DE102012221935A1 - Belleville spring for torque transmission device used for drive train of motor vehicle disc spring used in dual-mass flywheel, has base which is deviated from conical shape of base deformation portion - Google Patents

Abstract

The spring (10) has annular base (11) which is provided with a radially inner edge portion (12) and a radially outer edge portion (13), and is formed conical in shape. The base is deviated from the conical shape of the base deformation portion. The annular peripheral deformation portions (14,15) are radially spaced from each other.

Description

The invention relates to a plate spring, in particular for a torque transmission device.

In particular, in torque transmission devices for the drive train of a motor vehicle disc springs are used to cause a distortion of two components or a force application of a component. Disc springs can be used in two-mass flywheels or clutch discs. Also disc springs can be used in engine or torsional vibration dampers. Other applications include pulley decouplers and belt tensioners.

In this case, a plate spring on a base body with an annular shape, which is conically placed or potted, so that a conical annular shell is formed. The stiffness of the disc spring and / or the cup spring force is determined by the dimensions of radially inner edge and radially outer edge and the material thickness of the disc spring. Thus, depending on the application, the plate spring can be dimensioned so that the desired cup spring force results. If an increased Belleville spring force is desired for a given geometry, this is usually accomplished by increasing the material thickness, thereby providing greater rigidity, which increases Belleville spring force. As a result, however, more material is used, which makes the plate spring more expensive. Alternatively, another stiffer material can be selected, but this is usually also associated with price disadvantages.

Therefore, it is the object of the invention to provide a plate spring, which is improved in its Belleville spring force and yet easy and inexpensive to manufacture.

The object is achieved by a plate spring with the features of claim 1.

An embodiment of the invention provides a disc spring, with an annular base body and a radially inner edge region and a radially outer edge region, wherein the base body is conically positioned, characterized in that the base body has at least one deviating from the conical body deformation. The deformation between the radially inner and the radially outer edge region is formed, so that a higher rigidity of the base body is effected.

It is particularly advantageous if the plate spring is designed such that the at least one deformation is formed annularly encircling. Circumferentially encircling means circumferentially around the annular base body, wherein between closed ring circumferentially, so without interruption, and open ring circumferentially with at least one interruption can be distinguished.

It is particularly advantageous if the main body has two deformations, which are in each case formed in an annular manner. In this case, one deformation is arranged adjacent to the radially inner edge region and the other deformation is arranged adjacent to the radially outer edge region. The arrangement of two or more deformations in the base body between the radially inner and outer edge region, a further increase in the stiffness of the body can be effected.

It is particularly advantageous if the two annular circumferential deformations are arranged radially spaced from each other. It is advantageous if the deformations differ with respect to the sectional plane of the base body of this in different directions. Thus, with two deformations, one deformation may deviate in one direction and the other deformation in the other direction.

Furthermore, it is advantageous if at least one of the deformations is a deviation of the base body from the conical three-dimensional surface.

It is also advantageous if the deformation is a substantially linear deviating from the conical three-dimensional surface angled or projecting contour.

It is also expedient if the annular circumferential deformation is a closed circumferential contour. Alternatively or additionally, it is expedient if the annular circumferential deformation is a circumferential contour, which is formed open by at least one interruption.

It is also expedient if a deformation is an angled or protruding embossing of the main body. As a result, the at least one deformation can be easily introduced into the main body.

It is advantageous if, viewed in section, the basic body has a contour deviating from a straight line. This increases the rigidity of the diaphragm spring, so that instead of a material thickening or expansion of the diaphragm spring between the radially inner and the radially outer edge region can be avoided or reduced.

The present invention will be explained in more detail below with reference to preferred exemplary embodiments in conjunction with the associated figures:

Showing:

1 a three-dimensional view of a plate spring according to the prior art,

2 a plan view of a diaphragm spring according to the prior art,

3 a section of the diaphragm spring according to the prior art,

4 a three-dimensional view of a plate spring according to the invention,

5 a top view of a plate spring according to the invention,

6 a section of a plate spring according to the invention,

7 a section of a plate spring according to the invention,

8th a section of a plate spring according to the invention,

9 a section of a plate spring according to the invention, and

10 a section through a plate spring according to the invention.

The 1 shows a plate spring 1 with an annular base body 2 with a radially inner edge region 3 and a radially outer edge region 4 , where the main body 2 is conically positioned.

The 2 shows the plate spring 1 in a supervision and the 3 shows a section through the plate spring 1 according to line II. It can be seen that the plate spring 1 a basic body 2 which is conical, but the main body 2 is smooth, ie that the basic body 2 flat straight and parallel opposite side walls 5 . 6 has, when you cut in 3 considered.

The 4 to 6 show a disc spring according to the invention 10 with an annular base body 11 with a radially inner edge region 12 and a radially outer edge region 13 ,

The main body 11 is conical, so that the main body 11 take an angle to the plane 16 that is defined by the radially inner edge region or to the plane 17 that can be described the radially outer edge region.

Furthermore, the main body 11 at least one deformation, in the embodiment of 4 to 6 but two deformations 14 . 15 on, with the plate spring 10 in the area of deformations 14 . 15 from the conical shape of the body 11 differs.

In the embodiment of 6 gives way to the deformation 14 from the imaginary ideal flat body 11 in the direction of the plane which is definable by the radially outer edge region, wherein the deformation 15 deviates in the direction with respect to the plane which is definable by the radially inner edge region. This means that the two deformations 14 . 15 in opposite directions from an ideal conical course of the body 11 differ.

It can deformations 14 . 15 be considered as annular circumferential deformations. In the 4 and 5 it can be seen that the deformations 14 . 15 are annular deformations formed circumferentially, the two deformations 14 . 15 are each arranged on a different radial diameter and are thus arranged radially spaced from each other and adjacent to each other. The ring-shaped deformations 14 . 15 may be closed deformations, so that the respective deformation is completely circumferential. Alternatively, a deformation may also be regarded as incompletely circumferential, so that the deformation has an interruption at least at one point of the circumference of the main body. In this case, an annular circumferential, open deformation would be given.

Depending on the exemplary embodiment, the at least one deformation may be a closed circumferential deformation, or an open circumferential deformation. In the presence of more than one deformation, any deformation may be of the open-circuit type or any deformation may be of the closed-circuit type. Alternatively, a mixture of the two types may also be present, such that at least one deformation of the open-revolving type and at least one deformation of the closed revolving type is present.

In the case of open circumferential deformations, the open region (s) of the interruption (s) in the case of a plurality of deformations may be arranged at the same angular range with respect to the circumference of the disc spring. alternative the interruptions can also be arranged offset to one another.

It is advantageous if the deformations are introduced as embossings in the base body, wherein in the embodiment of the 4 to 6 the two imprints cause the deformation 14 in a different direction from the course of the body 11 deviates as the deformation 15 ,

The 7 shows a section through the main body of a plate spring 20 , where the conical body areas 21 . 22 and 23 in which the basic body 20 seen in section has a substantially straight extension, wherein the deformations 24 and 25 a deviation of the basic body 20 from the conical course of the body 20 cause. Here is the deformation 24 in the presentation of the 7 formed in one direction, that is, upwards, deviating, wherein the deformation 25 in the opposite direction, that is down, deviating formed. In the embodiment of 7 the deformations are introduced as almost triangular imprints. Alternatively, arcuate embossments can be introduced.

The 8th also shows a basic body in section 30 a diaphragm spring, the areas 31 and 32 represent a straight conical shape and the areas 33 and 34 as deformations between the areas 31 and 32 are arranged and merge into each other.

Here are the areas 33 and 34 arcuately formed and represent an arcuate deformation, which depends on the conical shape of the body in the areas 31 and 32 differ. This shows the deformation 33 in one direction with respect to the main body, the deformation 34 deviates in the opposite direction.

The 9 also shows a basic body 40 a diaphragm spring in section, with a central area 41 is shown as a conically trained straight course. This is in the embodiment of 9 the middle region of the plate spring, wherein in the two end regions 42 and 43 an arcuate deformation is present, so that in the areas 42 and 43 the course of the diaphragm spring from the conical shape of the body 40 differs. The direction of the expression of the deformation 44 is again opposite to the direction of the expression of the deformation 45 so that the deformation 44 in the 9 in one direction, ie deviates upwards from the conical course of the body and the deformation 45 in the 9 down, so deviates in the other direction.

The deviations of the deformations 24 . 25 . 33 . 34 and 44 . 45 are each directed opposite. Embodiments are also conceivable in which the deformations of a disc spring are aligned in the same direction, so that, for example, the deformations 24 . 25 designed so that they both in the one, eg upper direction show. The same is true for the embodiments of 8th and 9 just as conceivable.

The 10 shows a further section through an embodiment of a disc spring according to the invention 50 , The plate spring 50 has an annular body 56 on, extending in the radial direction substantially in three areas 51 . 52 and 53 subdivided. The areas 51 . 52 and 53 close to each other from radially outside to radially inside, the areas 52 and 53 through the deformation 54 and the areas 51 and 53 through the deformation 55 are separated from each other.

Here are the areas 51 and 52 at the radially inner edge and at the radially outer edge of the base body 56 as viewed in section straight parallel to each other aligned areas 51 . 52 formed, each lying in a plane or on a straight line, which are aligned parallel to each other and offset from each other.

The offset of the two levels or the two areas 51 . 52 is in 10 represented such that the width of the areas 51 respectively. 52 each value is s, while the total width of area 51 to area 52 is the value t. The value t is thus the sum of the width s plus the offset v.

The offset v is thereby achieved that the range 53 to the areas 51 and 52 is at an angle, wherein the angle α1 is the angle between the area 51 to the area 53 and the angle α2 is the angle between the area 52 and the area 53 , where the area 53 as a straight area inclined between the two areas 51 and 52 extends.

The deformations 54 and 55 are thus bends of the main body of the diaphragm spring.

Furthermore, it is conceivable that only one deformation is formed annularly circumferential or that more than two deformations are formed annularly encircling. Thus, for example, it can also be provided that three, four or more deformations are formed annularly circumferential, wherein the orientation of the deformations are aligned in the same direction or alternately in the opposite direction or in groups the same and in groups opposite.

LIST OF REFERENCE NUMBERS

1

 Belleville spring

2

 body

3

 border area

4

 border area

5

 Side wall

6

 Side wall

10

 Belleville spring

11

 body

12

 border area

13

 border area

14

 deformation

15

 deformation

16

 level

17

 level

20

 Belleville spring

21

 Area

22

 Area

23

 Area

24

 deformation

25

 deformation

30

 body

31

 Area

32

 Area

33

 Area

34

 Area

40

 body

41

 Area

42

 end

43

 end

44

 deformation

45

 deformation

50

 Belleville spring

51

 Area

52

 Area

53

 Area

54

 deformation

55

 deformation

56

 body

Claims (10)

Disc spring ( 20 ) with an annular base body ( 21 ) and a radially inner edge region and a radially outer edge region, wherein the main body ( 21 ) is conically positioned, characterized in that the basic body ( 21 ) at least one deviating from the conical shape of the body deformation ( 24 . 25 ) having. Disc spring ( 20 ) according to claim 1, characterized in that at least one deformation ( 24 . 25 ) is formed annularly circumferentially. Disc spring ( 20 ) according to claim 2, characterized in that the basic body ( 21 ) two deformations ( 24 . 25 ), which are each formed annularly circumferentially. Disc spring ( 20 ) according to claim 3, characterized in that the two annular circumferential deformations ( 24 . 25 ) are arranged radially spaced from each other. Disc spring ( 20 ) according to claim 1, 2, 3 or 4, characterized in that at least one of the deformations ( 24 . 25 ) a deviation of the basic body ( 21 ) is from the conical three-dimensional surface. Disc spring ( 20 ) according to claim 5, characterized in that the deformation ( 24 . 25 ) is an essentially line-shaped angled or projecting contour deviating from the conical three-dimensional surface. Disc spring ( 20 ) according to at least one of the preceding claims, characterized in that the annular circumferential deformation ( 24 . 25 ) is a closed circumferential contour. Disc spring ( 20 ) according to at least one of the preceding claims, characterized in that the annular circumferential deformation ( 24 . 25 ) is a circumferential contour which is open by at least one interruption. Disc spring ( 20 ) according to at least one of the preceding claims, characterized in that a deformation ( 24 . 25 ) an angled or protruding embossing of the main body ( 21 ). Disc spring ( 20 ) according to at least one of the preceding claims, characterized in that the basic body ( 21 ) seen in section has a deviating from a straight line contour.

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