 |
Description  |
|
|
The invention relates to a ball joint for use in motor vehicles and
comprising a bearing member made of a plastic material and located between
a joint housing made of a plastic material and a ball head of a ball stud.
The bearing member is secured against being forced out of the joint
housing by projections formed on its outer surface and which engage
undercuts on the inner wall of the joint housing.
There is a desire to produce ball joint housings from a plastic material.
Thereby, production costs and part weight may be reduced. It is also
possible to form the joint housing integral with rods made from a glass
fiber material. Certain rods in motor vehicles, for example, connection
rods for a stabilizer, may be subjected to considerable stresses.
Therefore, when the joint housing is made from a plastic material, the
ball stud must be effectively secured against being pulled or pushed out
of the housing. Moreover, a hermetic and economical sealing of the ball
joint is required to protect the interior of the joint housing against
penetration of dirt.
German Laid-Open application No. 3,239,208 discloses a ball joint
comprising a joint housing made of a plastic material, a bearing member
made of a plastic material, and a ring for receiving a ball head. The
bearing member is made of a plastic material and has on the outer surface
thereof a ring groove for receiving a circumferential projection on the
inner wall of the joint housing. This bearing member has also a
circumferential flange for engaging and sealing against the upper end
surface of the joint housing. A split resilient ring is received in a bore
portion of the plastic joint housing tapered toward the opening through
which a stud extends. Upon insertion of the ball head of the ball stud
into the joint housing, the ring is expanded until it circumscribes the
main diameter of the ball head. Then the ring contracts and lies against a
tapered surface of the bore. Then the ball head is supported against both
the bearing member and the ring and is secured against being pulled out of
the joint housing. The preload of the ring prevents against backlash.
In the known ball joint, the ball stud is unable to withstand large axial
pulling forces since it can be pulled out of the ring which is made of
metal. Moreover, the production of the joint housing is expensive because
forming the circumferential projection and the tapered bore therein
requires an expensive spray mold or an additional finishing step. The
circumferential projection in the joint housing requires application of
large forces during assembly of the bearing member half made of a plastic
material with the housing which forces can damage the edges of the
projection and of the ring groove of the plastic bearing member. This, in
turn, may cause, during use, pushing of the ball stud out of the housing.
Moreover, in the known construction, there is a possibility of rotation of
the plastic bearing member with the ball head. This may cause wear of
respective surfaces of the joint housing and the plastic bearing member.
The wear increases the danger of the ball stud being pushed out of the
housing.
German Pat. No. 3,515,303 discloses a ball joint comprising a ball stud, a
ball socket with slits at the open side thereof, a steel ring with an arm
for receiving a linkage and a one-piece tensioning unit associated with
the ball socket and which tensions the upper zone of the ball socket to
provide for force-locking and form-locking stabilization of the ball
socket. The tensioning unit for axial tensioning of the ball socket which
socket together with the steel ring form the housing of the ball joint, is
designed as a toggle mechanism. This toggle mechanism has claws which
engage the ball socket and which are connected by arms with a centrally
arranged and axially movable pressure member. The pressure member serves
as a handle for actuating the toggle mechanism. In this known ball joint,
the ball socket is not secured against rotation in the housing.
Finally, British Laid-Open application No. 2,166,487 discloses a ball joint
comprising a bearing member which can be snapped into a mounting and is
kept therein by a collar surrounding the mounting and flexible claws. In
this known ball joint, the bearing member is also not secured against
rotation.
The object of the invention is a ball joint comprising a housing which can
be produced more simply, and a bearing member which is prevented from
rotation with the ball head and is reliably secured against being pushed
or pulled out of the joint housing.
According to the invention, axially extending grooves are formed in the
inner wall of the joint housing. The grooves are open at the end surface
of the joint housing where the shank extends from the joint housing. At
their opposite ends, the grooves are closed by end walls formed by
undercuts in the inner wall of the housing. The bearing member has
projections thereon which engage the end walls of the grooves and the side
walls of the grooves.
In a ball joint according to the invention, when the bearing member is
pressed into the joint housing, the projections are pressed toward the
bearing member and then snap into the grooves. Since the projections
engage the end walls of the grooves which extend circumferentially, the
bearing member is secured against being pushed out of the housing. The
bearing member is held against being pulled out of the housing in a
conventional manner, by an inner flange of the joint housing, gripping
against its end or, if it has a tapered end, the bearing member is held by
a respectively tapered portion of the inner wall of the joint housing. It
is also within the scope of the invention to provide the joint housing
with two groups of grooves which open at both ends of the joint housing,
while respective groups of projections secure the bearing member against
being pushed or being pulled out of the housing. Since the projections
also engage the boundary walls of the grooves, turning of the bearing
member with the ball head is prevented.
The joint housing of a ball joint according to the invention can be simply
manufactured by injection molding. To this end, a two-part core stamp is
used. One core stamp part forms the inner wall of the grooves and the
other core stamp part forms the rest of the inner wall of the joint
housing. These core stamp parts are arranged, in injection molding,
gripping each other in the injection mold, and are moved, after the
injection molding, separately from each other, in opposite axial
directions to form the joint housing with undercuts.
In one preferred embodiment of the invention, the projections are resilient
bendable tongues formed on the bearing member and extending at an acute
angle to the circumferentially extending end or boundary walls of te
grooves. The tongues, when the bearing member is inserted into the
housing, are bent toward the bearing member by the inner wall of the joint
housing and on reaching the grooves, snap into the latter. The tongues do
not undergo any damage during assembly. They are able to transmit large
axial forces since they are subjected practically only to compression
stresses. If the tongues have edge beads that engage the boundary
circumferential walls as well as radial and bottom surfaces of the
grooves, the forces are favorably distributed in the tongue or the joint
housing and no local plastic deformations occur.
In a further embodiment, the joint housing is made of a glass-fiber
material and is able to withstand considerable force. Preferably, the
bearing member is made of a hard resilient plastic material such as
polyoxymethylene (POM). The housing cover, on the other hand, may be made
of a soft resilient plastic material such as polyurethane, since it
performs mainly a sealing and not a bearing function.
Other details and advantages of the invention will appear from the
description which follows with reference to respective drawings in which a
preferred embodiment of a ball joint according to the invention is shown.
In the drawings:
FIG. 1 illustrates a longitudinal cross section of a ball joint with the
sectional plane displaced by 90.degree. on the sides of the stud axis;
FIG. 2 shows an exploded view of the ball joint of FIG. 1.
FIG. 1 shows a ball joint with a joint housing 1 made of a plastic material
and comprising a connecting rod 2 formed integrally therewith. A ball head
3 is placed into the joint housing and a shank 4 projects from an opening
in the joint housing 1. The gap between joint housing 1 and the shank 4 is
closed by a rubber resilient sealing bellows 6 the beads of which are
fastened by suitable clamping means against the joint housing 1 and/or the
shank 4.
The ball head 3 is held in a bearing member 7 made of a plastic material
and having an approximately cylindrical outer surface which upon assembly
of the ball joint is bent by the inner wall of the joint housing 1 so that
it tapers to the opening 5 toward the axis of the shank. Thereby, the
bearing member 7 is resiliently preloaded against the ball head 3, and the
ball head 3 and bearing member 7 are secured against being axially pulled
out of the joint housing 1.
The bearing member 7 is prevented from being pushed axially out of the
housing by projections 10 formed on the end of the bearing member 7 which
is opposite the bent portion thereof. The projection engage undercuts 11
of the joint housing 1. The projections 10 have the form of tongues and
are provided at their free ends with edge beads 12.
The undercuts 11 form boundary surfaces of axially extending grooves 13
formed in the inner wall 9 and which open at the end 14 of the joint
housing where the shank extends from the joint housing. The undercuts 11
extend circumferentially of the inner wall 9. To deform the joint housing
after injection molding, a core stamp part is pulled out of the groove 13
at the end 14, and another core stamp part, forming the rest of the inner
wall 9 of the joint housing 1, is pulled out at the opposite end of the
joint housing 1. In this manner, both the grooves 13 with the undercuts 11
and the inner wall 9 of the joint housing 1 tapering toward the opening 5
are formed.
The projections 10, designed as tongues, extend at an acute angle to the
boundary circumferentially extending surfaces of the grooves 13. This
insures good bending properties of the projections 10 and a good
distribution of force. In the embodiment shown, two undercuts 11 are
spaced by 180.degree., and two corresponding projections 10 are provided.
The bearing member has at its end which is opposite to that where the shank
4 extends, spring elements 15 that engage the ball head and have at their
free ends hooks 16 engaging a pressure-knob-like portion 17 of a housing
cover 18. The portion 17 has catch beads 19 that grip under the hooks.
Outer sides of the spring elements 15 engage an inner surface 20 of the
housing cover 18. Thereby, they are biased against the ball head 3. To
provide for a definite contact pressure, the spring elements 15 are
provided in their lower quarter portion with cams 21 which engage the ball
head 3.
The housing cover 18 has an inner flange 22 received in a ring groove
extending around the outer surface of the joint housing for fixing the
cover. Adjacent the flange 22, the housing cover 18 has on its inner
surface sealing beads 24 which engage a conically inclined sealing surface
25 of the joint housing 1.
Assembling of a ball joint according to the invention can best be explained
with reference to FIG. 2. First, the ball head 3 is pushed into the
opening 5 of the bearing member 7, while openings 26 of the bearing member
7 adjacent the projections 10 provides for resilient deflection and
engagement with the ball head 3. Then the pre-assembled unit of the ball
head 3 and the bearing member 7 is pushed through an opening in a cover
side of the joint housing, and the two tongue-like projections 10 are
inserted into the grooves 13. As shown in the drawing, additional inlet
grooves 27 may be formed at the cover end of the joint housing 1, and
undercuts 11 are formed in the transition zone of the grooves 13 and the
inlet grooves 27. The projections resiliently snap beneath the undercuts.
Finally, the housing cover 18 is put on and is caught by the hooks of the
spring elements 15. The flange 22 of the cover snaps behind the rim of the
joint housing 1.
* * * * *
|
|
 |
|
 |
Description |
|
