KR20200113898A - A Torque Converter Having Connecting Lugs - Google Patents

Abstract

The present invention relates to a torque converter (100) having connecting lugs, which comprises: a front cover (104); an impeller (106) engaged and rotated together with the front cover (104); a turbine (108) placed at a position facing the impeller (106); a reactor (110) placed between the impeller (106) and the turbine (108) to turn the flow of fluid coming out from the turbine (108) towards the impeller (106); a lockup clutch (114) which has a piston (116) connecting the front cover (104) and the turbine (108); and a torsional damper (120) which includes a plurality of springs (131) engaged with the lockup clutch (114). The front cover (104) is engaged with the connecting lugs (141). Since a fastening member (145) is fastened with the connecting lugs (141), a drive plate (143), which transfers driving force of the engine, is engaged with the front cover (104). The connecting lugs (141) include: a lug main frame (141a) which is a hollow body with an internal surface unit (141a-1) and is engaged with the front cover (104); and an insertion member (141b) inserted into the internal surface unit (141a-1) of the lug main frame (141a) to be engaged with the lug main frame (141a), and having a female screw unit (141b-1) on an internal diameter surface. The fastening member (145) is fastened with the female screw unit (141b-1) of the insertion member (141b) by a screw. The torque converter having connecting lugs is able to increase the rigidity of the connecting lugs and increase the fastening force with the fastening bolt.

Description

Torque Converter Having Connecting Lugs{A Torque Converter Having Connecting Lugs}

The present invention relates to a torque converter equipped with a connecting lug, and more specifically, there is no chip generation for screw formation, manufacturing cost is reduced, there is no problem of physical property change due to welding, and stiffness increases, and connection It relates to a torque converter provided with a connecting lug that makes it possible to simplify the shape of the lug.

The torque converter is a device that is installed between the engine and the transmission of the vehicle and transmits the driving force of the engine to the transmission using a fluid.

The torque converter is provided with a lock-up clutch, which is a means for directly connecting the engine and the transmission, since power transmission efficiency may decrease when the load acting on the engine increases. The lock-up clutch is disposed between the turbine and the front cover directly connected to the engine so that the rotational power of the engine can be directly transmitted to the transmission through the turbine. The lock-up clutch includes a piston axially movable on a turbine shaft. A friction material in frictional contact with the front cover is coupled to the piston, and a torsion damper capable of absorbing shock and vibration acting in the direction of rotation of the shaft is coupled when the friction material is coupled to the front cover.

A connecting lug that fixes the drive plate that transmits the driving force of the engine is coupled to the front cover. The connecting lugs are fixedly coupled by welding (temporal welding) to fix the position to be disposed on the front cover by projection welding, and then welding the circumferential portion again.

1 is a schematic half sectional view showing a conventional torque converter, and FIG. 2 is a diagram illustrating a step of forming a connection lug of a portion "A" of FIG. 1.

Conventional torque converters have a front cover 4 connected to the crankshaft on the engine side to rotate, an impeller 6 connected to the front cover 4 and rotating together, and a position facing the impeller 6 The turbine 8 is disposed, and the reactor 10, or'stator', which is located between the impeller 6 and the turbine 8 and transfers the flow of fluid from the turbine 8 to the impeller 6 side. ). The reactor 10 that delivers fluid to the impeller 6 has the same rotational center as the front cover 4. In addition, the lock-up clutch 14 used as a means for directly connecting the engine and the transmission is located between the front cover 4 and the turbine 8.

The lock-up clutch 14 has a substantially disk shape and includes a piston 16 that can move in the axial direction. A friction material 18 in frictional contact with the front cover 4 is coupled to the piston 16, and a torsional force acting in the rotation direction of the shaft when the friction material 18 is in close contact with the front cover 4 to the lock-up clutch 14 A torsional damper (20, Torsional damper), which serves to absorb and dampen vibrations, is combined. The torsion damper 20 is provided with a plurality of springs 31 that absorb shocks and vibrations acting in the circumferential direction. The springs 31 are disposed along the circumferential direction (rotation direction) and are formed of a compression coil spring. The spring 31 is supported by a retaining plate 33 coupled to the piston 16. The spring 31 is elastically supported by a driven plate 35 coupled to the turbine 8. The spring 31 is elastically supported between the retaining plate 33 and the driven plate 35 to absorb vibrations and shocks in the rotational direction (circumferential direction).

The driven plate 35 is coupled to the turbine 8 by rivets or bolts. And the driven plate 35 may be coupled together by the above-described rivets or bolts to the spline hub 37 that transmits the driving force to the transmission side.

A connection lug 41 is coupled to the front cover 4. The connecting lug 41 is coupled with a drive plate 43 that transmits the driving force of the engine. The connection lug 41 is formed with a female thread and is screwed to the fastening member 45 so that the drive plate 43 is coupled to the front cover 4.

In forming the connection lug 41 on the front cover 4, the connection lug member 41' is welded and attached to the position where the seat groove 4a is formed as shown in FIG. 2 (FIG. 2(a)) ), by drilling with a drill or the like to form the inner surface portion 41a (FIG. 2(b)), and processing the female thread on the inner surface to form the female threaded portion 41b (FIG. 2(c)).

In the conventional method of forming a connecting lug of a torque converter as described above, contamination may be caused by chips generated during processing such as screw processing, and a connecting lug member 41' is attached to the front cover 4 and the connecting lug Since it is necessary to form the female thread 41b on the member 41 ′, processing is not easy and processing cost increases, and the connection lug processed as known in Japanese Laid-Open Patent Publication No. 2001-263451 In the case of welding and attachment, a separate jig had to be used in order to be welded in an upright state, and due to welding, the properties and dimensions of the connecting lug were changed, causing a problem in that a connection failure with the fastening member 45 occurred.

And in order to prevent changes in the physical properties and dimensions of the connecting lug due to welding, as shown in 3, lug legs 41-1 extending toward the front cover 4 are provided on both sides of the female threaded portion 41b, and the lug The end of the leg 41-1 was welded to the front cover 4 so that the welded portion was moved away from the female threaded portion 41b. Therefore, there is a problem in that the shape of the connecting lug 41 should be made into a more complex shape than necessary.

Republic of Korea Registration No. 10-1152427 Registered Patent Publication Japanese Patent Application Laid-Open Publication No. 2001-263451

The present invention has been proposed to solve the problems of the prior art as described above, and it is possible to form a connection lug without a separate jig, and it is possible to prevent the occurrence of fastening failure due to changes in dimensions or physical properties due to welding, and It provides a torque converter equipped with a connecting lug that increases rigidity and increases the fastening force with the fastening bolt, thereby increasing the height adjustment margin of the connecting lug.

For the above purposes, the present invention provides a front cover, an impeller coupled to the front cover and rotating together, a turbine disposed at a position facing the impeller, and a fluid coming from the turbine located between the impeller and the turbine. A lock-up clutch including a reactor for converting the flow of flow to the impeller side, a piston connecting the front cover and the turbine, and a torsion damper provided with a plurality of springs coupled to the lock-up clutch; A connecting lug is coupled to the front cover, and a drive plate is coupled to the front cover by fastening a fastening member to the connecting lug to transmit driving force of the engine; The connecting lug is a hollow body having an inner surface portion and includes a lug body coupled to the front cover, and an insertion member inserted into the inner surface of the lug body and coupled to the lug body, and a female threaded portion is formed on the inner diameter surface, and the fastening member is inserted It provides a torque converter provided with a connection lug screwed to the female thread of the member.

In the above, the connecting lug is provided by being coupled to the position where the seat groove of the front cover is formed, so that the lug body is separated from the bottom of the seat groove, and the insertion member is inserted into the lug body so that the end protrudes into the seat groove past the lug body. It features.

In the above, the connecting lug is coupled to the position where the seat groove of the front cover is formed so that the lug body is spaced from the bottom of the seat groove, and the insertion member is inserted into the lug body and protrudes into the seat groove past the lug body, so that the end of the seat groove It characterized in that it is provided in contact with the bottom of the.

In the above, the adhesive material is provided between the inner surface portion of the lug body and the insertion member, and the insertion member is adhered to the inner surface portion of the lug body and is provided.

In the above, the inner surface portion is formed in a circular cross-section, the outer surface of the insertion member is also formed in a circular shape, the insertion member is characterized in that the insert is inserted into the inner surface by force fit.

In the above, the inner surface portion and the outer surface of the insertion member is characterized in that it is formed in a form that does not rotate relative to each other.

According to the torque converter equipped with a connecting lug of the present invention, the effect of changes in physical properties and dimensions due to welding is small, preventing poor connection with the fastening bolt, increasing the bonding strength with the fastening bolt, and Since contamination is prevented and thread processing is performed before being coupled to the front cover, processing is easy, and time and cost required for processing are reduced.

1 is a half sectional view showing a torque converter according to the prior art,
FIG. 2 is a flow chart illustrating a method of forming a connection lug of the “A” part of FIG. 1 according to the prior art,
3 is a perspective view showing an example of a connection lug according to the prior art,
4 is a half sectional view showing a torque converter according to the present invention,
5 is a flow chart illustrating a method of forming a connection lug of the "A" part of FIG. 4;
6 is a perspective view showing a connection lug provided in the torque converter of the present invention,
7 is a perspective view showing a modified example of a connection lug provided in the torque converter of the present invention.

Hereinafter, a torque converter provided with a connection lug according to the present invention will be described in detail with reference to the accompanying drawings.

4 is a half sectional view showing a torque converter according to the present invention, FIG. 5 is a flow chart illustrating a method of forming a connection lug of the "A" part of FIG. 4, and FIG. 6 is provided in the torque converter of the present invention. It is a perspective view showing the connecting lug, and Figure 7 is a perspective view showing a modified example of the connecting lug provided in the torque converter of the present invention.

The torque converter 100 according to the present invention includes a front cover 104 connected to the crankshaft on the engine side and rotating, and an impeller 106 connected to the front cover 104 and rotated together, as shown in FIG. ), the turbine 108 disposed at a position facing the impeller 106, and the impeller 106 disposed between the impeller 106 and the turbine 108 to change the flow of fluid from the turbine 108 It includes a reactor 110 that is transmitted to the side. A lock-up clutch 114 used as a means of directly connecting the engine and transmission is located between the front cover 104 and the turbine 108.

The lock-up clutch 14 is provided with a piston 116 that can move in the axial direction. A friction material 118 in frictional contact with the front cover 104 is coupled to the piston 116, and a torsion acting in the direction of rotation of the shaft when the friction material 118 is in close contact with the front cover 104 to the lock-up clutch 114 A torsion damper 120 that absorbs the force and attenuates vibration is combined. The torsion damper 120 is provided with a plurality of springs 131 that absorb shocks and vibrations acting in the circumferential direction. The spring 131 is disposed along a circumferential direction (rotation direction) and supported by a retaining plate 133 coupled to the piston 116. The spring 131 is elastically supported by a driven plate 135 coupled to the turbine 108. The spring 131 is elastically supported between the retaining plate 133 and the driven plate 135 to absorb vibrations and shocks in the rotational direction (circumferential direction). The driven plate 135 is coupled to the turbine 108 by rivets or bolts.

A connection lug 141 is coupled to the front cover 104. The connecting lug 141 is coupled to a drive plate 143 that transmits the driving force of the engine. A female threaded portion 141b-1 is formed in the connection lug 141 and is screwed to a fastening member 145 which is a bolt, so that the drive plate 143 is coupled to the front cover 104.

A plurality of concave seat grooves 104a are formed in the front cover 104 to be spaced apart along the circumferential direction, and a plurality of connection lugs 141 are coupled to a position where the seat groove 104a is formed.

The connecting lugs 141 are spaced apart from each other along the circumferential direction and provided in plurality, and a fastening member 145 which is a bolt at a plurality of locations is fastened to the connecting lug 141.

The connecting lug 141 according to the present invention includes a lug body 141a and an insertion member 141b inserted into and coupled to the lug body 141a.

The lug body (141a) is a hollow body in which an inner surface portion (141a-1), which is a through hole that is opened through both sides, is formed, and one end is welded to the position where the seat groove (104a) of the front cover 104 is formed. 104).

The lug member 104a' to be formed as the lug body 141a is welded to the front cover 104 at the position where the seat groove 104a is formed, and it is also possible to form the inner surface portion 141a-1 through drilling. Do. It is also possible to form the lug member 104a' as a hollow body and the inner surface portion 141a-1 through a finishing operation (finishing process). The lug body 141a is welded to the front cover 104 to the outside of the seat groove 104a along its circumference, and the lug body 141a is spaced apart from the bottom of the seat groove 104a. The inner surface portion 141a-1 is formed to have a size located inside the edge of the seat groove 104a.

The insertion member (141b) is inserted into the inner surface (141a-1) of the lug body (141a) is coupled to the lug body (141a). A female threaded portion 141b-1 is formed on the inner diameter surface of the insertion member 141b, so that the fastening member 145 is screwed to the female threaded portion 141b-1 of the insertion member 141b. The insertion member (141b) is inserted into the lug body (141a) and the end protrudes into the seat groove (104a) past the lug body (141a). The fastening member 145 is screwed with the insertion member 141b up to the protruding portion into the seat groove 104a, so even when the height of the connecting lug 141 is not high, the number of screw threads to be screwed in is increased compared to the prior art. As it becomes possible, the screw tightening force increases and the screw is tightened more stably.

The insertion member 141b is pre-processed in a form in which a female threaded portion 141b-1 is formed on an inner diameter surface, and is inserted into the lug body 141a to be coupled. Therefore, there is no need to couple a lug member serving as a connecting lug to the front cover 104 and to process the female threaded portion 141b-1, and no chips for processing the female threaded portion 141b-1 are generated, and the lug body 141a ), since the insertion member 141b is inserted into the lug body 141a after welding, there is no change in physical properties or dimensions of the insertion member 141b due to welding, so that a fastening failure does not occur.

The insertion member 141b is inserted into the lug body 141a, passes through the lug body 141a and protrudes into the seat groove 104a, so that the end thereof may contact the bottom of the seat groove 104a. Accordingly, the fastening member 145 is screwed to the female threaded portion 141b-1 over the entire depth d of the seat groove 104a, so that the number of screw fastening screws is increased to the maximum.

An adhesive material is provided between the inner surface portion 141a-1 of the lug body 141a and the insertion member 141b so that the insertion member 141b is adhered to the inner surface portion 141a-1 of the lug body 141a. . An adhesive material is applied to the inner surface portion 141a-1 of the lug body 141a, or an adhesive material is applied to the outer surface of the insertion member 141b, and the insertion member 141b is the inner surface portion 141a- It is inserted in 1). The adhesive may be applied to both the inner surface portion 141a-1 of the lug body 141a and the outer surface of the insertion member 141b.

The inner surface portion 141a-1 of the lug body 141a has a circular cross-section, and the outer surface of the insertion member 141b is also formed in a circular shape, so that the insertion member 141b is an inner surface of the lug body 141a. The part (141a-1) may be forcibly fitted and inserted to be coupled.

In addition, the inner surface portion 141a-1 of the lug body 141a and the outer surface of the insertion member 141b may be formed in a form that cannot rotate relative to each other. It is possible to combine the inner surface portion 141a-1 of the lug body 141a in a polygonal or spline shape, and similarly to the outer surface of the insertion member 141b in a polygonal or spline shape so as not to be able to move relative to each other.

By forming the connecting lug 141 provided in the torque converter 100 of the present invention with a lug body 141a and an insertion member 141b inserted and coupled to the lug body 141a, the front cover 104 Machining after welding is minimized, and defects due to welding are prevented.

100: torque converter 104: front cover
141: connecting lug 141a: lug body
141b: insertion member 143: drive plate
145: fastening member

Claims (7)

A front cover 104, an impeller 106 coupled to the front cover 104 and rotating together, a turbine 108 disposed at a position facing the impeller 106, the impeller 106 and a turbine A reactor 110 located between 108 and converting the flow of fluid from the turbine 108 toward the impeller 106, and a piston 116 connecting the front cover 104 and the turbine 108 And a torsion damper 120 provided with a lock-up clutch 114 and a plurality of springs 131 coupled to the lock-up clutch 114;
A connecting lug 141 is coupled to the front cover 104, and a drive plate 143 is coupled to the front cover 104 by fastening the connecting member 145 to the connecting lug 141 to transmit the driving force of the engine. ;
The connection lug 141 is a hollow body having an inner surface portion 141a-1 formed thereon, and is inserted into the lug body 141a coupled to the front cover 104 and the inner surface portion 141a-1 of the lug body 141a It is coupled to the lug body (141a) and includes an insertion member (141b) having a female threaded portion (141b-1) formed on the inner diameter surface, the fastening member 145 is a female threaded portion (141b-1) of the insertion member (141b) Torque converter 100 provided with a connection lug, characterized in that screwed to the. The method of claim 1, wherein the connection lug 141 is provided by being coupled to a position where the seat groove 104a of the front cover 104 is formed, so that the lug body 141a is spaced apart from the bottom of the seat groove 104a, and the The insertion member (141b) is inserted into the lug body (141a) and the end of the torque converter (100) provided with a connecting lug, characterized in that protruding into the seat groove (104a) past the lug body (141a). The method of claim 1, wherein the connection lug 141 is coupled to the position where the seat groove 104a of the front cover 104 is formed, and the lug body 141a is spaced apart from the bottom of the seat groove 104a, and the insertion member (141b) is inserted into the lug body (141a), passes through the lug body (141a) and protrudes into the seat groove (104a), and the end thereof is provided in contact with the bottom of the seat groove (104a). Converter 100. The lug body (141a) according to any one of claims 1 to 3, wherein an adhesive is provided between the inner surface (141a-1) of the lug body (141a) and the insertion member (141b), and the insertion member (141b) is a lug body (141a). ). Torque converter 100 provided with a connecting lug, characterized in that it is adhered to the inner surface portion (141a-1) of the. The method according to any one of claims 1 to 3, wherein the inner surface portion (141a-1) of the lug body (141a) has a circular cross section, and the outer surface of the insertion member (141b) is also formed in a circular shape, The insertion member (141b) is a torque converter (100) provided with a connecting lug, characterized in that the force fit inserted into the inner surface portion (141a-1) of the lug body (141a). The method according to any one of claims 1 to 3, characterized in that the inner surface portion (141a-1) of the lug body (141a) and the outer surface of the insertion member (141b) are formed in a form that cannot rotate relative to each other. Torque converter 100 provided with a connecting lug. The torque converter with a connecting lug according to claim 4, wherein the inner surface portion 141a-1 of the lug body 141a and the outer surface of the insertion member 141b are formed in a form that cannot rotate relative to each other. 100).

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