DE202011103429U1 - Transmission control panel - Google Patents

Abstract

Transmission control plate with at least one oil passage opening from a first side of the transmission control plate to a second side of the transmission control plate, with at least one spacer layer, at least one first active layer that is arranged adjacent to the spacer layer on the first side and at least one second active layer that is the spacer layer on the second Side is arranged adjacent, the oil passage opening extending through the first active position, the spacer position and the second active position from the first side of the transmission control plate to the second side of the transmission control plate, characterized in that at least one of the active layers has an oil flow control opening for the oil passage opening.

Description

The present invention relates to a transmission control plate. Such transmission control plates are used in particular in transmissions in vehicle construction.

Transmission control plates often have a spacing that has oil passage openings. This distance layer has a thickness in the range of 1 mm or larger. The oil passage openings are stamped in the distance position. About the diameter of this oil passage opening in the distance position of the oil flow is deliberately limited, since the oil passage opening acts as a throttle. However, production of the oil passage opening with the accuracy required for this purpose is possible only by means of expensive fine-stamping technology.

The oil passage openings in the distance position must therefore be punched out with a predetermined diameter for each oil passage opening, since due to the large sheet thickness of the spacer layer, the oil passage openings form a flow channel, which acts as a throttle for the fluid flowing through, for example, an oil. The oil passage openings in the distance position act here as oil flow control openings. Due to the considerable flow distance through the distance layer, there is a throttling effect, which limits the flow of the oil through flow turbulence, friction and pressure drop. However, the above-mentioned factors leading to throttling also have a negative effect, since the oil pressure after flow is too low and the oil heats up due to friction and flow turbulence.

According to the prior art, the distance position relative to adjacent components in each case by means of a thin gasket layer, also called active layer, sealed. These active layers have a considerably smaller thickness than the distance layer, but are provided with sealing elements, such as sealing beads and coatings around the oil passage openings in the distance position. With such sealing structures and flow channels are formed parallel to the plane of the active layers on the respective outwardly facing surface of the active layer.

The active layers have in oil flow direction adjacent to the oil passage openings in the distance position also corresponding oil passage openings, but no independent influence on the flow of the flowing fluid, such as an oil, have, since the throttling effect of the opposite to the openings in the active layers much longer opening in the distance position results.

3a shows such a transmission control plate in cross section, as used in the prior art. The transmission control plate 1 has a distance 2 and adjacent to these two assets 3 and 4 on. Such active layers are usually provided with beads to fulfill sealing functions over the distance position.

In the distance position there is an oil passage opening 5a ' and in the flow direction adjacent to this oil passage opening 5a ' are in the active positions 3 and 4 also oil passages 5a respectively. 5a '' arranged. The openings 5a and 5a '' have a larger diameter than the opening 5a ' in the distance to the intended throttle effect of the opening 5a in the distance not to influence. The distance position thus determines due to the length of its flow channel in the oil passage opening 5a ' the total passage of oil through the transmission control plate 1 through the openings 5a . 5a ' and 5a '' , The opening 5a ' acts as an oil flow control port.

As mentioned above, it is necessary to open 5a ' very precise to produce a predetermined throttling action over the flow channel of the opening 5a ' to obtain. However, this is only possible with expensive fine-punching technology.

The present invention has for its object to provide a transmission control plate, which can be manufactured inexpensively. Furthermore, to be precisely adjustable in this transmission control plate, the oil passage through the oil passage openings for each of the oil passage openings.

This object is achieved by the transmission control plate according to claim 1. Advantageous developments of this transmission control plate are given in the dependent claims.

According to the invention, the proposed transmission control plate goes away from the previously known concept and suggests that at least one of the active layers has an oil flow control orifice. This means that this active layer limits the oil flow through the oil passage opening of all layers, that is, has a greater flow resistance than the openings in the adjacent layers, through which the limited oil flow flows. For this purpose, the existing oil passage opening in the respective active position can be formed as an oil flow control opening, in particular by the oil passage opening is provided in the active position with a specific aperture effect, which essentially determines the oil flow through the distance position and the two adjacent active layers. Basically, therefore, the concept of throttling the oil flow through the oil passage openings of a transmission control plate, in which the desired limitation of the Flow by means of pressure drop, friction and turbulence of a laminar flow along a bore precisely affected by these factors, discarded and by means of a narrow aperture in at least one or both or all active layers, in which due to the lower flow path the above-mentioned disadvantages in a great deal occur to a lesser extent, limits the flow of oil.

Advantageously, this is accomplished by the fact that the oil passage opening in the active layer, which is to act as an oil flow control opening, has a smaller inside width than the oil passage opening through the adjacent distance layer. This is supported if the distance for the oil passage opening has a ratio of clear width to the length of the bore (thickness of the distance layer) of> 0.8, advantageously> 1.0.

The cross-section of the oil passage opening in the active layer, which acts as an oil flow control opening, is advantageously> 10%, advantageously> 20%, smaller than the cross-sectional area of the oil passage opening in the adjacent distance layer.

A further possibility of forming an oil flow control opening in the active position is to arrange the oil passage opening in the active position, which is to serve as an oil flow control opening, so that it overlaps only partially with the oil passage opening in the distance position. This results in a reduced effective clear width of the oil passage opening in the active position, so that the desired aperture effect occurs.

On the other hand, in order to avoid turbulence in the oil flowing therethrough, it is advantageous if the oil passage openings in projection in the direction of flow on the oil passage openings in the distance position for the active layer within the edge of the oil passage opening of the distance position or at least not outside the edge of the oil passage opening in the distance position.

Thus, a large flow cross-section in the thick spacer layer is deliberately selected in comparison to the diaphragm in the at least one active position, in order to keep the interface effects between the oil and the wall of the opening in the distance position low.

The active layer, which is adjacent on one side to the distance position, may also be formed as a double layer, wherein it has openings that intersect, and together form the effective clear width of the oil passage openings through the double-layered active layer. Advantageously, the openings expansions in different directions, so that they can optionally act mutually as a lateral tolerance compensation.

The active layers advantageously have a thickness of 0.1 to 0.3 mm, advantageously 0.15 mm to 0.25 mm, while the distance layer advantageously has a thickness of 0.3 mm to 5 mm, advantageously of 0.3 mm to 2 mm. The dimensions mentioned here refer to the sheet thickness without an optionally present polymer coating. Since the active position is considerably thinner than the distance, it acts as a shutter rather than a throttle. Also, it is possible to more accurately manufacture the oil flow control orifice in the active layer with simpler tools, for example, no fine blanking is required to create the oil flow control orifice in the relatively thin active layer. However, now that the active layer takes over the oil flow control, a less precise manufacturing process for the oil passage openings is possible for the oil passage opening in the distance position.

This results in cost advantages especially in manufacturing. Furthermore, a smaller diameter of the Öldurchflußsteueröffnung is possible, which in turn makes a higher degree of freedom in the design of the transmission control plate possible. After the bottleneck of the oil flow control orifice, a lesser pressure loss can be achieved by the primary orifice effect of the oil flow control orifice in the active position (compared to the throttling effect of an oil flow control orifice in the distance layer). The turbulences are also reduced, since the outlet cone is omitted as in the prior art for the flow. So it is possible to optimize the flow conditions.

All these advantages result in increased process reliability, longer tool life and higher cycle times in production. Furthermore, the smooth cut portion of the oil flow wells, also an investment in fine blanking presses is not required.

According to the invention, the active layers can consist in particular of full-surface coated C steels, such as, for example, C steels DC01 C490 or DC01 C590, or C steels with particularly high tensile strength or of partially coated stainless steel layers, such as, for example, stainless steel 1.4016. As with the C-steels, it will also depend on the pressure requirements of stainless steels, in particular, whether a spring-hard steel or a softer grade is chosen. As spring-resistant stainless steels, the spring steels 1.4310 or 1.4372 are preferably used.

The distance layer is preferably free of polymeric coatings. But you can avoid it of corrosion risks, in particular all over the entire surface have a metallic protective layer such as a galvanizing.

The active layers may be coated around the oil passage openings, and in particular around the oil flow control openings. These coatings can be combined with seal beads surrounding the respective oil passage openings or defining an oil flow path. In particular, the following substances are suitable as coating materials: fluoropolymer, such as FPM (vinylidene fluoride-hexafluoropropylene copolymer), silicone rubber or NBR rubber (acrylic butadiene rubber), PUR (polyurethane), NR (natural rubber), FFKM ( Perfluoro rubber), SBR (styrene-butadiene rubber), BR (butyl rubber), FVSQ (fluorosilicone), CSM (chlorosulfonated polyethylene) and / or silicone or epoxy resin.

In the following, some examples of transmission control plates according to the invention will now be given. The same or similar reference numerals designate the same or similar components. In the following examples, individual elements of the present invention are each illustrated in conjunction with individual examples. Nevertheless, these individual features of the examples also constitute essential individual features of the invention and can be easily combined with other individual features from other examples.

Show it

1 and 2 a transmission control plate in plan view as a partial explosion representation ( 1 ) or in review ( 2 );

3a a cross section through a transmission control plate according to the prior art;

3b and 3c Cross sections through transmission control plates according to the present invention;

4 a transmission control plate according to the present invention; and

5 another transmission control plate according to the present invention.

The 1 and 2 show a transmission control plate in plan view as a part exploded view in 1 or in review in 2 , A transmission control plate 1 as in 1 has a distance 2 and two active positions 3 and 4 on, each on different sides of the distance 2 the distance position 2 are arranged adjacent. The distance position 2 owns oil flow holes 5a through which oil can pass through perpendicular to the layer plane. These oil flow holes 5a and further oil channels running in the layer plane or parallel to it are provided by sealing structures 6a . 6b For example, beads, which may optionally be coated with a polymer-based coating limited. The outer contour of the active position 3 is with the reference numeral 9a designated. The outer contour of the distance position 2 is with the reference numeral 9a ' designated. The distance layer has a considerably greater thickness than the active layers 3 and 4 on. Also in the distance position 2 there are corresponding oil flow openings 5a ' ,

In the active position 4 There are also corresponding oil flow openings 5a '' that of their own sealing structures, such as beads 6a '' or 6b '' , are surrounded. The outer contour of the active position 4 is with the reference numeral 9a '' shown. The flow openings 5a . 5a ' and 5a '' are perpendicular to the plane of the plates 2 . 3 and 4 arranged one above the other, so that through them oil from one side of the transmission control plate 1 can pass to the other side.

3a shows a cross section through a transmission control plate 1 with distance 2 and assets 3 and 4 in the area of an oil passage hole 5a . 5a ' and 5a '' , As already described above, the flow opening is 5a ' in the distance position 2 provided with the smallest diameter and therefore exercises for through the openings 5a . 5a ' and 5a '' from one side of the transmission control plate 1 to the other side of the transmission control plate 1 passing through oil to a throttling effect. The opening 5a ' therefore acts as an oil flow control port 8th ,

In the 3b and 3c are transmission control plates 1 represented according to the present invention. In 3b is the clear width or the diameter of the openings 5a and 5a ' the same size, while the clear width of the openings 5a '' is significantly smaller than the clear width of the openings 5a and 5a ' , Accordingly, the opening acts 5a '' as an aperture for the one side to the other side of the transmission control plate 1 passing through oil flow and thus also provides an oil flow control opening at the same time 8th represents.

In 3c are the openings 5a and 5a '' with smaller clear width or diameter than the opening 5a ' in the considerably thicker distance 2 educated. Therefore, now form both openings 5a and 5a '' or the openings 5a and 5a '' in all assets 3 . 4 the transmission control plate 1 Oil flow control orifices 8a . 8a ' , This embodiment is preferred when the oil flow in both directions should be possible.

In 4 is another transmission control plate according to the invention 1 shown at the now the opening 5a in the active position 3 with reduced diameter compared to the diameter of the openings 5a ' and 5a '' is trained. The opening 5a therefore forms an oil flow control orifice. Adjacent to the openings 5a and 5a '' are in the active positions 3 and 4 each beading 6a . 6b for the active position 3 or beads 6a '' . 6b '' in the active position 4 educated. These beads form a seal against oil between the area of the openings 5a and 5a '' and the area of these openings 5a and 5a '' opposite side of the beads 6a . 6b . 6a '' . 6b '' out.

In the 3 and 4 is the outer edge of each acting as an oil flow control opening opening 5a '' ( 3b ) 5a . 5a '' ( 3c ) 5a ( 4 Projection into a common plane within the opening edge of the opening 5a ' in the distance position 2 arranged.

In 5 is another cross section through another transmission control plate 1 in the range of two oil flows A and B shown. In this example, the opening is 5b '' in the active position 4 as an oil flow control port 8th educated. For the flow of the stream A at the other opening in the distance position 2 and the assets 3 and 4 is the opening 5a as an oil flow control port 8th educated. This means that at both openings 5 each the upstream opening 5b '' respectively. 5a in the upstream active layer 4 respectively. 3 is designed as an oil flow control opening. In this embodiment, the oil pressure ensures optimum contact of the active layer having the oil flow control opening at the distance position.

Claims (13)

Transmission control plate having at least one oil passage opening from a first side of the transmission control plate to a second side of the transmission control plate, with at least one distance position, at least a first active layer adjacent to the distance position on the first side and at least one second active layer, the distance position on the second Side is arranged adjacent, wherein the oil passage opening extends through the first active position, the distance position and the second active position from the first side of the transmission control plate to the second side of the transmission control plate, characterized in that at least one of the active layers has an oil flow control opening for the oil passage opening. Transmission control plate according to the preceding claim, characterized in that the oil passage opening is formed in at least one of the active layers as an oil flow control opening for this oil passage opening. Transmission control plate according to the preceding claim, characterized in that the oil passage opening in the active position in which it is formed as an oil flow control opening, a smaller clear width, advantageously by ≥ 10%, advantageously by ≥ 20% less than in the distance position. Transmission control plate according to claim 3, characterized in that the oil passage opening in the distance position, a ratio of clear width of the oil passage opening to the thickness of the spacer layer of ≥ 0.8, advantageously ≥ 1.0, has. Transmission control plate according to one of claims 2 to 4, characterized in that the oil passage opening in the active position in which it is formed as an oil flow control opening, a cross-sectional area, advantageously by 10%, advantageously by ≥ 20%, smaller than in the distance position. Transmission control plate according to one of claims 2 to 5, characterized in that the oil passage opening in the active position in which it is designed as an oil flow control opening, the oil passage opening in the distance position at least partially covered. Transmission control plate according to one of claims 2 to 6, characterized in that the edge of the oil passage opening in the active position in which it is designed as an oil flow control opening, in projection in the direction of flow to the oil passage opening in the distance position within or not outside the edge of the oil passage opening in the distance position runs. Transmission control plate according to one of claims 2 to 7, characterized in that the active layer, in which the oil passage opening is formed as Öldurchflusssteueröffnung, at least two perpendicular to the layer plane adjacent to each other arranged layers each having an oil passage opening, which arranged in the adjacent layers Intersecting oil passage openings and form a flowing in the direction of the plane perpendicular direction oil control port. Transmission control plate according to one of the preceding claims, characterized in that at least one of the active layers has a thickness of 0.1 mm to 0.3 mm, advantageously 0.15 mm to 0.25 mm, and / or the distance layer has a thickness of 0, 3 mm to 5 mm, advantageously from 0.3 mm to 2 mm. Transmission control plate according to one of the preceding claims, characterized in that the spacer layer has no polymer-based coating. Transmission control plate according to one of the preceding claims, characterized in that at least one of the active layers on the side facing the distance layer and / or on the side facing away from the spacer layer at least partially, for example in the range of dense beads, optionally adjacent to these coated. Transmission control plate according to the preceding claim, characterized in that the at least one active layer with an elastomer, in particular with fluoropolymer such as FPM (vinylidene fluoride-hexafluoropropylene copolymer), silicone rubber or NBR rubber (acrylic butadiene rubber), PUR (polyurethane ), MR (natural rubber), FFKM (perfluoro rubber), SBR (styrene-butadiene rubber), BR (butyl rubber), FVSQ (fluorosilicone), CSM (chlorosulfonated polyethylene) and / or silicone or epoxy resin. Transmission control plate according to at least one of the preceding claims, characterized in that at least one of the active layers contains a carbon steel or a stainless steel, preferably with a tensile strength ≥ 900 N / mm ² or more preferably ≥ 1100 N / mm ² , in particular spring steel or with the exception the coating consists of it.

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