Claims
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AI Technical Summary

Problems solved by technology

However, because the calculation of the deformation at any position of the non-isomorphic few-piece parabolic variable-section leaf spring is very complicated, it has not been possible to give the non-end-contact type small-piece variable-section primary and secondary springs before. Reliable Calculation Method of Acting Load
Although someone has previously given a design method for a few variable-section leaf springs, for example, Peng Mo and Gao Jun once proposed the design of variable-section leaf springs in "Automotive Engineering", 1992 (Volume 14) No. 3 Calculation method, this method is mainly for the design and calculation of few-piece parabolic variable-section leaf springs with end isomorphism, and its shortcoming is that it cannot meet the design and calculation of few-piece parabolic variable-section leaf springs with non-isomorphic ends requirements, and it cannot meet the checking calculation requirements of the non-end contact type few parabolic variable cross-section main and auxiliary springs and auxiliary springs.

Method used

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  • Load checking calculation method when auxiliary spring of non-end-contact type few-piece variable cross section master and auxiliary springs works
  • Load checking calculation method when auxiliary spring of non-end-contact type few-piece variable cross section master and auxiliary springs works
  • Load checking calculation method when auxiliary spring of non-end-contact type few-piece variable cross section master and auxiliary springs works

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Experimental program
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Effect test

Embodiment 1

[0029] Embodiment 1: The number of pieces of a non-end contact type few-piece parabolic variable-section main spring is N=2, wherein, half of the length L=575mm of each piece of main spring, width b=60mm, elastic modulus E=200GPa, The thickness h of the straight section at the root 2 =11mm, half of the installation distance l 3 =55mm, the distance l from the root of the parabola segment to the end point of the main spring 2 =L-l 3 =520mm; Thickness h of the straight section at the end of the first main spring 11 =7mm, the thickness ratio of the parabolic segment of the first main spring to β 1 = h 11 / h 2 =0.64, h of the second main spring 12 = 6mm, the thickness ratio of the parabolic segment of the second main spring to β 2 = h 12 / h 2 = 0.55. Half length L of auxiliary spring A =365mm, the horizontal distance from the auxiliary spring contact point to the main spring end point l 0=210mm, the design value of the primary and secondary spring gap between the second...

Embodiment 2

[0047] Embodiment 2: The number of pieces of a non-end contact type few-piece parabolic main spring is N=2, wherein, half of the length of each main spring is L=600mm, width b=60mm, elastic modulus E=200GPa, and the root is flat Straight section thickness h 2 =14mm, half of the installation distance l 3 =60mm, the distance from the root of the parabola segment to the end point of the main spring l 2 =L-l 3 =540mm; Thickness h of the straight section at the end of the first main spring 11 =9mm, the thickness ratio of the parabolic segment of the first main spring to β 1 = h 11 / h 2 =0.64; the thickness h of the straight section at the end of the second main spring 12 = 8mm, the thickness ratio of the parabolic segment of the second main spring to β 2 = h 12 / h 2 =0.57. Half length L of secondary spring A =380mm, the horizontal distance l between the auxiliary spring contact and the main spring end point 0 =L-L A =220mm, the primary and secondary spring gap between ...

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Abstract

The invention relates to a load checking calculation method when an auxiliary spring of non-end-contact type few-piece variable cross section master and auxiliary springs works, and belongs to the technical field of suspension steel plate springs. The load checking calculation method comprises the following steps: according to the structure size and the elasticity modulus of each parabolic type variable cross section master spring piece with a flat end section and a non-equal structure, firstly determining the deformation coefficient and the half rigidity of an end point of each master spring piece, and the deformation coefficient Gx-BC of the Nth master spring piece at the contact point of a parabolic segment and the auxiliary spring; finally, according to the thickness of a flat section of the root of the master spring, the half rigidity of the master spring piece, the Gx-BC of the Nth master spring piece, and the gap design value of the master and auxiliary springs, performing checking calculation on the load when the auxiliary spring works. Through deformation simulation verification, accurate checking calculation on the load when the auxiliary spring of the non-end-contact type few-sheet variable cross section master and auxiliary springs works can be performed according to the method, so that the design level and the properties of products are improved, and the ride comfort of a vehicle is improved; besides, the weight and the cost of the springs are reduced, the design and experiment expenses are reduced, and the product development speed is accelerated.

Description

technical field [0001] The invention relates to a vehicle suspension leaf spring, in particular to a method for checking and calculating the active load of an auxiliary spring of a non-end contact type few-piece primary and auxiliary spring with variable cross-section. Background technique [0002] In order to meet the variable stiffness design requirements of the vehicle suspension under different loads, a small number of variable cross-section leaf springs are usually designed as the main spring and the auxiliary spring. There is a certain gap between the main spring and the auxiliary spring contacts. The design requirements for the active load of the auxiliary spring. Since the first piece of the main spring with variable cross-section is subjected to complex forces, it not only bears vertical loads, but also bears torsional loads and longitudinal loads. Therefore, the end thickness of the first leaf spring actually designed is usually thicker than other springs. Each pi...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G06F17/50
CPCG06F30/17G06F30/23
Inventor 周长城王炳超赵雷雷于曰伟王凤娟许祥利邵明磊
Owner WM MOTOR TECH GRP CO LTD
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