JP5669788B2 - Manufacturing method of clutch plate - Google Patents

Description

  The present invention relates to a method for manufacturing a clutch plate used in an automatic transmission.

  FIG. 6 is a diagram for explaining a method of manufacturing a clutch plate according to a conventional example. FIG. 6A is a diagram for explaining a case where a ring-shaped clutch plate Kp is manufactured by punching a single metal plate P1. (B) is a diagram for explaining a case where a plurality of arc-shaped members P4 are punched out from a single metal plate P1 in order to produce a ring-shaped clutch plate Kp ′, and (c) It is a figure explaining the ring-shaped clutch board Kp 'obtained by connecting the circular arc-shaped member P4 shown to (b).

The clutch plate Kp used in the vehicle automatic transmission has a ring shape when viewed from the axial direction. As a method for manufacturing the clutch plate Kp, a rectangular metal plate P1 is punched into a ring shape. The method is generally known (see FIG. 6A).
Here, although the metal plate P1 for punching the ring-shaped clutch plate Kp has a relatively large area, the remaining portions P2, P3 after punching the ring-shaped clutch plate Kp are performed. Are often discarded without being diverted to other uses.
Therefore, such a manufacturing method has a problem that the yield is poor and the manufacturing cost of the clutch plate Kp is high.

Therefore, for example, Patent Document 1 discloses that a ring-shaped clutch plate Kp ′ is manufactured by connecting a plurality of arc-shaped members P4.
In the case of such a manufacturing method, as shown in FIGS. 6B and 6C, by setting a plurality of arc-shaped members P4 to be punched in one metal plate P1, the metal plate P1 The area of the discarded portion P5 can be suppressed.

JP 2007-177931 A

  However, when a ring-shaped clutch plate Kp ′ is manufactured by connecting a plurality of arc-shaped members P4, the strength of the obtained clutch plate Kp ′ is higher than that of a clutch plate Kp created by punching a single metal plate. There is a risk of weakening.

  Therefore, it is required to manufacture a ring-shaped clutch plate having sufficient strength with a high yield.

The present invention
On one end side in the longitudinal direction of the bottomed cylindrical substrate to which the other end is sealed in the longitudinal direction, and the enlarged diameter portion forming step of forming a radially enlarged portion whose diameter increases toward the one end,
A dividing step of dividing a cylindrical base material of the bottom in which the enlarged diameter portion is formed, and the enlarged diameter portion, the cylindrical base material of the new bottomed said radially enlarged portion is removed,
A press step for creating a ring-shaped plate-like member by pressing the expanded portion obtained in the dividing step;
A punching step of obtaining a ring-shaped clutch plate by punching the ring-shaped plate member,
While the length in the longitudinal direction of the new bottomed cylindrical base material obtained in the dividing step is a length capable of forming the enlarged diameter portion in the enlarged diameter portion forming step, the dividing step is performed. Using the obtained new bottomed cylindrical base material, the enlarged-diameter portion forming step, the dividing step, the pressing step, and the punching step are performed. Method.

According to this invention, while the length of the longitudinal direction of the new cylindrical base material obtained by a division | segmentation process is the length which can form an enlarged diameter part, the newly obtained cylindrical base material is used. In addition, since the process from the enlarged diameter portion forming process to the punching process is repeatedly performed, a plurality of clutch plates can be obtained from one cylindrical base material prepared first.
And only the part of the length which cannot form an enlarged diameter part among the cylindrical base materials prepared initially is finally discarded. Therefore, since the discarded portion in the cylindrical base material can be reduced, a ring-shaped clutch plate can be manufactured with a high yield.
Moreover, since a ring-shaped clutch plate is manufactured from a cylindrical base material, the strength of the clutch plate is higher than that of a ring-shaped clutch plate manufactured by connecting arc-shaped members.
Therefore, a ring-shaped clutch plate having sufficient strength can be manufactured with high yield.

It is a flowchart of the manufacturing method of the clutch board concerning embodiment. It is a figure explaining the manufacturing method of the clutch board concerning an embodiment. It is a figure explaining the manufacturing method of the clutch board concerning an embodiment. It is a figure explaining the manufacturing method of the clutch board concerning an embodiment. It is a figure explaining the manufacturing method of the clutch board concerning an embodiment. It is a figure explaining the manufacturing method of the clutch board concerning a prior art example.

Hereinafter, a clutch plate used in an automatic transmission, which is a clutch plate 16 (see FIG. 4C) provided with a plurality of teeth on the inner periphery, will be described as an example. A method for manufacturing the clutch plate will be described.
FIG. 1 is a flowchart of the manufacturing method of the clutch plate 16 according to the embodiment. In addition, in FIG. 1, the member used as a result of the process used as a result of a process or the process used with each process (S1-S6) of a process is shown.
FIG. 2 is a diagram for explaining the process from the production of one rectangular metal plate 10 to the bottomed cylindrical base material 13. In addition, in (a) to (c) in FIG. 2, a sectional view (A- (A cross-sectional view), which emphasizes these thicknesses.

In the clutch plate manufacturing method according to the embodiment, the clutch plate 16 (see FIG. 4) is manufactured from one rectangular metal plate 10 (see FIG. 2).
Here, the metal plate 10 is comprised from the metal material which comprises the clutch board 16, and has substantially uniform thickness W1 over the whole region (refer Fig.2 (a)).

  First, in step S <b> 1 (see FIG. 1), the circular plate member 11 is created by circular punching of the metal plate 10. At this time, the remaining material 12 having the opening 12a having a size matching the plate-like member 11 at the center is obtained together with the circular plate-like member 11, and this remaining material 12 is obtained from the subsequent clutch plate. It is not used for the production of 16 but discarded.

In subsequent step S <b> 2, a bottomed cylindrical base material 13 is created by drawing the plate-like member 11.
The base material 13 includes a circular bottom portion 13a as viewed from the axial direction, and a peripheral wall portion 13b surrounding the outer periphery of the bottom portion 13a over the entire circumference, and the height h1 of the peripheral wall portion 13b from the bottom portion 13a is: It is formed at the same height over the entire circumference.
Note that the inner diameter D1 of the peripheral wall portion 13b is set to be smaller than the inner diameter Da (see FIG. 4) of the finally obtained clutch plate 16 (Da> D1). This is to secure a margin for forming the tooth portion 161 of the clutch plate 16.

  FIG. 3 is a diagram illustrating from the base material 13 to the creation of the enlarged diameter portion 14 and a new base material 13A. 3A to 3C, the sectional view (A) of each member is shown below the plan view of each member (base materials 13, 13 ′, enlarged diameter portion 14, and new base material 13A). -A sectional view), which emphasizes these thicknesses.

In step S3 (see FIG. 1), the end portion 13b1 on the opening side of the peripheral wall portion 13b of the base material 13 is flared to form the enlarged diameter portion 14 in which the inner diameter D2 increases toward the distal end side.
The enlarged diameter portion 14 is formed by bending a range of a predetermined height ha in the peripheral wall portion 13b outward in the radial direction in the base material 13 shown in FIG. 3 (a). Is set in accordance with the radial width W of the ring-shaped clutch plate 16 and the outer diameter Db (see FIG. 4C).

  In subsequent step S4, in the base material 13 'on which the enlarged diameter portion 14 is formed, a base point 13b2 of the enlarged diameter portion 14 in the peripheral wall portion 13b (a bent origin point in the peripheral wall portion 13b) is set to a horizontal line Z that is horizontal to the bottom portion 13a. Cut along (see FIG. 3B). Thereby, the base material 13 ′ on which the enlarged diameter portion 14 is formed is divided into the enlarged diameter portion 14 and a new base material 13 </ b> A in which the height of the peripheral wall portion 13 b is lowered. Here, the height h2 from the bottom portion 13a of the peripheral wall portion 13b of the base material 13A newly obtained is higher than the height h1 of the peripheral wall portion 13b of the base material 13 described above. It is lower by the amount of ha (see (a) in FIG. 3) (h1> h2).

In the embodiment, one end (end portion 13b1) side of the peripheral wall portion 13b is bent radially outward over the entire circumference to form the enlarged diameter portion 14, and the bottomed cylinder in which the enlarged diameter portion 14 is formed. In the shaped base material 13 ′, the rigidity of the peripheral wall portion 13 b on the enlarged diameter portion 14 side (base point 13 b 2 side) is enhanced by the enlarged diameter portion 14.
Therefore, when the peripheral wall portion 13b is cut at the base point 13b2 of the enlarged diameter portion 14, it is suitably prevented that the enlarged diameter portion 14 side of the peripheral wall portion 13b is deformed by the stress acting at the time of cutting. The peripheral wall portion 13b can be divided at a horizontal line Z that is parallel to the bottom portion 13a.

  Further, the rigidity strength of the peripheral wall portion 13b on the side of the enlarged diameter portion 14 is enhanced by the enlarged diameter portion 14, so that the shape when the peripheral wall portion 13b of the new base material 13A is viewed from the axial direction is expanded in diameter. It becomes the same circular shape as the surrounding wall part 13b of the base material 13 before the part 14 is formed.

  Here, the inclination θ of the enlarged diameter portion 14 with respect to the bottom portion 13a may be any inclination that can increase the rigidity strength of the peripheral wall portion 13b, and is set to be approximately 45 ° in the embodiment.

  FIG. 4 is a diagram for explaining the process from the enlarged diameter portion 14 to the creation of the clutch plate 16. 4A to 4C, cross-sectional views (AA cross-sectional views) of each member are provided below the plan view of each member (the enlarged diameter portion 14, the plate-like member 15, and the clutch plate 16). ) And emphasized these thicknesses.

In step S5 (see FIG. 1), a ring-shaped plate-like member 15 is created as seen from the axial direction by coining the enlarged diameter portion 14 obtained in step S4.
Here, in the enlarged diameter portion 14 obtained by the above-described step S4, the inner circumference 140a side and the outer circumference 140b side of the ring-shaped base portion 140 are offset in the axial direction of the center line X of the enlarged diameter portion 14, In the case of FIG. 4A, the outer periphery 140b side has a shape positioned on the upper side of the inner periphery side 140a. Therefore, in the coining in step S5, the outer periphery 140b side of the base portion 140 of the enlarged diameter portion 14 is bent in the direction indicated by the arrow f in the figure, and the ring-shaped plate member 15 is finally formed.

In the embodiment, the ring-shaped base portion 140 is deformed until the inclination θ1 of the base portion 140 with respect to the center line X of the enlarged diameter portion 14 is approximately 90 °, and the ring-shaped plate-like member 15 is formed. The base 140 is prevented from being greatly compressed in the axial direction of the center line X during coining.
Therefore, the radial width W2 of the ring-shaped base portion 150 in the plate-like member 15 is slightly larger than the radial width ha of the ring-shaped base portion 140 in the expanded diameter portion 14. The shape of the circumference 150a and the outer circumference 150b seen from the axial direction is maintained in a substantially circular shape without greatly changing from the shape of the inner circumference 140a and the outer circumference 140b of the enlarged diameter portion 14 seen from the axial direction. .

In step S <b> 6, the clutch plate 16 in which the tooth portion 161 is formed on the inner periphery of the ring-shaped base portion 160 is created by press punching the ring-shaped plate-shaped member 15. At this time, the slight portions 15 a and 15 b on the inner peripheral 150 a side and the outer peripheral 150 b side of the plate-like member 15 are discarded as the remaining material 17.
Here, in the base 150 shown in FIG. 4B, the range in which the tooth portion 161 is formed on the inner periphery 150a of the base 150 is indicated by reference numeral 15a, and the tooth portion 161 to be finally formed is shown. Illustration of the shape is omitted.

Here, in step 4 described above, in addition to the enlarged diameter portion 14, a new bottomed cylindrical base material 13A in which the height of the peripheral wall portion 13b is reduced is obtained.
In the base material 13A, in step S7, whether or not the height of the peripheral wall portion 13b is a height at which the diameter-expanded portion 14 can be newly formed, that is, whether or not the flare process is possible. Is confirmed.

When the height is such that flare processing is possible, flare processing is performed on the new base material 13A, and a new clutch plate 16 is formed from the enlarged diameter portion 14 formed by the flare processing. Will be.
Therefore, flare processing (FIG. 1: S3) and division (FIG. 1: S4) are repeatedly executed while the height of the peripheral wall portion 13b in the new base material is a height that allows flare processing. A predetermined number of clutch plates 16 determined according to the number of repetitions of flare processing are created from the first metal plate 10.

  FIG. 5 shows a new base material 13A that is obtained each time flare processing (FIG. 1: S3) and division (FIG. 1: S4) are performed from the bottomed cylindrical base material 13 formed first. -It is a figure explaining 13X.

  Here, in the manufacturing method of the clutch plate 16 according to the embodiment, the height of the peripheral wall portion 13b is lower than before each time flare processing (FIG. 1: S3) and division (FIG. 1: S4) are performed. Thus, the bottomed cylindrical base material 13A... 13X is obtained.

Therefore, when flare processing (FIG. 1: S3) and division (FIG. 1: S4) are performed a plurality of times, the height of the peripheral wall portion 13b of the newly obtained bottomed cylindrical member cannot be subjected to flare processing. The height hx is reached (see (d) of FIG. 5).
In this case, the base material 13X having the peripheral wall portion 13b having a height hx that cannot be subjected to flare processing is discarded (FIG. 1: S7).

Here, in the embodiment, the clutch plate 16 is created while reducing the height of the peripheral wall portion 13b of the bottomed cylindrical base material 13, but the height of the peripheral wall portion 13b is low. Even so, the rigidity of the lower end side of the peripheral wall portion 13b is held by the bottom portion 13a.
Therefore, in the base material 13X-1 immediately before the height of the peripheral wall portion 13b reaches the height hx at which flare processing cannot be performed, the peripheral wall portion 13b is low although the height hx-1 of the peripheral wall portion 13b is low. Is secured by the bottom 13a.
Therefore, even if flare processing is performed on the base material 13X-1, the shapes of the peripheral wall portion 13b and the enlarged diameter portion 14 are not greatly collapsed. In addition, even when a stress such as a cutter acts on the peripheral wall portion 13b during the division following the flare processing, the shape of the enlarged diameter portion 14 separated from the peripheral wall portion 13b is not greatly collapsed.

In the above-described embodiment, the case where the clutch plate 16 is manufactured from one rectangular metal plate 10 has been described as an example, but a base material composed only of the cylindrical peripheral wall portion 13b is prepared, You may manufacture the clutch board 16 from the base material which consists only of this cylindrical surrounding wall part 13b.
In addition, instead of the single rectangular metal plate 10, a single circular metal plate (plate-like member 11) may be prepared, and the clutch plate 16 may be manufactured from the plate-like member 11.

As described above, in the embodiment, in the base material 13 having the cylindrical peripheral wall portion 13b, the diameter is increased toward the one end (end portion 13b1) in the longitudinal direction of the peripheral wall portion 13b toward the end portion 13b1. An enlarged diameter portion forming step for forming the portion 14 (FIG. 1: S3);
A dividing step (FIG. 1: S4) for dividing the base material 13 ′ having the enlarged diameter portion 14 into the enlarged diameter portion 14 and a new base material 13A from which the enlarged diameter portion 14 has been removed;
A coining step (FIG. 1: S5) for creating a ring-shaped plate-like member 15 by coining the enlarged diameter portion 14 obtained in the dividing step;
A punching step (FIG. 1: S6) of obtaining a ring-shaped clutch plate 16 having a tooth portion 161 on the inner periphery by punching the ring-shaped plate-like member 15;
While the length in the longitudinal direction of the peripheral wall portion 13b of the new base material obtained in the dividing step is longer than the length (hx) where the enlarged diameter portion 14 cannot be formed in the enlarged diameter portion forming step, the dividing step is performed. With respect to the obtained new base material 13A... 13X-1, the enlarged diameter portion forming step, the dividing step, the pressing step, and the punching step are executed to create the clutch plate 16,
When the length in the longitudinal direction of the peripheral wall portion 13b of the new base material 13X obtained in the dividing step becomes a length (hx) at which the expanded diameter portion 14 cannot be formed, the clutch plate 16 configured to discard the base material 13X. It was set as the manufacturing method of this.

If comprised in this way, while the length of the longitudinal direction of the new base material 13 obtained at a division | segmentation process is longer than the length (hx) which cannot form the enlarged diameter part 14, newly obtained base material 13A ... Since 13X-1 is used repeatedly from the enlarged diameter portion forming step to the punching step, a plurality of clutch plates 16 can be obtained from one base material 13 prepared first.
And only the base material 13X with which the peripheral wall part 13b used as the length (hx) which cannot form the enlarged diameter part 14 was left among the base materials 13 prepared initially is discarded finally. Therefore, since the discarded part in the base material 13 can be reduced, the ring-shaped clutch plate 16 can be manufactured with a high yield.
Further, since the ring-shaped clutch plate 16 is made from the ring-shaped plate member 15 obtained from the base material 13, the strength of the obtained clutch plate 16 is a ring manufactured by connecting the arc-shaped member P4. The rigidity is higher than that of the clutch plate Kp ′.
Therefore, the ring-shaped clutch plate 16 having sufficient strength can be manufactured with high yield.

In particular, the outer diameter side 140b is positioned on the radially outer side of the inner diameter side 140a due to the coining of the enlarged diameter portion 14 in which the inner circumference 140a side and the outer circumference 140b side of the ring-shaped base 140 are offset in the axial direction of the center line X. Until then, the enlarged diameter portion 14 is deformed to form the ring-shaped plate member 15.
When a ring-shaped plate member is manufactured by pressing a wire connected in a ring shape, it is difficult to control the inner and outer shapes of the obtained ring-shaped plate member. It has been difficult to stably produce a ring-shaped plate member having a radial width necessary for punching.
With the configuration as described above, the base 140 of the enlarged diameter portion 14 is not greatly compressed in the axial direction of the center line X during coining, so the shafts of the inner periphery 150a and the outer periphery 150b of the base 150 of the obtained plate-like member 15 are obtained. The shape viewed from the direction is maintained in a substantially circular shape without greatly deforming from the shape viewed from the axial direction of the inner periphery 140a and the outer periphery 140b of the enlarged diameter portion 14.
Therefore, since the width W2 of the base 150 of the obtained plate-like member 15 does not change greatly from the width ha of the base 140 of the enlarged diameter portion 14, a ring-shaped plate having a radial width necessary for punching the clutch plate 16 The shaped member 15 can be obtained stably.

The base material having the cylindrical peripheral wall portion 13b is a bottomed cylindrical base material 13 in which the other end side of the peripheral wall portion 13b is sealed by the bottom portion 13a.
Prior to the enlarged diameter portion forming step, a clutch plate manufacturing method including a drawing step of forming the bottomed cylindrical base material 13 by drawing the circular plate-like member 11 was used.

In the manufacturing method of the clutch plate 16 according to the embodiment, the height of the peripheral wall portion 13b is lowered each time a new base material 13 is obtained.
When the base material 13 is composed only of the cylindrical peripheral wall portion 13b, the rigidity strength of the base material 13 decreases as the height of the peripheral wall portion 13b decreases, so the length of the peripheral wall portion 13b increases in diameter. Even if the length of the portion 14 can be formed, there is a possibility that the shapes of the enlarged diameter portion 14 and the plate-like member 15 obtained from the base material 13 may vary.
When the base material 13 is a bottomed cylindrical base material in which the other end side of the peripheral wall portion 13b is sealed by the bottom portion 13a, the rigidity strength of the peripheral wall portion 13b is reduced even if the height of the peripheral wall portion 13b is reduced. Since it is ensured by the bottom portion 13a, variations in the shapes of the enlarged diameter portion 14 and the plate-like member 15 obtained from the base material 13 can be suppressed.
Thereby, since the base material can be used for the production of the clutch plate 16 until the peripheral wall portion 13b has a length that cannot form the enlarged diameter portion 14, the discarded portion of the base material 13 can be reduced. Can be manufactured with good yield.

  The clutch plate manufacturing method further includes a circular punching step for obtaining a circular plate-like member 11 by punching the rectangular metal plate 10 before the drawing step.

In the case where the base material 13 is composed only of the ring-shaped peripheral wall portion 13b, the portion of the base material 13 that is finally discarded can be minimized, but the base material composed of only the ring-shaped peripheral wall portion 13b No. 13 has a higher procurement cost than the metal plate 10.
When a circular plate-like member 11 is created by punching a rectangular metal plate 10 and a bottomed cylindrical base material 13 is created by drawing the plate-like member 11, the periphery of the plate-like member 11 in the metal plate 10 is obtained. The (remaining material 12) is discarded without being used for making the clutch plate 16.
However, the procurement cost of the metal plate 10 is more than the procurement cost of the base material composed only of the ring-shaped peripheral wall portion 13b, even if the cost of the remaining material 12 to be discarded and the newly added circular punching process and drawing process are taken into account. Therefore, the clutch plate 16 can be produced at a lower cost as a whole.

  Here, in the dividing step, the base point 13b2 of the enlarged diameter portion 14 in the peripheral wall portion 13b (the base point of bending in the peripheral wall portion 13b) is set to a horizontal line Z that is horizontal to the bottom portion 13a of the base material 13 (see FIG. 3B). It was set as the structure cut | disconnected along.

In the bottomed cylindrical base material 13 ′ in which the enlarged diameter portion 14 is formed, the rigidity of the peripheral wall portion 13 b on the enlarged diameter portion 14 side (the base point 13 b 2 side of the enlarged diameter portion 14) is increased by the enlarged diameter portion 14. ing.
For this reason, by cutting the peripheral wall portion 13b at the base point 13b2 of the enlarged diameter portion 14 in the peripheral wall portion 13b, it is possible to suitably prevent the enlarged diameter portion 14 side of the peripheral wall portion 13b from being deformed by the stress acting at the time of cutting.
Thereby, in base material 13A ... 13X newly obtained, when the peripheral wall part 13b of the said base material 13A ... is seen from an axial direction, the base material before the enlarged diameter part 14 is formed 13 has the same shape (circular shape) as the peripheral wall portion 13b.
Therefore, the shape seen from the axial direction of the enlarged diameter portion 14 and the ring-shaped plate-like member 15 created from the newly obtained base material 13A... 13X-1 is created from the first base material 13. The diameter portion 14 and the ring-shaped plate member 15 are formed in substantially the same shape. Therefore, since the variation of the shape of the enlarged diameter part 14 obtained from the one base material 13 or the plate-shaped member 15 is few, the clutch board 16 finally obtained can be produced with a sufficient yield.

  In the above-described embodiment, the case of the clutch plate 16 having the tooth portion 161 on the inner peripheral side has been described as an example. However, the manufacturing method described above includes a clutch plate having a tooth portion on the outer peripheral side, The present invention can also be suitably applied to manufacture of a clutch plate having teeth on the inner peripheral side and the outer peripheral side.

Furthermore, in the above-described embodiment, the case where the ring-shaped plate-like member 15 is created by coining the enlarged-diameter portion 14 obtained in the dividing step is illustrated, but the ring-like plate-like member 15 is formed by pressing. You may make it create.
In such a case, the ring-shaped base 140 is pressed with a pressure that is not greatly compressed in the axial direction of the center line X, so that the variation in the shape of the finally obtained plate-like member 15 can be reduced as in the case of coining. .

DESCRIPTION OF SYMBOLS 10 Metal plate 11 Plate-shaped member 12 Remaining material 12a Opening 13 Base material 13b1 End part 13b2 Base point 13, 13A, ..., 13X Base material 13a Bottom part 13b Peripheral wall part 14 Expanded part 140 Base part 140a Inner circumference 140b Outer circumference 15 Plate shape Member 150 Base 150a Inner circumference 150b Outer circumference 16 Clutch plate 160 Base portion 161 Teeth portion 17 Remaining material Kp Clutch plate Kp 'Clutch plate P1 Metal plate X Center line Z Horizontal line

Claims (4)

On one end side in the longitudinal direction of the bottomed cylindrical substrate to which the other end is sealed in the longitudinal direction, and the enlarged diameter portion forming step of forming a radially enlarged portion whose diameter increases toward the one end,
A dividing step of dividing a cylindrical base material of the bottom in which the enlarged diameter portion is formed, and the enlarged diameter portion, the cylindrical base material of the new bottomed said radially enlarged portion is removed,
A press step for creating a ring-shaped plate-like member by pressing the expanded portion obtained in the dividing step;
A punching step of obtaining a ring-shaped clutch plate by punching the ring-shaped plate member,
While the length in the longitudinal direction of the new bottomed cylindrical base material obtained in the dividing step is a length capable of forming the enlarged diameter portion in the enlarged diameter portion forming step, the dividing step is performed. Using the obtained new bottomed cylindrical base material, the enlarged-diameter portion forming step, the dividing step, the pressing step, and the punching step are performed. Method. Before front Symbol enlarged diameter portion forming step, the aperture of the circular plate-shaped member, said diaphragm forming a bottomed cylindrical substrate, the clutch plate according to claim 1, characterized in that it comprises Production method.   The method of manufacturing a clutch plate according to claim 2, further comprising a circular punching step of obtaining the circular plate-like member by punching a metal plate before the drawing step. In the dividing step, the bottomed cylindrical base material on which the expanded diameter portion is formed is cut at a base end of the expanded diameter portion, and the expanded diameter portion and the expanded diameter portion are removed. The method for manufacturing a clutch plate according to any one of claims 1 to 3, wherein the method is divided into a bottomed cylindrical base material.

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