DE102017110465A1 - torsional vibration dampers - Google Patents

Abstract

A torsional vibration damper, in particular a dual-mass flywheel (100), the torsional vibration damper having an input part (102) and an output part (116) with a common axis of rotation (118) about which the input part (102) and the output part (116) rotatable together and limited relative to each other rotatable and a spring damper device operative between the input member (102) and the output member (116), the input member (102) being a cup-shaped input flange member (104) having a flange bottom portion (106) and a flange wall portion (108) and A diaphragm cover member (110), wherein the diaphragm cover member (110) has a cup-like shape with a diaphragm bottom portion (112) and a diaphragm wall portion (114) to structurally and / or functionally enhance the torsional vibration damper.

Description

The invention relates to a torsional vibration damper, in particular two-mass flywheel, the torsional vibration damper having an input part and an output part with a common axis of rotation about which the input part and the output part rotatable together and rotatable relative to each other limited, and effective between the input part and the output part spring damper Means, wherein the input part comprises a cup-like shaped Eingangsflanschteil with a flange bottom portion and a flange wall portion and a diaphragm cover part.

From the registered on 08.12.2015 German patent application with the file number 10 2015 224 505.5 is a torsional vibration damper, in particular two-mass flywheel of the torsional vibration damper comprising an input part and an output part having a common axis of rotation about which the input part and the output part rotatable together and rotatable relative to each other are limited, and an effective between the input part and the output part spring-damper device with at least one spring, wherein the input part has a shell-like shape and the output part has a lid-like shape and the input part and the output part define a receiving space for the at least one spring, in which a resilient sealing device is arranged between the input part and the output part.

The from the on 08.12.2015 registered German patent application with the file number 10 2015 224 505.5 Known sealing device has at least one sealing element and at least one support element. The at least one sealing element has a ring-like shape, radially on the outside a connecting portion assigned to the input part, and radially on the inside a sealing portion assigned to the supporting element and / or the output part. The at least one sealing element is made of a membrane-like material and executed plate spring-like. The at least one support element is connected to the output part lubricant-tight and axially supported on the output part. Between the at least one support element and the input part, a sealing gap is formed. The at least one sealing element is connected to the input part lubricant-tight and sealingly abuts the at least one support element to form a sealing mating. The sealing device acts on the output part with a spring force axially in the direction of the input part.

For more detailed information about the features of the present invention is expressly applied for on 08.12.2015 German patent application with the file number 10 2015 224 505.5 directed. The teaching of this patent application is to be regarded as part of the present document. Features of this patent application are features of the present document.

From the on 22.12.2016 registered German patent application with the file number 10 2016 125 386.3 is a torsional vibration damper, in particular two-mass flywheel, the torsional vibration damper having an input part and an output part with a common axis of rotation about which the input part and the output part rotatable together and rotatable relative to each other limited, effective between the input part and the output part spring-damper device and an inner space, wherein the input part has a membrane lid part and the membrane lid part extends radially at least over a predominant part of the inner space. It is proposed to weld the membrane cover part with its outer edge to the wall portion of the Eingangsflanschteils.

The invention has for its object to improve a torsional vibration damper mentioned structurally and / or functionally.

The object is achieved with a torsional vibration damper with the features of claim 1. Advantageous embodiments are the subject of the dependent claims.

The torsional vibration damper may be designed as a dual mass flywheel. The torsional vibration damper may be for placement in a drive train of a vehicle. The drive train may include a prime mover. The prime mover may be an internal combustion engine. The internal combustion engine may have a crankshaft. The powertrain may include a friction clutch device. The powertrain may include a hydrodynamic torque converter. The drive train may have a transmission. The drive train may have at least one drivable vehicle wheel. The drive train may have an accessory drive. The torsional vibration damper can be used for mounting on a crankshaft, on a friction clutch device, on a torque converter or on an accessory drive.

The terms "input part" and "output part" refer to a line flow direction originating from an engine. Unless stated otherwise or not otherwise determined from the context, the statements "axially", "radially" and "in the circumferential direction" refer to an extension direction of the axis of rotation. " Axial "then corresponds to an extension direction of the axis of rotation. "Radial" is then a direction perpendicular to the direction of extension of the axis of rotation and intersecting with the axis of rotation direction. "In the circumferential direction" then corresponds to a circular arc direction about the axis of rotation.

The input part and / or the output part can / can be made of a sheet metal. The input part and / or the output part can / can be produced in a punch-forming method. The input part and / or the output part can / can be produced by plastic deformation.

The spring-damper device may comprise at least one bow spring. The at least one bow spring can be supported on the one hand on the input part and on the other hand on the output part. The at least one bow spring may be a coil spring. The at least one bow spring may be a compression spring. The spring-damper device may have a plurality of bow springs. The plurality of bow springs may be arranged in series. The plurality of bow springs may be arranged in parallel. The at least one bow spring can serve as a mechanical energy storage. The at least one bow spring can store mechanical energy when the input part and the output part are rotated against a spring force of the at least one bow spring relative to each other. The at least one bow spring can turn the input part and the output part back relative to one another using the stored mechanical energy.

The flange bottom portion may extend substantially radially. The flange wall portion may extend substantially axially. The membrane bottom portion may extend substantially radially. The membrane wall portion may extend substantially axially.

The torsional vibration damper may have an interior. The entrance flange portion and the diaphragm cover portion may confine the interior space. The flange bottom portion and the diaphragm bottom portion may laterally bound the interior space axially. The flange wall portion and the diaphragm wall portion may define the inner space radially outside.

The torsional vibration damper may have a receiving space for the at least one bow spring. The receiving space may have a toroidal shape. The receiving space may be arranged radially on the outside in the interior. The interior can continue to extend radially inwards starting from the receiving space.

The output part may have an inner part and an outer part. The inner part may extend substantially radially. The inner part may have an annular disk-like shape. The inner part can be arranged in the interior. The inner part may be arranged axially between the Eingangsflanschteil and the diaphragm cover part. The outer part may extend substantially radially. The outer part may have an annular disk-like shape. The outer part can be arranged outside the interior. The outer part can be arranged axially on the outer part on the output side. The inner part and the outer part can be firmly connected to each other, in particular riveted, be. The outer part may have an inner surface facing the inner part in the axial direction. The outer part may have holes for the passage of / on connecting means, such as rivets and / or screws.

The Eingangsflanschteil may comprise at least one projecting into the receiving space supporting portion for the at least one bow spring. The inner part of the output part may have at least one support section projecting into the receiving space for the at least one bow spring. The at least one bow spring can be supported on the one hand on the at least one support portion of the Eingangsflanschteils and on the other hand on the at least one support portion of the inner part.

The torsional vibration damper may have a bearing device for mutually rotatable mounting of the input part and the output part. The bearing device may have a roller bearing, in particular ball bearings or needle roller bearings. The bearing device may have a plain bearing. The input flange part may have a dome portion directed axially toward the output part. The outer part of the output part may have an axially directed to the input part towards the dome portion. The bearing device can be arranged on the dome sections.

The membrane wall portion may have a hollow cylindrical shape. The flange wall portion may have a hollow cylindrical shape. The diaphragm wall portion and the flange wall portion may be concentric with each other. The membrane wall section can engage around the flange wall section radially on the outside. The membrane cover part may be pushed with its membrane wall portion on the flange wall portion. The input flange part and the membrane cover part can be connected to one another in a force-locking manner, in particular by frictional engagement. The input part may have a ring part. Of the Membrane wall portion may be disposed radially between the flange wall portion and the ring member. The membrane wall portion may be clamped radially between the flange wall portion and the ring portion. The ring part can be shrunk. The ring member may have an external toothing. The external toothing can be used for engagement with a toothed wheel of a starter for starting an internal combustion engine. The ring member may be disposed on the input flange part axially output part side. The membrane cover part can be supported with its membrane inner edge on the outer part.

The spring-damper device may comprise a friction device. The friction device may have a friction ring. The friction ring can be arranged on the inner part. The friction device may comprise a spring ring. The spring ring can be performed plate spring-like. The friction device may have a support disk. The support disk can be arranged on the input flange part. The spring ring can be supported on the one hand on the friction ring and on the other hand on the support disk. The spring ring can be biased.

In summary, and in other words thus results in the invention, inter alia, a diaphragm cover with sprocket or a clamp using a clamping ring. A membrane may be potted outside and pushed onto a primary flywheel. Thereafter, the ring gear or alternatively a clamping ring can be shrunk onto the membrane and clamp the membrane against the primary flywheel. Sprocket or clamping ring can be placed further on the transmission side and improve bursting strength.

With the torsional vibration damper according to the invention a cost, such as manufacturing costs, is reduced. A cohesive connection, such as weld, can be omitted. Operational safety can be increased. Bursting strength can be increased.

An embodiment of the invention will be described in more detail with reference to a figure. From this description, further features and advantages. Concrete features of this embodiment may represent general features of the invention. Features associated with other features of this embodiment may also represent individual features of the invention.

1 shows schematically and exemplarily a dual mass flywheel 100 with an entrance part 102 , which is a cup-shaped entrance flange part 104 with a flange bottom section 106 and a flange wall portion 108 and a cup-shaped membrane lid portion 110 with a membrane bottom section 112 and a membrane wall portion 114 having.

The dual mass flywheel 100 serves for arrangement in a drive train of a motor vehicle between an internal combustion engine and a friction clutch. The dual mass flywheel 100 serves to dampen rotational irregularities in the drive train. Such rotational irregularities can be excited in particular by the internal combustion engine and / or a transmission.

The dual mass flywheel 100 has the entrance part 102 and an output part 116 with a common axis of rotation 118 on. The entrance part 102 and the starting part 116 are about the axis of rotation 118 rotatable together and limited rotatable relative to each other.

The flange bottom section 106 of the input flange part 104 extends substantially radially, the flange wall portion 108 extends from the flange bottom portion 106 essentially axially. The membrane lid part 110 is designed like a membrane and / or plate spring. The membrane bottom section 112 of the membrane lid part 110 extends substantially radially, the membrane wall portion 114 extends from the diaphragm bottom section 112 essentially axially. The flange wall section 108 and the membrane wall portion 114 are directed towards each other. The dual mass flywheel 100 has an interior 120 on. The interior 120 is from the input flange part 104 and the membrane lid part 110 limited.

The starting part 116 has an inner part 122 and an outdoor part 124 on. The inner part 122 and the outer part 124 each extend substantially radially and each have an annular disk-like shape. The inner part 122 is in the interior 120 axially between the input flange part 104 and the membrane lid part 110 arranged. The outer part 116 is outside the interior 120 axially on the output side of the outer part 116 arranged. The inner part 122 and the outer part 116 are riveted together. The outer part 116 has in the axial direction a side facing the inner part side surface 125 on. The outer part 116 has holes, such as 126, for the passage of / on screws 128 on.

The membrane wall section 114 and the flange wall portion 108 each have a hollow cylindrical shape with corresponding diameters. The membrane wall section 114 and the flange wall portion 108 lie concentrically against each other. The membrane wall section 114 surrounds the flange wall section 108 radially outside. The membrane lid part 110 is with its membrane wall section 114 on the flange wall section 108 postponed. The Eingangsflanschteil 104 and the membrane lid part 110 are positively connected with each other.

The entrance part 102 has a shrunk ring part 130 with an external toothing on. The membrane lid part 110 is with its membrane wall section 114 radially between the flange wall portion 108 and the ring part 130 trapped and held tight. The ring part 130 is at the entrance flange part 104 arranged axially output part side. The membrane lid part 110 rests with its inner membrane edge 132 on the side surface 125 of the outer part 124 from.

The two-mass swing wheel 100 has a friction device with a friction ring 134 , a spring washer 136 and a support disk 138 on. The friction ring 134 is radially inward on the inner part 122 arranged. The support disk 138 is at the entrance flange part 104 arranged. The spring ring 136 is supported on the one hand on the friction ring 134 and on the other hand on the support disk 138 from.

LIST OF REFERENCE NUMBERS

100

Dual Mass Flywheel

102

introductory

104

Eingangsflanschteil

106

Flanschbodenabschnitt

108

Flanschwandabschnitt

110

Membrane cover part

112

Membrane bottom portion

114

Diaphragm wall section

116

output portion

118

axis of rotation

120

inner space

122

inner part

124

outer part

125

side surface

126

hole

128

screw

130

ring part

132

Membrane inner edge

134

friction ring

136

spring washer

138

support disc

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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.

Cited patent literature

• DE 102015224505 [0002, 0003, 0004]
• DE 102016125386 [0005]

Claims (10)

A torsional vibration damper, in particular a dual-mass flywheel (100), the torsional vibration damper having an input part (102) and an output part (116) with a common axis of rotation (118) about which the input part (102) and the output part (116) rotatable together and limited relative to each other rotatable and a spring damper device operative between the input member (102) and the output member (116), the input member (102) being a cup-shaped input flange member (104) having a flange bottom portion (106) and a flange wall portion (108) and A diaphragm cap part (110), characterized in that the diaphragm cap part (110) has a cup-like shape with a diaphragm bottom portion (112) and a diaphragm wall portion (114). Torsional vibration damper after Claim 1 characterized in that the diaphragm wall portion (114) and the flange wall portion (108) are concentric with each other. Torsional vibration damper according to at least one of the preceding claims, characterized in that the membrane wall portion (114) surrounds the flange wall portion (108) radially on the outside. Torsional vibration damper according to at least one of the preceding claims, characterized in that the membrane cover part (110) with its diaphragm wall portion (114) is pushed onto the flange wall portion (108). Torsional vibration damper according to at least one of the preceding claims, characterized in that the Eingangsflanschteil (104) and the diaphragm cover part (110) are positively connected with each other. Torsional vibration damper according to at least one of the preceding claims, characterized in that the input part (102) has a ring part (130) and the membrane wall portion (114) is arranged radially between the flange wall portion (108) and the ring part (130). Torsional vibration damper after Claim 6 , characterized in that the ring member (130) is shrunk. Torsional vibration damper according to at least one of Claims 6 to 7 , characterized in that the ring part (130) has an external toothing. Torsional vibration damper according to at least one of the preceding claims, characterized in that the output part (116) has an inner part (122) and an outer part (124) and the membrane cover part (110) has a membrane inner edge (132) and the membrane cover part (110) with its membrane inner edge (132) on the outer part (124) is supported. Torsional vibration damper after Claim 9 , characterized in that the spring-damper device comprises a friction device with a friction ring (134), a spring ring (136) and a support ring (138).

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