DE102020120896A1 - Method of making a flexible disc coupling and flexible disc coupling - Google Patents

Abstract

Method for producing a flexible disc coupling (104) with an outer ring part (100) and an inner part (102), the outer ring part (100) being produced from unhardened sheet metal in a cutting process, with an inner round being obtained, and the inner part (102) being made from of the inner round is produced, and flexible disc coupling (104) with an outer ring part (100) and an inner part (102), the disc coupling (104) being produced by such a method.

Description

The invention relates to a method for producing a flexible disc coupling. The invention also relates to a flexible disc coupling.

From the document DE 198 22 665 A1 is a hydrodynamic torque converter known with an impeller, a turbine wheel, a guide wheel and a lock-up clutch, which are contained in a housing and with a torque sensor, in which the torque sensor in the space between the turbine wheel and a drive-side first housing shell of the housing radially inside the lock-up clutch is integrated. It is proposed to drive the first housing shell using a flexplate, which is connected in a torque-proof manner to an output shaft of an engine or a crankshaft, and to arrange a starter ring gear on a radially outer, axial area of the flexplate.

From the document DE 10 2012 219 800 A1 a torsional vibration damper is known, in particular for pre-assembly on a clutch for a drive train of a motor vehicle, with an input part, an output part that can be rotated in the circumferential direction relative to the input part about a main axis of rotation, and an energy storage device via which the output part is coupled to the input part in a rotatable, in particular limited rotatable manner , wherein the output part is designed to support only the energy storage device and the clutch. It is proposed that the input part has a drive disc in the form of a flexplate and the flexplate further has a toothed ring around its periphery, with which the flexplate can be operated by a starter motor for starting the internal combustion engine.

The object of the invention is to improve a method mentioned at the outset. In addition, the invention is based on the object of improving the structure and/or function of a disk clutch as mentioned at the outset.

The object is achieved with a method having the features of claim 1. The object is also achieved with a disk clutch having the features of claim 10. Advantageous designs and/or developments are the subject matter of the dependent claims.

The outer ring part can be made from a prefabricated sheet metal. The outer ring part can be made from sheet metal. The outer ring part can be made from flat sheet metal. The sheet metal can be made of unalloyed and low-alloy steel. The sheet may be made from case hardening steel such as 16MnCr5. The outer ring part can be produced in a stamping process. The outer ring part and the inner blank and/or the inner part can have at least approximately geometrically corresponding edge sections. The outer ring part can have an inner edge. The inner blank and/or the inner part can have a disk-like shape. The inner blank and/or the inner part can/can have an outer edge. The inner edge of the outer ring part and the outer edge of the inner blank and/or the inner part can at least approximately correspond to one another geometrically. The inner edge of the outer ring part and the outer edge of the inner blank and/or the inner part can correspond to one another at least in sections. The outer ring part can have projections and/or recesses on its inner edge. The inner blank and/or the inner part can have projections and/or recesses on its inner edge. Projections on the outer ring part can engage in recesses on the inner blank and/or the inner part. Projections on the inner blank and/or the inner part can engage in recesses on the outer ring part. The inner circular blank and/or the inner part can/can arise as a surplus when the outer ring part is manufactured. The inner blank and/or the inner part can be produced together with the outer ring part in a cutting process, in particular in a stamping process.

The outer ring part and/or the inner part can have a central axis. The central axis can serve as the axis of rotation. The outer ring part and/or the inner part can/can be rotationally symmetrical to the central axis. Unless otherwise stated or the context does not indicate otherwise, the statements “axial”, “radial” and “in the circumferential direction” relate to a direction in which the central axis extends. “Axial” then corresponds to an extension direction of the central axis. "Radial" is then a direction perpendicular to the direction of extension of the central axis and intersecting with the central axis. "In the circumferential direction" then corresponds to a circular arc direction around the central axis.

The outer ring part can be machined after it has been manufactured. The outer ring part can be processed in a forming process. The outer ring part can be processed in a bending process, compression molding process, compression compression molding process and/or compression molding process. Starting from a flat shape, the outer ring part can be deformed into a pot-like shape. The outer ring part can be changed from a planar cross section to an L-shaped cross section.

Increments can be made on the outer ring part. The increments can be used to generate a speed signal. The increments can serve to enable a speed recording using a speed sensor. Increments can be produced on the outer ring part in order to make the outer ring part usable as an increment wheel. The increments can be represented with the aid of recesses and webs that follow one another periodically. The increments and/or recesses can be produced in a separating process, in particular in a stamping process. The increments and/or recesses can be produced during and/or after production of the outer ring part. The increments and/or recesses can be produced on the flat outer ring part before forming. The increments and/or recesses can be made on the formed outer ring part. The increments and/or recesses can be produced in a stamping process. The increments and/or recesses can be produced in the direction of a press stroke movement. The increments and/or recesses can be made in a direction transverse to a press stroke movement. The increments and/or recesses can be made using a slide tool.

The inner part can be flexible, in particular in the axial direction. The inner part can serve to enable axial movements, wobbling movements and/or rotary movements to be accommodated. The inner part can also be referred to as a flexplate.

The inner part can be machined after it has been manufactured. The inner part can be processed in a cutting process and/or in a forming process. The inner part can be processed in a stamping process. The inner part can be processed in a bending process, compression molding process, compression compression molding process and/or compression molding process.

The outer ring part and the inner part can be manufactured with corresponding connecting sections. The connecting sections can each have a tab-like shape. The outer ring part can be made with connecting sections for the inner part. The connecting sections of the outer ring part can extend radially inwards. The inner part can be made with connecting sections for the outer ring part. The connecting sections of the inner part can extend radially outwards. The connecting sections of the outer ring part and/or the connecting sections of the inner part can be deformed axially. The connecting sections of the outer ring part and/or the connecting sections of the inner part can each have a recess for connecting means such as rivets. The recesses of the outer ring part can form an outer ring part hole pattern. The recesses of the inner part can form an inner part hole pattern. The outer ring part hole pattern and the inner part hole pattern can correspond to each other.

The inner part can be manufactured with connection sections. The connection sections can each have a tab-like shape. The connecting sections can be used to connect the disc clutch to a drive train module, such as a crankshaft, friction clutch, hydrodynamic torque converter, transmission and/or auxiliary unit drive. The connection sections can extend radially outwards. The connection sections can be deformed axially. The connection sections can each have a recess for connecting means. The recesses of the connection sections can form a connection hole pattern.

The inner part can be made with female sections. The receiving sections can be used to receive fastening elements such as nuts. The fastening elements can be firmly connected to the receiving sections, in particular with a material connection.

The inner part can be heat-treated, in particular hardened, surface-hardened and/or case-hardened. The inner part can be heat-treated after processing, in particular after cutting and/or forming. The inner part can be heat-treated after processing, in particular after cutting and/or forming. The inner part can be heat-treated after the fastening elements are firmly connected to the receiving sections.

The outer ring part and the inner part can be connected to each other. The outer ring part and the inner part can be connected to each other at the connection portions. The outer ring part and the inner part can be riveted together.

The disc clutch may have a cup-like shape. The disc clutch may include a floor portion and a wall portion. The bottom section can extend essentially in the radial direction. The bottom section can be formed using the inner part. The wall section can extend essentially in the axial direction. The wall section can be formed using the outer ring part.

The disc clutch can be arranged in a drive train of a motor vehicle to. The disc clutch can be used for arrangement on a crankshaft, a friction clutch, a hydrodynamic torque converter, a transmission and/or an auxiliary unit drive. The disk clutch can serve to absorb axial movements, wobbling movements and/or rotary movements and/or to reduce torsional vibrations and/or axial vibrations.

In summary and presented in other words, the invention thus results, among other things, in a flexplate in a material-optimized design. A common starting material, for example an easily formable case-hardening steel such as 16MnCr5, can be used for all individual elements. An encoder ring can be produced from an unhardened starting blank and an inner part can be produced from a remaining inner circular blank, which after a final heat treatment meets the strength requirements for a flexplate function.

An entire flywheel can consist of an inner component and an external sensor ring with a specified sensor toothing. The transducer ring may be the first to be stamped in the soft state in a manufacturing sequence. Transducer windows can be produced in a flat board state and then folded over into an L-shape during reshaping into a pot-like target geometry, or they can be produced after deep-drawing using a slide tool. The encoder ring can remain heat-untreated in a further production process. The encoder ring can be connected to the flexplate using a hole pattern and separately inserted rivets. The inner part can also be stamped in a soft state using an inner blank left over after stamping the donor ring. Depending on the case, additional connection areas for fastening the flexplate to a pump housing of a hydraulic torque converter can be punched. These connection areas can be in the form of further recessed radial tongues with corresponding through-holes. Furthermore, areas can be provided in the flexplate that serve to accommodate welded-on threaded nuts, to which, for example, a cold test adapter for testing internal combustion engines at the end of the assembly line can be attached. In this case, the flexplate can be heat treated after the threaded nuts have been welded on.

With the invention, a manufacturing outlay, a use of material, a waste, a number of parts, a number of connection points and/or a cost outlay are/are reduced.

• 1 ein Außenringteil und ein Innenteil einer elastischen Scheibenkupplung,
• 2 eine elastische Scheibenkupplung mit einem Außenringteil und einem Innenteil und
• 3 Schnittansichten einer elastischen Scheibenkupplung mit einem Außenringteil und einem Innenteil.

Exemplary embodiments of the invention are described in more detail below with reference to figures, which show schematically and by way of example:

• 1 an outer ring part and an inner part of a flexible disc coupling,
• 2 a flexible disc coupling having an outer ring part and an inner part and
• 3 Sectional views of a flexible disc coupling with an outer ring part and an inner part.

1 12 shows an outer ring member 100 and an inner member 102 of a flexible disc coupling 104 prior to connection. 2 shows the flexible disc coupling 104 with the connected outer ring part 100 and inner part 102. 2 shows sectional views of the flexible disc coupling 104.

Disk clutch 104 is used to be arranged in a drive train of a motor vehicle on a hydrodynamic torque converter in order to absorb axial movements, wobbling movements and/or rotary movements and to reduce torsional vibrations and/or axial vibrations.

The disk clutch 104 has a cup-like shape with a central axis 105, a wall portion and a bottom portion. The wall section extends substantially in the axial direction and is formed using the outer ring part 100 . The bottom section extends essentially in the radial direction and is formed with the help of the inner part 102 .

The outer ring part 100 has an L-shaped cross section and radially inwardly extending tab-shaped connecting sections, such as 106, with holes. The inner part 102 has a disk-like shape and radially outwardly extending tab-shaped connecting sections, such as 108, with holes. The holes of the connecting portions 106 and the holes of the connecting portions 108 correspond to each other. The outer ring part 100 and the inner part 102 are connected to each other by means of rivets such as 110.

The disk clutch 104 has increments formed radially on the outside with the aid of periodically successive recesses, such as 112, and webs, such as 114, which are used to enable a speed recording using a speed sensor.

The disk clutch 104 has tab-shaped connector portions, such as 116, for connecting the disk clutch 104 to a hydrodyna mix up torque converters. The connection sections 116 extend radially outwards, are deformed axially and each have a hole, such as 118, for a connecting means. Disc clutch 104 has holes such as 120 for connecting disc clutch 104 to a crankshaft.

The disk clutch 104 has receiving portions, such as 122, to which nuts, such as 124, are welded, to which a cold test adapter for testing internal combustion engines can be attached.

Disc clutch 104 is manufactured by stamping outer ring member 100 from unhardened sheet metal of case-hardened steel, such as 16MnCr5, leaving an inner blank. The inner part 102 is punched out of the inner blank. The punched contour of the outer ring part 100 and the punched contour of the inner part 102, as in 1 shown, arranged rotated to each other such that the connecting portions 106 of the outer ring part 100 are arranged in gaps between the connecting portions 108 of the inner part 102 and the connecting portions 108 of the inner part 102 are arranged in gaps between the connecting portions 106 of the outer ring part.

After its manufacture, the outer ring part 100 is formed from a flat shape with a flat cross section into a pot-like shape with an L-shaped cross section. The recesses 112 of the increments are punched before the forming in the axial direction or after the forming in a direction transverse to the central axis. The inner part 102 is reshaped after it has been manufactured. In the process, the connecting sections 108 and the connecting sections 116 are deformed axially, as in FIG 3 shown. Subsequently, the nuts 124 are welded to the receiving portions 122 and the inner part 102 is hardened. The outer ring part 100 remains unhardened. Then the outer ring part 100 and the inner part 102 are riveted together, as in 2 shown.

In particular, “may” denotes optional features of the invention. Accordingly, there are also developments and/or exemplary embodiments of the invention which additionally or alternatively have the respective feature or features.

If necessary, isolated features can also be selected from the combinations of features disclosed here and used in combination with other features to delimit the subject matter of the claim, eliminating any structural and/or functional relationship that may exist between the features.

Reference List

100

outer ring part

102

inner part

104

disk clutch

105

central axis

106

connection section

108

connection section

110

rivet

112

recesses

114

web

116

connector section

118

hole

120

hole

122

recording section

124

nut

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 19822665 A1 [0002]
• DE 102012219800 A1 [0003]

Claims (10)

Method for producing a flexible disc coupling (104) with an outer ring part (100) and an inner part (102), characterized in that the outer ring part (100) is produced in a cutting process from unhardened sheet metal, with an inner round being obtained, and the inner part ( 102) is made from the inner blank. procedure after claim 1 , characterized in that the outer ring part (100) is processed in a forming process. Method according to at least one of the preceding claims, characterized in that increments are produced on the outer ring part (100). Method according to at least one of the preceding claims, characterized in that the inner part (102) is processed in a cutting process and/or in a forming process. Method according to at least one of the preceding claims, characterized in that the outer ring part (100) and the inner part (102) are produced with corresponding connecting sections (106, 108). Method according to at least one of the preceding claims, characterized in that the inner part (102) is produced with connection sections (116). Method according to at least one of the preceding claims, characterized in that the inner part (102) is produced with receiving sections (122). Method according to at least one of the preceding claims, characterized in that the inner part (102) is heat-treated. Method according to at least one of the preceding claims, characterized in that the outer ring part (100) and the inner part (102) are connected to one another. Elastic disc coupling (104) with an outer ring part (100) and an inner part (102), characterized in that the disc coupling (104) is produced by a method according to at least one of the preceding claims.

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