DE19726909C1 - Synchronised rotary joint with joint outer part - Google Patents

Abstract

The joint has an inner part (7) with a second longitudinal axis (8), in the outer surface (9) of which inner running grooves (10) are distributed around the second longitudinal axis. The outer and inner grooves are opposite each other in pairs and accommodate steel balls (16) for torque transmission. A cage (12) is arranged between the inner surface (4) of the joint outer part (7) and the outer surface (9) of the joint inner part (7). It has windows (15) which guide balls (16). The balls are made of an unalloyed quality steel with a carbon content smaller than or equal to 0.7 percentage by weight. They are hardened, having a surface hardness of 58 to 65 HRc. The steel is of the quality Cf53 in accordance with German Industrial Standard DIN 17212 or Society of Automotive Engineers SAE 1050.

Description

The invention relates to a constant velocity universal joint with a Ge outer steering part with a first longitudinal axis defining a cavity has, in the inner surface of outer grooves around the first Longitudinal axis are distributed, with an inner joint part, with a second longitudinal axis, in the outer surface of the inner barrel grooves are distributed around the second longitudinal axis, so that the outer and inner grooves are in pairs, with steel balls for torque transmission, each in two opposite outer and inner grooves men, with a cage that is between the inner surface of the Ge outer steering part and the outer surface of the inner joint part is net and has windows that each lead a ball.

Constant velocity joints of various designs are part of the stand of the technique. For example, such joints are in the construct tion book, volume 36, edited by Prof. Dr. Ing. G. Pahl, "Joints and Cardan Shafts", by F. Schmelz, H.-CH. Count of Seherr-Thoss and E. Aucktor, Springer Verlag 1988, pages 128, 129 and described elsewhere in the same book. The The basic structure of all joints comprises an outer joint part, a gel chin part, balls and a cage. The joint components are out Manufactured steel, preferably steels that are inductive or in Are hardenable. There is an effort to do the joints as free of play as possible, the game being easy Back and forth bending of the joint is checked. The balls are made  made of ball bearing steel according to DIN 5401, quality class II / III, and preferably from a steel of quality 100 Cr6 or 100 CrMn6. The hardness to be observed is 63 ± 3 HRc. On due to increasing performance requirements for the torque support and the ability to bend the outer joint and joint inside each other and increasing encapsulation of the vehicles are the joint components increasing working temperatures from to Partly exposed to well over 100 ° C. Corresponding test bench level Endurance tests have shown that the lifespan is low values were achieved, accompanied by early failures unexpectedly short terms. It was also found that at the same time a tightness of the joints due to play ver wrestling, accompanied by progressive during the experiment Rise in joint temperatures led to the short terms.

The cause was on the balls opposite the delivery stood on the ball surface despite slight abrasive wear Chen found a significant increase in diameter.

It was also found that the conversion of Existing austenite in martensite, mainly in Temperature range between 100 ° and 200 ° C is responsible.

Various measures have been taken in connection with rolling bearings to increase dimensional stability, d. H. to reduce the rest austenite content at the ball bearing manufacturers, näm Lich:

Stabilization, d. H. Tempering treatment at temperatures of 50 ° C above the maximum operating temperature, being here at the same time a drop in hardness due to tempering has to be accepted;

Striving for a bainitic structure instead of a martensitic one Hardening, the disadvantage being that an insufficient Training hardship occurs;

Frozen treatments, d. H. Cooling below 0 ° C between Ab start and start process, with the disadvantage that worse  mechanical properties, such as reduced toughness, fatigue resistance, the result.

The invention has for its object the joint life, especially for applications with high temperature levels, especially in the operating temperature range of 100 ° -200 ° C improve.

This object is achieved in that the Ku made of an unalloyed quality steel with a carbon content less than or equal to 0.7 percent by weight and hardy are.

The advantage of this solution is that compared to hardening high-alloy ball bearing steels no or only neglected Significantly low austenite formation occurs.

With the usual hardening processes, namely induction or furnace hardening the same hardness can be achieved as for outdoor and inner grooves of the outer joint part or inner joint part be enough. This is for use in synchronous rotation steer adequately, although usually for rolling bearings for the balls have higher hardness values than the target for the raceways become.

Due to the missing or lower content of residual austenite the balls have a significantly better dimensional stability than balls made of ball bearing steel, so that the joint installation play in the zu of the assembly also over a long service life and remains even under high temperature loads. A Another advantage is that unalloyed quality steel With a carbon content of 0.7% by weight or less is inexpensive. Such steels are also inexpensive more heat-processable, for example by induction active hardening.

A particularly favorable choice of material is given if the Ku made of a steel of the quality Cf53 and derived from it  Materials exist because these materials are also preferred for Joint parts can be selected. The use of the same materials for all joint components, the recyclability or Cost because no disassembly and sorting is required to to obtain unmixed raw materials.

Surface hardness is preferably used in the hardness treatment aimed for from 58 to 65 HRc.

A constant velocity universal joint in which balls according to the invention Can be used is shown schematically in the drawing posed.

It shows

Fig. 1 is a side view of a so-called VL joint and

Fig. 2 shows a longitudinal section through the synchronous steering with a cut along the section line II-II of Fig. 1st

In Figs. 1 and 2, a constant velocity universal joint is shown, which comprises an outer joint member 1, having a first longitudinal axis 2. The outer joint part 1 is hollow. It has a cavity 3 centered on the first longitudinal axis 2 , in the inner surface of which 4 outer grooves 5 are circumferentially distributed. There are two different orientations of the outer grooves 5 , in such a way that they form a V along the first longitudinal axis 2 in the development.

Furthermore, the outer joint part 1 is provided with a connecting element 6 that is only partially shown in FIG. 2 and is used, for example, for connecting the outer joint part 1 to a driving or driven component, for. B. it can serve for connection to a transmission output of a motor vehicle differential.

An inner joint part 7 is received in the cavity 3 of the outer joint part 1 . This has a second longitudinal axis 8 . In the illustrations according to FIGS. 1 and 2, the two joint parts 1, but 7 shown oriented so that the first longitudinal axis 2 and the second longitudinal axis coincide. 8 The inner joint part 7 has an outer surface 9 , the inner race len 10 are assigned. An inner groove 10 and an outer groove 5 lie opposite each other. This means that the inner grooves 10 according to the distribution of the outer grooves 5 are arranged distributed around the second longitudinal axis 8 , but both intersect. Furthermore, the inner joint part 7 has a connection bore 11 , which is used to connect an intermediate shaft, which is intended, for example, for connection to the inner joint part of a further constant velocity joint.

Between the inner surface 4 of the outer joint member 1 and the outer surface 9 of the inner joint part 7 is a retainer 12 arranged sen of the cage inner surface 13 spaced from the outer surface 9 of the Ge is arranged joint inner part. 7

The cage 12 is guided with its cage outer surface 14 on the inner surface 4 of the outer joint part 1 and has on its circumference corresponding to the distribution of the outer grooves 5 and inner grooves 10 windows 15 , which represent an open opening between the cage inner surface 13 and the cage outer surface 14 . In these windows 15 balls 16 are guided, the inner surface 13 over the Käfigin protrude inward and beyond the cage outer surface 14 and with the protruding areas in engagement with the associated outer groove 5 or inner groove 10 . The balls 16 serve to transmit torque between the outer joint part 1 and the inner joint part 7 and also ensure that the two joint parts can be angled relative to one another so that their longitudinal axes 2 , 8 differ from one another. The balls 16 are made of an unalloyed quality steel with a carbon content of less than or equal to 0.7 percent by weight. They can have a surface which corresponds to that of the conventional balls made from ball-bearing steel or can also be ground, ie the usual lapping and polishing is dispensed with. In addition, the balls have a hardness of 58 to 65 HRc. A preferred material that meets these quality criteria is steel with the quality Cf53 according to DIN 17212 or SAE 1050.

Reference list

1

Outer joint part

2nd

first longitudinal axis

3rd

cavity

4th

Inner surface

5

External grooves

6

Connector

7

Inner joint part

8th

second longitudinal axis

9

Outside surface

10th

Inner grooves

11

Connection hole

12th

Cage

13

Inner surface of the cage

14

Cage outer surface

15

window

16

Bullet

Claims (2)

1. constant velocity universal joint with an outer joint part ( 1 ) with a first longitudinal axis ( 2 ), which has a cavity ( 3 ), in the inner surface ( 4 ) of which outer grooves ( 5 ) are distributed around the first longitudinal axis ( 2 ), with an inner joint part ( 7 ), with a second longitudinal axis ( 8 ), in the outer surface ( 9 ) of which inner grooves ( 10 ) are distributed around the second longitudinal axis ( 8 ), so that the outer and inner grooves ( 5 , 10 ) face each other in pairs with Balls ( 16 ) made of steel for torque transmission, which che are each received in two opposite outer and inner grooves ( 5 , 10 ), with a cage ( 12 ) between the inner surface ( 4 ) of the outer joint part ( 1 ) and the outer surface ( 9 ) of the inner joint part ( 7 ) is arranged and has windows ( 15 ) which each carry a ball ( 16 ), characterized in that the balls ( 16 ) made of an unalloyed quality steel with a carbon content t less than or equal to 0.7 percent by weight and hardened. 2. constant velocity universal joint according to claim 1, characterized in that the balls ( 16 ) have a surface hardness of 58 to 65 HRc.