The invention relates to a bearing pin for locking pieces, in particular a motor vehicle door lock. The locking pieces are at least partially rotationally mounted on the bearing pin, forming a bearing axis. The invention also relates to a motor vehicle door lock comprising locking pieces mounted on a carrier plate on such a bearing pin.
Motor vehicle door locks that are usually used are supplied as separately installable parts, which are then installed by the vehicle manufacturer. The motor vehicle door lock contains in most cases moveable parts that should ensure safe locking of the vehicle door. In most cases, catches are used on the vehicle door side interacting with pins or blocks to lock the motor vehicle door.
The catches have to absorb considerable forces, as break-ins as well as an unwanted opening of the door, in case of an accident, must be prevented. The catches and the parts in the motor vehicle door lock on which the catches are mounted must therefore be mounted securely in the motor vehicle door lock.
The large number of individual parts that have to be installed separately constitute an expensive part of the production of standard motor vehicle door locks. The individual parts and the assembled unit have to withstand high mechanical requirements with regard to stability under load.
In modern vehicles it also has become more and more important that moved parts, such as motor vehicle door locks, work as quietly as possible. Conventional motor vehicle door locks therefore require additionally installed means or costly low-noise fixings. All the above measures and stipulations create additional costs due to the large number of different parts and the associated manufacturing steps.
The invention has the task of reducing the aforementioned disadvantages and of providing an improved bearing for locking pieces as well as improved motor vehicle door locks, improving in particular the overall process sequence of production with regard to economic efficiency and quality.
The task is solved by a bearing pin for locking pieces according to claim 1 and a motor vehicle door lock with locking pieces mounted on a carrier plate according to claim 12.
According to the invention, a carrier plate, supporting at least one locking piece, is made of a shape-retaining material, in particular metal, from which a clip-shaped form is formed in essentially the axial direction of the bearing axis, with the bearing clip being formed by means of plastic extrusion coating about the clip-shaped form.
The invention suggests producing the support, which normally is provided by a solid metal axis, requiring separate installation, from a plastic extrusion coating part, formed from the carrier plate. The plastic extrusion coating of the bearing pin alone considerably reduces the noise of the catch in its bearing. The required high mechanical stability is provided by the clip-shaped form formed from the carrier plate.
The use of plastic also means a reduction in weight, which in turn reduces costs. Apart from providing considerable sound proofing, plastic also offers excellent properties with regard to temperature resistance, stability and distortion-resistance.
The plastics used may, for instance, be technical plastics and/or fiberglass or carbon-fiber reinforced plastic or elastomers.
The bearing axis is preferably produced by coating, using the so-called Outsert method. During this process, the plastic material is sprayed directly around the parts to be enclosed and edges, openings or projections on the metal carrier serving as an anchor or projection for the plastic. Assembly of the extruded parts is therefore not required. As a result, numerous process steps and material for the parts otherwise required for assembly are saved and costly logistics and storekeeping of parts that would otherwise have to be manufactured and supplied individually is also no longer required.
The Outsert method allows the production of very precise shapes with very low tolerances. As also no installation is required, any potential tolerances of the geometries associated therewith, are also avoided.
In a preferred embodiment of the invention the clip-shaped form has been punched out of the carrier plate and moved upright.
Preferably, the coating of the clip-shaped form forms a cylindrical bearing pin.
Also preferably the coating forms a bearing pin with a smaller internal and a larger external diameter with the larger diameter being provided in the main direction of the force transfer from the locking piece onto the bearing pin.
As a result of the thus chosen larger diameter, a wider clip-shaped form can be chosen, further increasing the divertible forces.
Consequently, a mainly dovetail-shaped bearing seat opening is provided in the locking piece, corresponding to the bearing pin, said opening having a corresponding smaller internal diameter and a larger external diameter. A further advantage of the cooperation of the thus designed bearing pin and bearing seat opening is that a definitive stop for the locking piece is created.
In an advantageous embodiment of the invention, the end of the bearing pin is seated in a recess in the lock housing enclosing the locking pieces at least partially.
Preferably, the locking pieces are a catch and/or a pawl of a motor vehicle door lock.
According to another aspect of the invention, a motor vehicle door lock with locking pieces on the carrier plate is suggested, in which at least one of the locking pieces is seated on a bearing pin according to claims 1 to 11.
In a preferred embodiment of the invention the carrier plate and/or the lock housing, covering at least partially the locking pieces on the carrier plate, contain guiding grooves and/or guiding elevations and/or stops for the locking pieces and/or other moved parts of the motor vehicle door lock consisting of an applied plastic coating or application.
Advantageously, the locking pieces partly contain a plastic extrusion coating, said plastic extrusion coating being applied, in particular, using the Outsert method.
In a particular advantageous further development of the invention, the external edges and/or edges of openings or punched-out sections of the carrier plate contain a plastic extrusion coating covering the edges at least partially, said plastic extrusion coating having, in particular, being applied using the Outsert method. As a result, potential injuries can be prevented and the usually required labor-intensive deburring is no longer necessary in most cases. The extrusion coating also protects the edges against corrosion as open punched or cut out areas are sealed and no longer in contact with air. As a result of the extrusion coating also thicker material can be used, whose edges do not contain an earlier applied protective layer, e.g. zinc layer because of the processing—e.g. punching. The extrusion coating also allows a better design in the visible area of the door lock, as any type of surface and forms can be achieved.
In order to reduce noise or friction, a further advantageous embodiment of the invention provides that at least partially between the locking pieces and the carrier plate and/or the frame box and/or the lock housing, a layer of extrusion coating is applied, in particular by the Outsert method. Such an extrusion coating applied from the outside can, apart from reducing the noise, also achieve an improved design of the entire motor vehicle door lock.
An embodiment characterized by an efficient production provides that the plastic extrusion coatings on the bearing plate are produced in a single production step, using the Outsert method.
Advantageously, the bearing plate is formed by a frame box of a motor vehicle door lock. If the Outsert method is used, also the lock housing enclosing the locking pieces on the bearing plate can be produced in one piece.
Other advantages, peculiarities and useful further developments of the invention are shown in the further subclaims or their subcombinations.
Below, the invention is explained in more detail with reference to drawings. The individual diagrammatic views are as follows:
The same reference figures in the drawings refer to the same elements or elements that function in the same way.
In the bearing pins, clip-shaped forms from the carrier plate are extrusion coated, as shown in more detail in
The clip-shaped forms 41 are punched out of the carrier plate 4 in a single process step and are mainly righted up in axial direction of the bearing axis L.
The bearing pins 1 are then formed by plastic extrusion coating 5 around the clip-shaped form 41 in a joint process step, using the Outsert method.
The catch 21 and the pawl 22 are simply placed onto the ends 13 of the bearing pins 1 and pushed down against the carrier plate.
In order to achieve further noise reduction, the catch 21 and the pawl 22 are also partly coated with a plastic extrusion coating 53.
In this view, the plastic extrusion coating 5 of the bearing pins 1 can be seen from below.
The extrusion coating 5 of the bearing pin 1a forms a smaller internal diameter and a larger external diameter. Accordingly, the catch 21a contains a mainly dovetail-shaped bearing seat opening 23, corresponding to the bearing pin 1a. This arrangement forms a stop for the catch preventing it from being turned around the bearing axis by more than a specified amount.
Because of this design, the clip-shaped form 41 can be very wide without the entire bearing seat opening 23 having to have the greater diameter 12 of the bearing pin 1a. The advantage of this is that in the main direction of the force transfer F, higher forces can be transferred onto the .carrier plate by the clip-shaped form 41 and the plastic extrusion coating 5.
The extrusion coating 5 of the bearing pin 1a forms a smaller internal diameter 11 and a larger external diameter 12, with the larger diameter 12 being provided in the main direction of the force transfer F from the catch 21a on the bearing pin 1a. The catch 21a contains, corresponding to the form of the bearing pin 1a, a mainly dovetail-shaped bearing seat opening 23, containing a corresponding smaller internal diameter 24 and a larger external diameter 25.
Number | Date | Country | Kind |
---|---|---|---|
10 2004 001 988.6 | Jan 2004 | DE | national |
This application claims priority under 35 U.S.C. 119 and 35 U.S.C. 365 based upon German Patent Application No. 10 2004 001 988.6, filed on Jan. 13, 2004. The entire disclosure of the aforesaid application is incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/DE05/00026 | 1/12/2005 | WO | 5/22/2007 |