CN201151406Y - Elastic coupling device for independence wheel pair single-axle bogie - Google Patents

Elastic coupling device for independence wheel pair single-axle bogie Download PDF

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Publication number
CN201151406Y
CN201151406Y CNU2008200619505U CN200820061950U CN201151406Y CN 201151406 Y CN201151406 Y CN 201151406Y CN U2008200619505 U CNU2008200619505 U CN U2008200619505U CN 200820061950 U CN200820061950 U CN 200820061950U CN 201151406 Y CN201151406 Y CN 201151406Y
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single axle
elastic coupling
bogie
independent wheel
coupling device
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CNU2008200619505U
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Chinese (zh)
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池茂儒
张卫华
曾京
戴焕云
邬平波
王勇
罗仁
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Southwest Jiaotong University
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Southwest Jiaotong University
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Abstract

The utility model relates to an elastic coupling device of an independent wheel pair single axle bogie, which is applied to the urban light rail floor vehicle. The elastic coupling device comprises a front single axle bogie and a rear single axle bogie which are fixedly connected with the front and rear bogie bodies, and two groups of elastic coupling mechanisms symmetrically arranged on the both sides on the vertical center lines on the upper edges of the front and rear single axle bogies, and each group of elastic coupling mechanism adopts the structure that two cylinders with identical structures are respectively arranged on the front and the rear single axle bogies, a connecting rod is hinged between two pistons through a ball pivot, and two springs which are in pre-compression conditions are respectively arranged on the left and the right sides of the pistons in the two cylinders. The elastic coupling device overcomes the disadvantages that the spreading of the prior independent wheel pair double axle bogie is insufficient on a curve, and the spreading of the independent wheel pair single bogie is excessive on a curve, and can ensure the front and the rear wheels of two independent wheel pair single bogies which are mutually coupled to simultaneously trend in the radial position, and thereby the guiding difficult problem of the independent wheel pair is thoroughly solved.

Description

Independent wheel is to the single axle truck elastic coupling device
Technical field
The utility model relates to the car hinge connecting mechanism between the train body bogie truck, be to be used for the urban light rail low floor vehicle independently to take turns elastic coupling device specifically to single axle truck, when passing through curve to two-axle bogie, independent wheel launches deficiency to solve, and independent wheel launches excessive problem to single axle truck during by curve, makes the trend radial position to launch appropriateness on curve of independent wheel.
Background technology
The right left and right wheels of independent wheel can freely rotate and axletree need not rotation round axletree, so can make down spill to independent wheel right axletree, thereby can reduce the height of vehicle floor face, so the urban light rail low floor vehicle adopts all usually independent wheel right.But because independent the wheel left and right wheels with respect to the independence and freedom revolution separately of its axletree, so vertically do not producing creep power, and vertically creep power plays a part very crucial in the right guiding of wheel, therefore it is relatively poor independently to take turns right steering capability, mainly show as: on straight line, independent wheel is to being difficult for centering, and track one side that reclines is easily moved; On curve, the right angle of attack of independent wheel is bigger, wheel rim takes place easily recline.Can increase the weight of the right wheel wear of independent wheel like this, on the one hand; On the other hand, the right derailing hidden danger of independent wheel increases.
And independent wheel to two-axle bogie and independent wheel to single axle truck in the weak point that all exists aspect the steering capability separately, the steering capability of the two contrast is as follows:
Shown in Fig. 1 be independent wheel to two-axle bogie the situation during by curve, because take turns being subjected to the constraint of same framework I, II position, wheel forms high incidence with respect to omnibearing line usually to I, and wheel forms the negative angle of attack with respect to omnibearing line usually to II, that is to say that I, II position wheel are to launching deficiency on curve.
Shown in Fig. 2 be independent wheel to single axle truck the situation during by curve, take turns no longer being subjected to the constraint of same framework I, II position, but the constraint of car body before and after being subjected to respectively, because wheel is in the rear end of front car body to I, and wheel so wheel forms the negative angle of attack with respect to omnibearing line usually to I, forms high incidence with respect to omnibearing line and take turns to II to the front end that II is in the back car body usually, that is to say that I, II position wheel are to launching excessively on curve.
The front and back wheel of bogie truck on curve no matter be launch deficiency or launch excessively all unfavorable to curve negotiating.
At the right guiding difficult problem of independent wheel, the utility model people once proposed the technical scheme of " a kind of independent wheel is to the single axis bogie flexible coupling mechanism " (number of patent application 2006200367488), and it is by being provided with suitable constraint, fundamentally having solved existing independent wheel to two-axle bogie and independent problem of taking turns the steering capability difference of single axle truck existence on independently taking turns single axle truck.
The utility model content
The purpose of this utility model provides a kind of independent wheel of structural development to the single axle truck elastic coupling device, thereby to realize that better through engineering approaches solves the right guiding difficult problem of independent wheel up hill and dale.
The purpose of this utility model is achieved in that a kind of independent wheel is to the single axle truck elastic coupling device, comprise the forward and backward single axle truck that connects firmly on forward and backward car body, be provided with to forward and backward single axle truck upper edge, its longitudinal midline bilateral symmetry two groups of elasticity coupling mechanisms, its single group structure is: two cylinder barrels that structure is identical are separately fixed on the forward and backward single axle truck, be hinged with a connecting rod through ball pivot between two pistons in the cylinder barrel, and two cylinder barrel inner carrier and arranged on left and right sides are respectively equipped with two springs that are in its pre-compressed state.
Independent wheel is because rigid frame is excessive to their constraint to I, the II position wheel of two-axle bogie to launch deficiency on curve; Take turns in expansion transition on the curve being the constraint because of shortage necessity between them I, the II position of independently taking turns single axle truck; And (shown in Figure 3) independent wheel can remedy weak point of preceding two kinds of bogie trucks just to the flexible couplings bogie truck: just might make I, II position wheel be tending towards radial position to launch appropriateness on curve when we choose suitable shaking the head for the coupling element of coupled bogie during rigidity value.
Above-mentioned independent wheel is as follows to the theoretical derivation of the coupling stiffness (rigidity value of shaking the head) of flexible couplings bogie truck:
1, coupling stiffness determines
Because the single stage suspension rigidity of single axle truck is much larger than secondary suspension rigidity, so can be wheel to regarding an integral body as with framework when making theoretical analysis.Because independent wheel is not to existing vertical creep power in theory, so the suffered deflecting torque of shaking the head of former and later two single axle trucks in the coupled bogie mainly is the moment M that coupling element produces CziMoment M with the generation of secondary suspension system Szi, and when the train stable state was passed through curve, these two moment sums should be 0, so can take turns to the equation of motion of shaking the head:
M szi+M czl=0 (1)
Wherein:
M szi = - 2 K sx B s 2 [ ψ Bi - ψ c + ( - 1 ) i ( l - b ) R ] - - - ( 2 )
M sci = ( - 1 ) i 2 K cx B c 2 [ ( - 1 ) i + 1 ψ Bi - ( - 1 ) i + 1 ψ B ( i ± 1 ) + 2 b R ] - - - ( 3 )
In the formula, K SxBe bogie truck one side secondary suspension longitudinal rigidity, K CxBe the vertical coupling stiffness of bogie truck one side, B sBe the horizontal span of secondary suspension half, B cBe the horizontal span of coupling element half, l is a vehicle name spacing half, and b is the wheelbase half of forward and backward single axle truck, and R is a circular curve radius, ψ BBe the framework angle of shaking the head, ψ cBe the car body angle of shaking the head.
Consider that wheel right displacement and suspension deflection are more much smaller than the nominal spacing 2l of vehicle, can think that therefore the middle body of car body is approximate tangent with circular curve, i.e. ψ c≈ 0.When the train stable state when the circular curve, for the front and back wheel that makes coupling traveling portion to being in radial position fully, must have: ψ BiB (i+1)=0, so can get according to formula (1)~formula (3):
2 K cx B c 2 2 b R = 2 K sx B s 2 ( l - b ) R - - - ( 4 )
That is:
K cx = ( B s B c ) 2 ( l - b ) 2 b K sx - - - ( 5 )
As can be seen from the above equation, the horizontal span B of half b, secondary suspension of the wheelbase of half l of vehicle name spacing, forward and backward single axle truck sPartly, the horizontal span B of coupling element cPartly all be construction parameter, in case structure has determined that these values are exactly steady state value, so coupling stiffness K CxChoose main and the secondary suspension stiffness K SxRelevant.It is coupling stiffness K that formula (5) also has prior characteristics CxChoose with radius of curve R irrelevantly, this is the excellent part of independent wheel coupled bogie just because this will mean: the radius of curve size of the route of pipe line not, as long as coupling stiffness K CxWith the secondary suspension stiffness K SxCoupling rationally, the independent wheel coupled bogie just can be under the effect of suspension and elasticity coupling element the automatically regulating front and back wheel to being tending towards radial position.
2, the realization of coupling mechanism
Derived independent wheel above to single axis bogie flexible coupling running part front and back wheel coupling element longitudinal rigidity K when being tending towards radial position CxNeed satisfied relationship between expression formula, will propose a kind of concrete coupling mechanism below.
Directly the left and right sides between former and later two single axle trucks connects two steel springs of vertically arranging, though make sense in theory, also unrealistic in actual applications, because arrange like this that in actual engineering there is the difficulty of following several respects in steel spring:
(1) supposed the longitudinal rigidity that coupling element only provides in the theoretical derivation in front, and the rigidity of other directions all is tending towards 0, have only the steel spring two ends to link to each other with the front and back framework by the form of ball pivot, and when vertical span of front and back hinge-point also will be bigger, this hypothesis could be set up, and two ends are the stability existing problems of steel spring under strained condition of ball pivot constraint like this;
(2) on the framework, steel spring meeting nature under the effect of gravity was sagging before and after the steel spring two ends were connected to, and can influence the normal operation of spring like this.
Given this, the utility model proposes the technical scheme of above-mentioned elastic coupling device.
The front and back cylinder barrel of every group of elasticity coupling mechanism is separately fixed on the framework of front and back; The two ends of connecting rod are connected with the front and back piston by ball and socket respectively; Length of connecting rod is regulated and catch gear is mainly regulated (satisfying the needs of disalignment apart from bogie truck) and locking to the length of connecting rod.Another set of identical elastic coupling device is arranged symmetrically in the opposite side of bogie truck.
On the framework, spring is placed in the cylinder barrel before and after cylinder barrel is fixed on, so just need not dangles spring between two bogie trucks; Connect because the two ends of connecting rod AB all are ball pivots, this can satisfy the hypothesis in the theoretical derivation of front just: coupling element only provides longitudinal rigidity, and the rigidity of other directions all is tending towards 0.
The equal precompressed compression certain displacement of spring in the cylinder barrel guarantees piston in the positive and negative stroke range of actv. work, and all springs all are in compressive state, and the location of both ends of the spring just is very easy to like this; The constraint of both ends of the spring no longer is the ball pivot constraint, but fixed constraint, so the stability of spring has been out of question.
Vertical coupling stiffness K of the every side of the utility model bogie truck Cx(being equivalent to the integral stiffness that every side elastic coupling device provides) and secondary suspension longitudinal rigidity K SxSatisfy formula (5), therefore, when train passed through curve, the utility model bogie truck just can the automatically regulating front and back wheel independently be taken turns a right guiding difficult problem to the trend radial position thereby solve under the effect of suspension and elasticity coupling element.
The utility model independently take turns to single axle truck elastic coupling device regulating mechanism can force intercouple two independent wheels to the front and back wheel of single axle truck to being tending towards radial position simultaneously, thereby thoroughly solve the right guiding difficult problem of independent wheel, believe along with independent wheel to the succeeding in developing of flexible couplings radial steering, open up the wide new world of a slice even also may bring huge economic benefit and social benefit for the development of urban light rail low floor vehicle.
Description of drawings
Fig. 1 is the scheme drawing that has now when independently wheel passes through curve to two-axle bogie;
Fig. 2 is the scheme drawing that has now when independently wheel passes through curve to single axle truck;
Fig. 3 be existing independent wheel to coupled bogie pass through curve the time scheme drawing;
Fig. 4 is the constructional drawing of single group elasticity coupling mechanism of the present utility model;
Fig. 5 is that the utility model is independently taken turns the scheme of installation to the single axle truck elastic coupling device.
Scheme drawing when Fig. 6 is the utility model shown in Figure 5 by curve.
The specific embodiment
Fig. 4 illustrates, single group elasticity coupling mechanism is made up of two spring installations and connecting rod, wherein spring installation is made up of cylinder barrel, piston and two springs again, and its structure is: two cylinder barrel 6,8 inner carriers 5,7 and arranged on left and right sides are provided with two springs 1,2,3,4 that are in its pre-compressed state.Connecting rod 13 is connected between two pistons 5,7 through ball pivot.
Referring to Fig. 5, forward and backward single axle truck 11,12 connects firmly respectively on forward and backward car body 9,10, be provided with two groups of elasticity coupling mechanisms of same structure as shown in Figure 4 to forward and backward single axle truck 11,12 its longitudinal midline bilateral symmetry of upper edge, promptly four of two groups of coupling mechanisms cylinder barrel two two places are separately fixed on the forward and backward single axle truck.In order to adapt to the different spacing of two single axle trucks on the forward and backward car body, can adopt lever regulated and locking mechanism 14, adjusting length of connecting rod and to be locked, and make that all springs all are in its pre-compressed state in the cylinder barrel.
The guiding principle of coupling device
As shown in Figure 5, in the utility model, when on curve, passing through, two springs 1.4 of the trailing or leading bogie outside (the curve center line outside) elasticity coupling mechanism two cylinder barrel near-ends (refer to the spring at last piston cylinder rear portion and the spring of one piston cylinder front portion, back, down together) can be by Piston Compression, and two springs 2.3 of two cylinder barrel outer ends (referring to the spring of last piston cylinder front portion and the spring at one piston cylinder rear portion, back, down together) can loosen automatically; And two springs of the inboard elasticity coupling mechanism of trailing or leading bogie two cylinder barrel outer ends can be by Piston Compression, and two other spring 2,3 can loosen automatically.Two groups of springs that separated by piston in the cylinder barrel are equivalent to effect in parallel, but connecting rod two ends spring installation is again the series connection effect, so the integral stiffness of elastic coupling device just equals the rigidity of one group of spring in the cylinder barrel.
Therefore require rigidity (5) design by formula of every group of spring in the steel cylinder.The spring of elastic coupling device is not crushed to death and function radially when guaranteeing the flexible couplings radial steering by curve, the compressible amount of every group of spring in the elastic coupling device steel cylinder should greater than
Figure Y20082006195000071
(b is the wheelbase half of forward and backward single axle truck, and Bc is the horizontal span half of left and right sides elastic coupling device, and R is the minimal curve radius of train operation track).

Claims (3)

1, a kind of independent wheel is to the single axle truck elastic coupling device, comprise and connecting firmly preceding, aftercarriage (9,10) before on, back single axle truck (11,12), it is characterized in that: before described, back single axle truck (11,12) be provided with to its longitudinal midline bilateral symmetry of upper edge two groups of elasticity coupling mechanisms, its single group structure is: two cylinder barrels (6 that structure is identical, 8) be separately fixed at before, back single axle truck (11,12) on, cylinder barrel (6,8) Nei two pistons (5,7) be hinged with a connecting rod (13) through ball pivot between, and two cylinder barrel inner carrier left sides, right both sides are respectively equipped with two springs that are in its pre-compressed state.
2, according to described independent wheel of claim 1, it is characterized in that: also have length of connecting rod and regulate and catch gear (14) the single axle truck elastic coupling device.
3, according to claim 1 or 2 described independent wheels to the single axle truck elastic coupling device, it is characterized in that: in described two cylinder barrels (6,8) all compression of spring amounts greater than
Figure Y2008200619500002C1
Wherein, b is the wheelbase half of forward and backward single axle truck, and Bc is the horizontal span half of two groups of elasticity coupling mechanisms, and R is the minimal curve radius of train operation track.
CNU2008200619505U 2008-01-23 2008-01-23 Elastic coupling device for independence wheel pair single-axle bogie Expired - Fee Related CN201151406Y (en)

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Application Number Priority Date Filing Date Title
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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101219669B (en) * 2008-01-23 2010-06-02 西南交通大学 Elastic coupling device for independent wheel-and-axle assembly single axle bogie
CN107458407A (en) * 2016-06-02 2017-12-12 株洲时代新材料科技股份有限公司 Be articulated and connected method between a kind of low floor vehicle car body
CN107458410A (en) * 2016-06-02 2017-12-12 株洲时代新材料科技股份有限公司 Be articulated and connected method and articulated system between a kind of low floor vehicle car body

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101219669B (en) * 2008-01-23 2010-06-02 西南交通大学 Elastic coupling device for independent wheel-and-axle assembly single axle bogie
CN107458407A (en) * 2016-06-02 2017-12-12 株洲时代新材料科技股份有限公司 Be articulated and connected method between a kind of low floor vehicle car body
CN107458410A (en) * 2016-06-02 2017-12-12 株洲时代新材料科技股份有限公司 Be articulated and connected method and articulated system between a kind of low floor vehicle car body
CN107458407B (en) * 2016-06-02 2019-04-30 株洲时代新材料科技股份有限公司 Be articulated and connected method between a kind of low floor vehicle car body
CN107458410B (en) * 2016-06-02 2019-07-02 株洲时代新材料科技股份有限公司 Be articulated and connected method and articulated system between a kind of low floor vehicle car body

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Granted publication date: 20081119

Termination date: 20120123