DE60105826T2 - Universal joint - Google Patents

Description

BACKGROUND THE INVENTION

Field of the invention

The The present invention relates to a universal joint according to the preamble of claim 1.

description of the prior art

One Such universal joint is known from US-B1-6,241,616. These known universal joint shaft is constructed in such a way that a shaft, a first sleeve and a second sleeve are superimposed with each different radius. The first sleeve is so engaged that they are in an area of their length in the Way flexible is that the shaft and the second sleeve in relation on the inside and the outside the first sleeve are displaceable, so the length the universal joint based on the vehicle types variable is.

One another joint is known from US-B1-6,257,798. This joint owns an elongated element that retracted during operation and inserted into a recess in a sleeve enclosing the shaft which compensates for a certain amount of room for noise, vibration, Reduce friction, etc.

in the Generally, a universal joint is one with up to a certain one Grad inclined angle installed, thereby transmitting a rotational force.

The Universal joint is made up of a yoke joint that is on one side for transferring a torque and installed on a side for receiving the same is, as well as from a slip joint, in an axial direction slides between the yoke joint, formed.

1 is a view illustrating a conventional universal joint. As shown therein, the yoke joint is 1 designed in such a way that two yokes are alternately engaged, thereby to install at one end thereof a pin in a radial direction.

Besides that is in between a spider is installed, thereby in a state in which the universal joint is inclined by a certain angle, a torque from the yoke on one side to the yoke on the other to transfer to another page.

The slip joint 2 is constructed in such a way that a rotational force of the Jochgelenk 1 on one side to the yoke joint 1 on the other hand, being the sliding joint 2 slides in an axial direction.

And that includes the slip joint 2 a pipe 3 that with the yoke joint 1 connected on one side, as well as a wave 4 that with the yoke joint 1 connected on the other side.

As in 2 shown is on the inside of the pipe 3 and on the outside of the shaft 4 a pair of interlocking rows of teeth (or keyways) 3a and 3b educated.

In addition, at an open end portion of the tube 3 a glider 3b formed in the axial direction.

At an open end section of the pipe 3 is a dust cover 6 installed to prevent a foreign body from entering the pipe 3 is inserted.

On an outside of the slider 3b is a clamp 5 installed to prevent the pipe 3 and the wave 4 solve and for an axial movement of the pipe 3 and the wave 4 to limit.

The pipe 3 and the wave 4 thus become through the clamp 5 firmly mounted, with the edge distance in the radial direction between the tube 3 and the wave 4 is minimized.

At the same time, a weight force of 8 ~ 15 kp in an axial direction of the pipe 3 and the wave 4 applied to the length of the slip joint 2 adjust. From a human hand, the above weight force is not developed.

The slip joint 2 is in an interior of the yoke joint 1 Installed. As in 3 is shown is between the slip joint 2 and the yoke joint 1 a vibration-damping rubber 7 Installed.

That is, between the inner portion of the yoke joint 1 and the outer portion of the slip joint 2 is a vibration-damping rubber 7 Installed from a rubber material with a good spring force installed, thereby reducing a vibration applied between them is reduced.

Also, in the slip joint 2 in the yoke joint 1 and in the vibration-damping rubber 7 each formed a bore in a radial direction, so that the sliding joint 2 , the yoke joint 1 and the vibration-damping rubber communicate with each other.

A pin-shaped pin 8th is in the interior Inserted space of the bore, thereby the sliding joint 2 , the yoke joint 1 and the vibration-damping rubber 7 to keep stable in an axial direction and in a rotational direction.

In the case of a rotation angle over one on the material property of the vibration damping rubber 7 based elastic area occurs, the rotational force is based on the strength of the pin 8th passing through the slip joint 2 and the yoke joint 1 is installed, transferred.

There in the conventional Universal joint, however, under the slip joint, the tube and the shaft Using a clamp are mounted, a sliding function between not really implemented them.

In addition, kick since then a lot of noise and a because of the close contact of the components strong vibration when the length of the sliding joint is changed.

There on the basis of an exact process a row of teeth in the Pipe and formed in the shaft is the manufacturing process complicated, whereby the production costs are increased.

Of the between the slip joint and the Jochgelenk installed vibration damping Rubber can be at a high or at a low temperature be decomposed, in which a crack may occur. In addition, will due to a high temperature, the strength of the same greatly changed.

There the strength of the vibration damping rubber to transfer the torque is low, a pin is additionally required.

SUMMARY THE INVENTION

Accordingly It is an object of the invention, an improved universal joint to provide an improved shaft connection can, to compensate for the backlash, a vibration reduction and a strength with respect to a temperature and to a Torque between a pipe and a shaft of a slip joint and between a slip joint and a yoke joint.

These Task is solved by the joint according to claim 1.

The preferred embodiments become dependent claims claimed.

SUMMARY THE DRAWING

The The present invention will be described with reference to the attached drawing, in which the only for explanation given and therefore not limiting to the present invention is, understandably, in which:

1 Fig. 12 is a cross-sectional view illustrating a conventional universal joint;

2 a cross-sectional view along the line AA of 1 is;

3 a cross-sectional view along the line BB of 1 is;

4 Fig. 3 is a cross-sectional view illustrating a universal joint according to the present invention;

5 a cross-sectional view along the line CC of 4 is;

6 a cross-sectional view along the line DD of 4 is;

7 is an exploded perspective view illustrating a universal joint according to the present invention;

8th Fig. 10 is a cross-sectional view illustrating another embodiment of the present invention; and

9 an exploded perspective view illustrating a still further embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The embodiments The present invention will be described with reference to the accompanying drawings.

4 FIG. 10 is a cross-sectional view illustrating a universal joint according to the present invention. FIG. As shown therein, the universal joint becomes a longitudinal sliding joint 20 and one at both ends of the slip joint 20 installed yoke joint 10 educated.

The yoke joint 10 is formed of two yokes to transmit a rotational force in an angled state at a certain angle.

That between the yoke joint 10 installed slip joint 20 transmits a rotational force and includes a tube that transmits a rotational force and slides in an axial direction, and a shaft 40 which is inserted in it.

As in the 5 and 7 is shown in the present invention, an elastic member and a transmission element between the tube 30 and the wave 40 of the sliding joint and the sliding joint 20 and the yoke joint 10 Installed.

That between the pipe 30 and the wave 40 of the sliding joint 20 installed elastic element is picked up by a spring pin 150 formed with a cut side, which is formed by rolling a metal material in such a way that it is outwardly stretchable.

The spring pin 150 is installed in such a way that the distance between the two spaced ends is reduced, so that the spring pin 150 is retracted in the direction of the middle side. After installation, an elastic force is generated from the outer side.

That is, the spring pin 150 becomes tight between an inner surface of the pipe 30 and an outer surface of the shaft 40 installed to thereby transmit a rotational force between them. There are three spring pins 150 installed in respective sections.

A transmission element between the pipe 30 and the wave 40 of the sliding joint 20 is installed to transmit a rotational force is provided for transmitting a larger rotational force.

With respect to the transfer element, there are a pair of installation grooves on every three sections 110 and 120 formed facing the inner surface of the tube 30 and the outer surface of the shaft 40 are formed in a circular shape to the spring pin 150 to insert in it.

At the same time the width of the installation grooves are in a state engaged 110 and 120 in close contact with the outer width of the spring pin 150 , where the outside width of the spring pin 150 is reduced and contracted.

The transmission element includes an engagement projection 140 coming from an outer surface of the shaft 40 protrudes, as well as a Eingriffnut 130 standing in the interior of the pipe 30 is formed, thus the engaging projection 140 to record in it.

That is, the three installation grooves 10 and the engagement projections 140 are in the outer portion of the shaft 40 installed at the same angle. The installation groove 110 and the engagement groove 130 are in the interior of the pipe 30 designed so that they coincide with it.

At the same time, the shapes of the installation grooves 110 and 120 as well as the engagement groove 130 the same, wherein the engaging projection 140 protrudes in the same shape as the spring pin 150 , The engaging projection 140 and the spring pin 150 are optional in the installation grooves 110 and 120 as well as in the engagement groove 130 inserted.

As in the 6 and 7 is shown, the elastic element and the transmission element between the sliding joint 20 and the yoke joint 10 implemented in a similar way.

At the same time in the present invention, the shaft 40 of the sliding joint 20 with the yoke joint 10 connected in the same way as the connection to the pipe 30 , is the connection of the pipe 30 and the yoke joint 10 described.

The elastic element between the slip joint 20 and the yoke joint is based on the spring pin 150 implemented in three corresponding sections.

In addition, the elastic element between the sliding joint 20 and the yoke joint 10 based on a pair of installation grooves 160 and 170 placed in three sections on the outer surface of the tube 30 and on the inner surface of the yoke joint 10 are formed to face each other, so that the spring pins 150 inserted in it, implemented.

The transmission element between the sliding joint 20 and the yoke joint 10 gets from an engaging projection 190 standing on the outer surface of the pipe 30 protrudes, and by a Eingriffnut 180 placed in the interior of the yoke joint 10 is formed, so that the engaging projection 190 is inserted in it, formed.

Three installation grooves 170 and three engaging projections 190 are in the outer section of the pipe 30 each formed at the same angle, wherein the installation groove 160 and the engagement groove 180 are formed in the interior of the yoke joint so as to correspond to the same.

As in 8th is shown is a spring pin 150 in the interior of the installation grooves 110 . 120 . 160 respectively. 170 inserted, while in the remaining grooves a metallic fixing pin 200 is inserted.

Since in this case the elastic force is reduced, but a larger rotational force is obtained, the numbers of the spring pin 150 and the fixing pins 200 be adjusted.

9 is an exploded pers pectic view illustrating another embodiment of the present invention. As shown therein, since the components other than the elastic member and the transmission member are the same as those of the previous embodiment of the present invention, the same component designations and the same reference numerals are used for the same components.

First is an elastic element that is between the tube 30 and the wave 40 of the sliding joint is installed, from spring pins 350 formed, which are opposite each other and are spaced from each other.

The spring pin 350 is hollow, wherein it is formed in such a manner that a metal material is rolled into a tube shape and that an outer part thereof is cut off with a cross section elongated in a radial direction and between the tube 30 and the wave 40 is in close contact.

That is, the spring pin 350 has a flat cross-section formed in a radial direction so that the spring pin 350 does not roll and is installed in a compressed state in the direction of a central portion in such a manner that the distance of the outer portions is reduced.

The transmission element between the pipe 30 and the wave 40 of the sliding joint 20 is engaged in a certain direction, leaving the pipe 30 and the wave 40 are more closely engaged in the direction of rotation, with a pair of opposing installation grooves 310 and 320 in the outer surface of the shaft 40 or the inner surface of the pipe 30 includes.

That is, the installation grooves 310 and 320 are hollowed in a mold so that one half of the elongated cavity is divided to an outer shape of the spring pin 350 correspond to. If the installation grooves 310 and 320 be opposed, is the spring pin 350 installed in a compressed state.

That between the pipe 30 and the wave 40 of the sliding joint 20 installed transmission element comprises an engagement projection 340 coming from an outer surface of the shaft 40 protrudes, as well as a Eingriffnut 330 placed in an outer side in the inner section of the pipe 30 is hollowed out.

In the outer section of the shaft 40 are two engaging projections 340 in a respect to the two installation grooves 320 formed crossed direction. The installation groove and the engagement groove 330 are in the inner section of the tube 30 educated.

At the same time, the shapes of the installation grooves 310 and 320 and the engagement grooves 330 the same, wherein the engaging projection 340 has a shape that matches the outer shape of the spring pin 350 for an optional insertion into the installation grooves 310 and 320 or in the engagement groove 330 is similar.

The elastic element and the transmission element are between the sliding joint 20 and the yoke joint 10 designed in a similar way.

At the same time is the wave 40 of the sliding joint 20 connected to the yoke joint in the same way as the connection to the pipe 30 , Therefore, in the present invention, the connection of the pipe 30 with the yoke joint 10 described.

First, one between the slip joint 20 and the yoke joint 10 installed elastic element installed on both opposite sides and includes a spring pin 350 with an elongated cross-section in a radial direction.

A transmission element between the slip joint 20 and the yoke joint 10 includes a pair of installation grooves 360 and 370 with elongated opposite cross sections in an outer surface of the shaft 40 or in an inner surface of the tube 30 in the way that the spring pin 350 is to be pushed.

One between the slip joint 20 and the yoke joint 10 installed transmission element comprises an engagement projection 390 coming from an outer surface of the pipe 30 protrudes, as well as a Eingriffnut 380 attached to an inner portion of the yoke joint 10 so hollowed out that they are the engaging projection 390 equivalent.

That is, there are two engagement projections 390 in an outer section of the tube 30 in one direction, dealing with the two installation grooves 370 crosses, trained. An installation groove 360 and an engagement groove 380 are in the inner portion of the yoke joint 10 designed so that they the engaging projections 390 correspond.

At the same time have the installation grooves 360 and 370 as well as the engagement groove 380 the same shapes, the engaging projection 390 one of the outer shape of the spring pin 350 similar shape, so that the engagement projection 390 optionally in the installation grooves 360 and 370 or the engagement groove 380 is inserted.

In the above-described universal joint according to the present invention, the engaging projections are 140 . 190 respectively. 340 . 390 the engagement grooves 130 . 180 respectively. 330 . 380 inserted in an axial direction, the shaft 40 and the pipe 30 of the sliding joint 20 as well as the slip joint 20 and the yoke joint 10 are fixed in the direction of rotation.

Because at the same time the engagement projections 140 . 190 respectively. 340 . 390 optionally in the engagement grooves 130 . 180 respectively. 330 . 380 as well as in the installation grooves 110 . 120 . 160 . 170 respectively. 310 . 320 . 360 . 370 to be installed, have the engagement grooves 130 . 180 respectively. 330 . 380 and the installation grooves 110 . 120 . 160 . 170 respectively. 310 . 320 . 360 . 370 into which the engaging projections 140 . 190 respectively. 340 . 390 not pushed in, certain places on, leaving the spring pins 150 respectively. 350 in the opposite installation grooves 110 . 120 . 160 . 170 respectively. 310 . 320 . 360 . 370 are to be inserted.

In the state where the wave 40 and the pipe 30 of the sliding joint 20 or the sliding joint 20 and the yoke joint 10 are temporarily fixed in the direction of rotation, are the spring pins 150 respectively. 350 in the opposite engagement grooves 130 . 180 respectively. 330 . 380 through the installation grooves 110 . 120 . 160 . 170 respectively. 310 . 320 . 360 . 370 and the installation grooves located in the radial direction 110 . 120 . 160 . 170 respectively. 310 . 320 . 360 . 370 retracted and inserted.

The spring pins 150 respectively. 350 Therefore, they generate an elastic force in an outer direction, together with the shaft 40 and the tube 30 of the sliding joint 20 or the sliding joint 20 and the yoke joint 10 are in close contact, being fixed in the rotational direction and in the axial direction, respectively. In addition, in the present invention, it is possible to reduce the vibration occurring between the shaft 40 and the tube 30 of the sliding joint 20 or the sliding joint 20 and the yoke joint 10 occurs.

As described above contains the universal joint according to the present Invention an elastic element that by a spring pin and a pin between the tube and the shaft of the sliding joint or is formed between the sliding joint and the Jochgelenk, as well a transmission element, that of an installation groove, an engaging projection and a Engagement groove is formed.

at The present invention thus provides the sliding function of the sliding joint lightly through the spring pin and the pin between the pipe and the shaft is implemented, whereby when the length of the slip joint is changed, the noise and the vibration are reduced and reliability of the product increases is.

In addition, will the transmission structure the torque is simplified, with the manufacturing and assembly processes of the slip joint and the yoke joint are simplified. In the It is therefore possible to reduce the manufacturing costs to lower.

apart Of this, the margin in the direction of rotation between the pipe and the shaft of the sliding joint as well as the sliding joint and the yoke joint balanced. Furthermore will noise reduced due to a margin between them and an efficient one Torque transfer function implemented.

There in the present invention between the sliding joint and the Jochgelenk a spring pin formed of a metal material are the festivities in terms of a high or a low temperature as well as transmitting a torque.

There the engagement groove and the engagement projection are integrally formed on the inside or on the outside of the Sliding joints or the Jochgelenks are formed, an additional Part and an additional process for mounting the slide joint and the yoke joint are eliminated.

There the present invention may be embodied in various forms can, without departing from the spirit or its essential characteristics Of course, the embodiments described above are not understood any of the details of the foregoing description are limited insofar as they are not specified otherwise, but rather are general within its scope, as defined in the appended claims, thus all changes and modifications that fall within the bounds of the claims, therefore of the attached claims are included.

Claims (5)

Universal joint, with: - a sliding joint ( 20 ), where a wave ( 40 ) in an interior of a hollow tube ( 30 ) is inserted to thereby implement a rotational force transmission and sliding function in the axial direction; - a first and a second Hohljochgelenk ( 10 ) on both sides of the slip joint ( 20 ) are installed, wherein the first Hohljochgelenk has a side that the pipe ( 30 ) surrounds, and the second hollow yoke joint has a side which the shaft ( 40 ) surrounds; - transmission means between the pipe ( 30 ) and the wave ( 40 ) and between both ends of the sliding joint ( 20 ) and the yoke joints ( 10 ) are installed and with the pipe ( 30 ), the wave ( 40 ), the slip joint ( 20 ) and the yoke joints ( 10 ) are integrally formed to thereby increase a rotational and transmission force, characterized in that Elastic means between the tube ( 30 ) and the wave ( 40 ) and between both ends of the slip joint ( 20 ) and the yoke joints ( 10 ) are introduced to generate a resilient force in the radial direction, wherein the elastic means of a spring pin ( 150 . 350 ) in which a hollow outer portion is cut off in an axial direction and compressed in a direction of a central portion to thereby generate an elastic force in an outer direction; and - the transfer means from installation grooves ( 110 . 120 . 310 . 320 ) located in an inner section of the tube ( 30 ) and in an outer portion of the shaft ( 40 ) are formed, and from installation grooves ( 160 . 170 . 360 . 370 ) located in an inner portion of the yoke ( 10 ) and in an outer portion of the tube ( 30 ) are formed, which face each other in the radial direction, so that the spring pin ( 150 . 350 ) can be retracted and inserted. Joint according to claim 1, in which the transmission means consist of engagement projections ( 140 . 340 ) coming from one end of the shaft ( 40 ) and into the interior of the tube ( 30 ) are inserted and from Eingriffvorsprüngen ( 190 . 390 ) coming from an outer end of the tube ( 30 ) protrude and into the interior of the yoke ( 10 ) are inserted, as well as from concave engagement grooves ( 130 . 330 ) located in an inner section of the tube ( 30 ) are provided, and of concave engagement grooves ( 180 . 380 ) located in an inner portion of the yoke ( 10 ) are provided, which the respective engagement projections ( 140 . 190 . 340 . 390 ) are formed. Joint according to claim 1, wherein a plurality of installation grooves ( 110 . 120 . 160 . 170 . 310 . 320 . 360 . 370 ) are formed in corresponding sections and a fixing pin ( 200 ) is inserted into a corresponding installation groove. Joint according to claim 1 or 2, wherein the spring pin ( 350 ) has an elongated cross section in the radial direction, so that the spring pin ( 350 ) does not roll, and the installation groove ( 310 . 320 . 360 . 370 ) has an elongated hole in which in the radial direction, the depth of the installation groove equal to half the thickness of the spring pin ( 350 ). Joint according to claim 1, 2 or 4, wherein the inner widths of the installation grooves ( 110 . 160 . 310 . 360 ) and the engagement grooves ( 130 . 180 . 330 . 380 ) are formed alternately in the sections symmetrically with the same shape and the outer widths of the spring pin ( 150 . 350 ) and the engagement projections ( 140 . 190 . 340 . 390 ) are formed with the same shape and the spring pin ( 150 . 350 ) and the engagement projections ( 140 . 190 . 340 . 390 ) optionally in the interiors of the installation grooves ( 110 . 160 . 310 . 360 ) or the engagement grooves ( 130 . 180 . 330 . 380 ) are inserted.