KR102090212B1 - A Torsional Damper - Google Patents

Abstract

The present invention is to the first retaining plate 101 by the first retaining plate 101 and a plurality of engaging members 115 that are spaced apart along the circumferential direction facing the first retaining plate 101. A plurality of coil springs which are arranged along the circumferential direction on the second retaining plate 103 and the first retaining plate 101 and the second retaining plate 103 to be coupled, and , A driven plate 105 provided between the first retaining plate 101 and the second retaining plate 103 and elastically supported by the plurality of compression springs to receive a reaction force in a rotational direction, and the driven plate 105 ) Is coupled to the spline hub 113 for transmitting the driving force;
The driven plate 105 is spaced apart in the circumferential direction and is provided with a driven stopper portion 1051 that protrudes outward in the radial direction and extends between the coupling members 115, and the coupling member 115 together with the driven stopper parts 1051 It relates to a torsional damper 100 acting as a stopper to prevent overcompression of the coil spring.

Description

A Torsional Damper}

The present invention is disposed between the engine and the transmission of the vehicle while absorbing vibration while preventing the coil spring from being over-compressed in the damper operating section and alleviating the shock generated by the stopper to prevent the deformation or damage of the stopper to the torsional damper. It is about.

In general, the torsional damper is installed between the engine of the vehicle and the transmission to attenuate the torsional vibration generated during the power transmission process. The torsional damper includes a first mass body, a second mass body, and a damping unit. The first mass is connected to the output shaft of the engine, and the second mass is connected to the input shaft of the transmission. A cover plate is coupled to the first mass body to provide a space therein, a damper unit is provided in this space, and oil is filled. The damper unit is for absorbing vibration and shock generated in the circumferential direction and includes a plurality of coil springs. The second mass body may include a spline hub coupled to the input shaft of the transmission, and a driven plate coupled to the spline hub by riveting.

This conventional torsional damper absorbs vibration and shock in the rotational direction in the damper unit, and in a certain section, the operation of the damper unit is stopped by the stopper. Therefore, the conventional torsion damper is suddenly stopped by the stopper when stopping the operation of the damper unit. Since the operation of the damper unit is stopped, there is a problem that the noise vibration of the vehicle is increased.

1 is a half sectional view of a conventional torsional damper. 1, the torsional damper includes an inertial plate 1, a cover plate 3, a first retaining plate 5, a second retaining plate 7, a plurality of compression coil springs 9, It includes a driven plate 11 and a spline hub 13.

The inertial plate 1 is connected to the output shaft of the engine and receives the driving force of the engine. The inertial plate 1 is made of a mass body having a certain load or more. The inertial plate 1 is coupled to the cover plate 3 to provide a space for receiving oil therein.

The cover plate 3 is coupled to the inertial plate 1, the ring gear R is coupled to the outer circumferential side of the inertial plate 1, and the cover plate 3 is coupled to the ring gear R while the inertial plate ( A space is provided between 1) and the cover plate 3. The ring gear R also acts as a mass.

The first retaining plate 5 and the second retaining plate 7 are provided facing each other and coupled to the inertial plate 1 by means of rivets, which are fastening means. A plurality of coil springs 9 are arranged on the first retaining plate 5 and the second retaining plate 7 along the circumferential direction. The first retaining plate 5 and the second retaining plate 7 act as driving elements of the plurality of coil springs 9. The plurality of coil springs 9 are arranged in the circumferential direction to absorb vibration and shock in the rotational direction. For more shock absorption, the coil springs 9 are arranged in series along the circumferential direction in pairs of two.

A connecting plate 17 is disposed on the outer circumference of the driven plate 11. The connecting plate 17 is formed of a ring-shaped plate, and extending portions 17a protruding from a portion extending in a rotational center direction are provided at regular intervals. In addition, an extension portion 17a of the connecting plate 17 is disposed between the coil springs 9 arranged in pairs. The extending portion 17a of the connecting plate 17 serves to support the coil springs 9, which are paired in pairs, to be arranged in series. The connecting plate 17 is made of metal or synthetic resin material. The plurality of coil springs 9 exert an elastic force in the rotational direction of the driven plate 11. The driven plate 11 acts as a driven element of the plurality of coil springs 9 and is coupled to the spline hub 13 by fastening means such as rivets. The driven plate 11 is provided with a space at regular intervals along the circumferential direction, and a plurality of coil springs 9 described above are arranged in series in this part. On the other hand, the outer peripheral surface side of the driven plate 11 is provided with an inclined portion 11a at regular intervals. And the inclined portion 11a provided on the driven plate 11 is provided in the damper operation section, and inclined in a direction away from the center of rotation when viewed based on the direction in which the damper is operated. The driven plate 11 forms an inclined surface in a section forming a height difference in the damper operation section, that is, the extension portion 17a of the connecting plate 17 moves along the inclined portion 11a of the driven plate 11 While the damper operation is made, the movement of the connecting plate 17 is gradually restricted by the inclined surface of the inclined portion 11a.

In the structure as described above, since it is buffered by sliding contact, tolerance management is difficult and manufacturing is difficult.

Republic of Korea Registration No. 10-1195945 Registered Patent Publication

The present invention has been proposed to solve the problems of the prior art as described above, the shock applied to the stopper is smoothly mitigated, easy to manufacture, and to provide a torsional damper for easy replacement of parts when damaged The purpose.

For the above purposes, the present invention is a second retaining plate and a second retaining plate coupled to the first retaining plate by a plurality of engaging members spaced apart along the circumferential direction facing the first retaining plate A plurality of coil springs arranged along the circumferential direction on the plate, the first retaining plate and the second retaining plate to absorb vibration and shock in the rotational direction, and between the first retaining plate and the second retaining plate It is provided and includes a driven plate elastically supported by the plurality of compression springs to receive a reaction force in a rotational direction, and a spline hub coupled to the driven plate to transmit driving force; The driven plate is spaced apart in the circumferential direction and has a radially outwardly projecting driven stopper portion extending between the coupling members, and the coupling member together with the driven stopper portion provides a torsional damper that acts as a stopper to prevent overcompression of the coil spring. do.

In the above, on the radially outer side of each coupling member, both sides of the axial direction are provided with shock absorbing members coupled to the first retaining plate and the second retaining plate, and the driven stopper part is in contact with the shock absorbing member before contacting the shock absorbing member. It is characterized by being relaxed.

In the above, the shock absorbing member extends across both circumferential ends of the coupling member in both circumferential directions and has a radially outwardly inclined shock absorbing part, and when the driven stopper part approaches the coupling member, the radially outer end contacts the inner surface of the shock absorbing part and the shock absorbing part It is characterized in that the shock is alleviated as it deforms radially outward.

In the above, the first retaining plate is spaced along the circumferential direction to form a plurality of first retaining coupling portions through the axial direction, the second retaining plate is spaced along the circumferential direction, and each of the first retaining coupling portions A plurality of second retaining engaging portions facing each other are formed through the axial direction; The coupling member is provided with coupling member insertion portions that are inserted into and coupled to the first retaining coupling portion and the second retaining coupling portion on both sides in the axial direction; The buffer member is provided with buffer coupling portions on both sides in the axial direction, and the buffer coupling portion is inserted into and coupled to the first retaining coupling portion and the second retaining coupling portion together with the coupling member insertion portion.

In the above, the shock absorbing portion is radially outwardly bent at a position spaced inwardly from the circumferential end of the coupling member and extends inclinedly, and radially outward at an angle smaller than the first shock absorbing portion at the end of the first buffer portion. It is characterized in that it consists of a second buffer portion is bent and extended inclined.

In the above, each of the first retaining coupling portion and the second retaining coupling portion is made of a through hole formed in a pair in parallel; The coupling member is composed of a coupling member body that is a hexahedron and a coupling member insertion portion protruding in the axial direction in pairs, spaced apart in a tangential direction on both sides of the coupling member body; The buffer member is composed of a buffer member body of a rectangular plate, and a buffer coupling portion spaced in a tangential direction on both sides in the axial direction of the buffer member body and protruding in the axial direction; The buffer member is stacked on the radially outer surface of the coupling member, and the buffer coupling part stacked on the radially outer side of the coupling member insertion portion and the coupling member insertion portion is the first retaining coupling portion and the second retaining coupling portion on both sides in the axial direction. Being inserted; The coupling member insertion portion protrudes past the first retaining coupling portion and the second retaining coupling portion at both sides in the axial direction and the protruding end is deformed to prevent separation from the first retaining coupling portion and the second retaining coupling portion It is characterized by being formed of a member coupling portion.

The torsional damper according to the present invention can alleviate the shock generated when the driven stopper forming the stopper and the coupling member contact each other with a simple installation structure.

1 is a half cross-sectional view of a conventional torsional damper cut in the axial direction,
Figure 2 is a half cross-sectional view of the torsional damper of the present invention cut in the axial direction,
Figure 3 is shown in the direction A of Figure 2, showing a state in which the first retaining plate is removed to clearly describe the present invention,
Figure 4 is a schematic perspective view showing an enlarged portion "A" of Figure 3,
5 is a perspective view showing a rivet coupling the first retaining plate and the second retaining plate in the torsional damper of the present invention,
FIG. 6 is an enlarged view of a portion “A” of FIG. 3 illustrated to explain the operation of the torsional damper of the present invention.

Hereinafter, the torsional damper according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a sectional view of the torsional damper of the present invention cut in the axial direction, and FIG. 3 is a view from the direction A of FIG. 2 and shows a state in which the first retaining plate is removed to clearly explain the present invention. One is, Figure 4 is a schematic perspective view showing an enlarged portion "A" of Figure 3, Figure 5 is a perspective view showing a rivet coupling the first retaining plate and the second retaining plate in the torsional damper of the present invention 6 is an enlarged view of a portion “A” of FIG. 3 illustrated to illustrate the operation of the torsional damper of the present invention.

In the description, a description will be given focusing on the configuration related to the present invention, and the inertial body, an inertial plate, and a ring gear may also be provided in the torsional damper of the present invention, but the description thereof will be omitted. And the horizontal direction of FIG. 2 is described in the axial direction.

The torsional damper 100 according to the present invention is made of a first retaining plate 101 and a plurality of engaging members 115 facing the first retaining plate 101 and spaced apart along the circumferential direction. 1 The second retaining plate 103 coupled to the retaining plate 101 and the first retaining plate 101 and the second retaining plate 103 are disposed along the circumferential direction and vibrate and impact in the rotational direction It is provided between the plurality of coil springs 107 for absorbing, and the first retaining plate 101 and the second retaining plate 103 and is elastically supported by the plurality of compression springs to receive a reaction force in a rotational direction. It includes a plate 105 and a spline hub 113 coupled to the driven plate 105 to transmit driving force.

The first retaining plate 101 constituting the present invention is connected to an inertial plate (not shown) coupled to the output shaft of the engine to rotate integrally, and the spline hub 113 is a transmission (not shown) of the engine It transmits the driving force.

The coupling member 115 is provided with one side in the axial direction coupled to the first retaining plate 101 and the other side in the axial direction coupled to the second retaining plate 103. The coupling member 115 is provided coupled to the outer edge of the radial direction of the first retaining plate 101 and the second retaining plate 103, the coil spring 107 is a radius from the coupling member 115 The first retaining plate 101 and the second retaining plate 103 are disposed along the circumferential direction at positions spaced apart in the direction.

The driven plate 105 may be installed on the spline hub 113 to be integrally rotated by being coupled to the rivet, and spline-coupled to be integrally rotated. The driven plate 105 is provided with a plurality of driven stopper portions 1051 spaced apart in the circumferential direction and projecting radially outwardly and extending between the coupling members 115. The driven stopper portion 1051 is spaced apart from the coupling members 115 on both sides of the circumferential direction.

The rotational force is transmitted through the output shaft of the engine so that the first retaining plate 101 and the second retaining plate 103 rotate, and the coil spring 107 is compressed by the inertia and acts as a stopper. And the driven stopper portion 1051 on one side of the circumferential direction of the coupling member 115 is in contact, the coil spring 107 is further prevented from being compressed.

As shown in FIG. 2, the torsional damper 100 of the present invention may be configured to further include a second driven plate 109 and a second coil spring 111. When the second driven plate 109 and the second coil spring 111 are further included, the second coil spring 111 is radially inwardly spaced from the coil spring 107 and spaced along the circumferential direction to be provided in plural. do. The second driven plate 109 is coupled by a spline hub 113 and a rivet or the like to be integrally rotated. At this time, the driven plate 105 is rotatably provided on the spline hub 113, and the second coil spring 111 is elastically supported between the driven plate 105 and the second driven plate 109. And when the rotational force is transmitted through the output shaft of the engine, the first retaining plate 101 and the second retaining plate 103 rotate and the rotational force is driven plate 105, coil spring 107, and second coil spring 111 ) And as shock and vibration are absorbed through the second driven plate 109, it is transferred to the spline hub 113.

In the present invention, since the coupling member 115 acts as a stopper to prevent overcompression of the coil spring together with the driven stopper portion 1051, there is no need to provide a separate configuration for the stopper, so the structure is simplified. have.

The torsional damper 100 of the present invention is a buffer member 117 coupled to the first retaining plate 101 and the second retaining plate 103 on both sides in the axial direction on the radially outer side of each coupling member 115. ) Is provided, and the driven stopper portion 1051 is in contact with the cushioning member 117 before contacting the coupling member 115 to alleviate the impact. The plurality of shock absorbing members 117 provided in the present invention are spaced apart in the circumferential direction and are respectively provided in contact with the radially outer side of each coupling member 115.

The buffer member 117 extends past both circumferential ends of the coupling member 115 on both sides in the circumferential direction and has a radially outwardly inclined buffer portion 1171, and the driven stopper portion 1051 is coupled on one side in the circumferential direction. When approaching the member 115, the radially outer end is in contact with the inner surface of the shock absorber 1171, and the shock absorber 1171 is deformed radially outward, so that shock is alleviated. The buffer member 117 may be made of metal, but is not limited thereto, and may be made of reinforced plastic.

The first retaining plate 101 is spaced along the circumferential direction, and a plurality of first retaining coupling portions are formed through the axial direction, and the second retaining plate 103 is spaced along the circumferential direction and is first retained. A plurality of second retaining engaging portions 1031 facing each of the engaging portions are formed through in the axial direction.

The coupling member 115 is provided with a coupling member insertion portion 1151 which is inserted into and coupled to the first retaining coupling portion and the second retaining coupling portion 1031 on both sides of the axial direction, and the buffer member 117 is also provided. The buffer coupling portion 1173 is provided on both sides of the axial direction, so that the buffer coupling portion 1173 is inserted into the first retaining coupling portion and the second retaining coupling portion 1031 together with the coupling member insertion portion 1151. do.

The buffer part 1171 is a first buffer part 1171a which is inclined and extended in a radially outward direction at a position spaced inwardly from a circumferential end of the coupling member 115, as shown in FIG. At the end of the first buffer portion 1171a, the second buffer portion 1171b is inclined and extended in an outward direction at a smaller angle than the first buffer portion 1171a. A gap S is formed between the buffer member 1171 and the radially outer side of the circumferential end of the coupling member 115.

Each of the first retaining coupling portion and the second retaining coupling portion 1031 is made of a pair of through holes formed side by side. The through holes formed in a pair in parallel and penetrated in the axial direction are spaced apart in a tangential direction.

The coupling member 115 is a hexahedral coupling member main body 1152 and the coupling member body 1152 spaced apart in a tangential direction on both sides of the coupling member body 1152 to form a pair of protruding coupling member insertion portion 1151 Is done.

The buffer member 117 is a buffer member 1117 of a rectangular plate-shaped buffer member body 1172 and spaced apart in a tangential direction on both sides in the axial direction of the buffer member body 1172 to protrude in the axial direction. Is done. The buffer part 1171 is provided on both sides in the circumferential direction of the buffer member body 1172.

The buffer member body 1172 is laminated on the radially outer side of the coupling member body 1152 in contact with the radial outer surface of the coupling member body 1152.

The coupling member 115 is formed to be thicker than the shock absorbing member 117 because the driven stopper portion 1051 acts as a shock stopper. The buffer member 117 is stacked on the radially outer surface of the coupling member 115, and the cushioning coupling part 1173 stacked on the radially outer side of the coupling member insertion portion 1151 and the coupling member insertion portion 1151 is It is inserted into the first retaining coupling portion and the second retaining coupling portion 1031 on both sides in the axial direction. In addition, the coupling member inserting portion 1151 protrudes past the first retaining coupling portion and the second retaining coupling portion 1031 on both sides in the axial direction, and the protruding end portions are deformed to form the first retaining coupling portion and the second retaining portion. It is formed of a coupling member coupling portion 1153 preventing separation from the inning coupling portion 1031.

The torsional damper 100 according to the present invention is provided with a buffer member 117 stacked on the radially outer side of the coupling member 115, and the driven stopper portion 1051 is cushioned before being impacted by the coupling member body 1152. Since it comes in contact with the portion 1171 and receives resistance, the impact force is alleviated. And the shock absorber 117 of a simple structure can effectively absorb the shock.

100: torsional damper
101: first retaining plate 103: second retaining plate
105: driven plate 107: compression spring
115: coupling member 117: buffer member

Claims (6)

The first retaining plate 101 and the first retaining plate 101 facing the first retaining plate 101 by a plurality of coupling members 115 are provided spaced apart in the circumferential direction is coupled to the first retaining plate 101 2 A plurality of coil springs disposed along the circumferential direction on the retaining plate 103, the first retaining plate 101 and the second retaining plate 103 to absorb vibration and shock in the rotational direction, and the agent It is provided between the 1 retaining plate 101 and the second retaining plate 103 and is elastically supported by the plurality of coil springs and coupled to the driven plate 105 receiving the reaction force in the rotational direction, and the driven plate 105 It comprises a spline hub 113 to transmit the driving force; The driven plate 105 is spaced apart in the circumferential direction and is provided with a driven stopper portion 1051 that protrudes outward in the radial direction and extends between the coupling members 115, and the coupling member 115 together with the driven stopper parts 1051 Acts as a stopper to prevent overcompression of the coil spring;
A buffer member 117 coupled to the first retaining plate 101 and the second retaining plate 103 on both sides of the axial direction is provided on the radially outer side of each coupling member 115, and the driven stopper part ( 1051) is in contact with the cushioning member 117 before contacting the coupling member 115, the shock is alleviated; The buffer member 117 extends past both ends of the circumferential direction of the coupling member 115 in both circumferential directions, and includes a radially outwardly inclined cushioning unit 1171, and a driven stopper unit 1051 is a coupling member 115 The torsional damper 100 characterized in that the shock is alleviated as the radially outer end contacts the inner surface of the shock absorber 1171 while the shock absorber 1171 is deformed radially outward. delete delete The method of claim 1, wherein the first retaining plate (101) is spaced along the circumferential direction to form a plurality of first retaining coupling portions through the axial direction, and the second retaining plate (103) is spaced along the circumferential direction. And a plurality of second retaining coupling portions 1031 facing each of the first retaining coupling portions are formed through the axial direction; The coupling member 115 is provided with coupling member insertion portions 1151 which are inserted into and coupled to the first retaining coupling portion and the second retaining coupling portion 1031 on both sides of the axial direction;
The buffer member 117 is provided with a buffer coupling portion 1173 on both sides in the axial direction, the buffer coupling portion 1173 is coupled with the first retaining coupling portion and the second retaining portion with the coupling member insertion portion 1151 The torsional damper 100, characterized in that inserted into the portion 1031 is coupled. The method of claim 4, wherein the buffer portion 1171 is a first buffer portion (1171a) and the first buffer portion inclined and extended in a radially outward direction at a position spaced apart inward from the circumferential end of the coupling member 115, the first buffer The torsional damper 100, characterized in that the second shock absorbing portion 1171b is radially outwardly bent at an angle smaller than the first shock absorbing portion 1171a at the end of the portion 1171a. According to claim 4 or claim 5, Each of the first retaining coupling portion and the second retaining coupling portion (1031) is made of a through-hole through a pair in parallel;
The coupling member 115 is a hexahedral coupling member body 1152, and the coupling member body 1152 spaced apart in a tangential direction on both sides of the coupling member body 1152 to form a pair and protrude in the axial direction to the coupling member insertion portion 1151 Is done;
The buffer member 117 is a square plate-shaped buffer member body 1172, and the buffer member 1117 is spaced apart in a tangential direction on both sides in the axial direction of the buffer member body 1172 to form a pair and protrude in the axial direction. Is made;
The buffer member 117 is stacked on the radially outer surface of the coupling member 115, and the cushioning coupling part 1173 stacked on the radially outer side of the coupling member insertion portion 1151 and the coupling member insertion portion 1151 is Inserted into the first retaining engaging portion and the second retaining engaging portion 1031 on both sides in the axial direction; The coupling member inserting portion 1151 protrudes past the first retaining coupling portion and the second retaining coupling portion 1031 on both sides in the axial direction, and the protruding ends are deformed so that the first retaining coupling portion and the second retaining portion The torsional damper 100, characterized in that it is formed of a coupling member coupling portion 1153 to prevent departure from the coupling portion (1031).

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