JP2009014082A - Manufacturing method and device for clutch drum - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a manufacturing method and device for a clutch drum capable of obtaining higher processing accuracy while adopting simple press working. <P>SOLUTION: This method for manufacturing the clutch drum 10 having a spline groove 14 formed in a cylindrical bottomed cylindrical part includes: a die receiving process P3 of making an outer peripheral side of the cylindrical part abut on a receiving face 41 of a die 40; a trimming process P4 of then, moving a trimming punch 53 from inside to outside to trim a cylindrical tip part 19 to a predetermined length; a punching process P5 of moving a hole punching punch 60 from inside to outside and punching an oil hole 15 after the trimming process P4; a groove forming process P6 of moving a groove forming punch 58 from inside to outside and forming a snap ring groove 17 on the inner peripheral side in the axial position between the cylindrical tip part 19 and the oil hole 15 after the punching process P5; and a die retracting process P8 of then, retracting the die 40. The device achieves the manufacturing method. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a method and apparatus for manufacturing a clutch drum suitable for a wet multi-plate clutch used in an automatic transmission of an automobile or the like.

  Conventionally, a general automatic transmission of an automobile has a wet multi-plate clutch incorporated therein. This clutch generally includes a clutch drum which is a bottomed cylindrical rotating body. The clutch drum includes a hydraulic piston and a plurality of clutch plates. The clutch plate includes a plurality of friction plates and a plurality of metal plates to which a friction material is affixed, and these are arranged coaxially and alternately.

  One of the friction plate and the metal plate is engaged with the input side member and the other is engaged with the output side member by spline fitting. Here, the clutch drum is either an input side member or an output side member. In other words, one of the friction plate and the metal plate is spline-fitted with the clutch drum. Therefore, a spline groove for spline fitting is formed in the cylindrical portion (at least the inner peripheral side) of the clutch drum.

  The hydraulic piston is provided on the bottom side (closed side) of the clutch drum with respect to the clutch plate. On the other hand, a snap ring that receives the pressing force of the hydraulic piston (via the clutch plate) is provided on the opposite side of the hydraulic piston in the axial direction with respect to the clutch plate, that is, on the open end side of the clutch drum. The snap ring is fitted and held in a snap ring groove formed on the inner peripheral side of the clutch drum.

  When the hydraulic piston is not actuated, an appropriate gap is secured between the clutch plates so that they can rotate relative to each other. That is, the clutch is in a released state, and no power is transmitted from the input side to the output side.

  When the hydraulic piston is activated, the hydraulic piston presses the clutch plate. The pressed clutch plates are pressed against each other, and relative rotation is prohibited. That is, the clutch is engaged and power is transmitted from the input side to the output side.

Patent Document 1 discloses a technique for obtaining a clutch drum with high dimensional accuracy with a small number of steps for such a clutch drum. According to the method for manufacturing a clutch drum described in Patent Document 1, a process (trimming process) for trimming the front end of the cylindrical portion of the clutch drum by a press process using a punch and a die, and a groove forming process for a snap ring groove are performed. Done at the same time.
JP 2000-230574 A

  However, there has been a problem that the manufacturing method disclosed in Patent Document 1 is insufficient to further improve the processing accuracy.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a clutch drum manufacturing method and a manufacturing apparatus capable of obtaining higher processing accuracy while adopting simple press processing.

  The invention according to claim 1 for solving the above-mentioned problem is a manufacturing method of a clutch drum in which a spline groove is formed in a cylindrical part having a bottomed cylindrical shape made of sheet metal, and the outer peripheral side of the cylindrical part is a receiving surface of a die. A die receiving step for abutting on the die, and after the die receiving step, a trimming punch is moved from the radially inner side to the outer side of the cylindrical portion to trim the open end portion of the cylindrical portion to a predetermined axial length. A drilling step of moving the punching punch from the radially inner side to the outer side of the cylindrical portion, and drilling an oil hole penetrating the cylindrical portion in the radial direction after the trimming step; and the groove forming punch of the cylindrical portion A groove forming step of forming a snap ring groove on the inner peripheral side of the axial position between the tip portion of the cylindrical portion and the oil hole after the drilling step, The above groove After step, characterized in that it comprises a die retracting step for retracting the dies.

  According to a second aspect of the present invention, there is provided a clutch drum manufacturing apparatus in which a spline groove is formed in a cylindrical portion having a bottomed cylindrical shape made of sheet metal, a die for receiving the outer peripheral side of the cylindrical portion, and an open side of the cylindrical portion. A trimming punch for trimming the tip portion to a predetermined length in the axial direction, a punch for making an oil hole penetrating the cylindrical portion in the radial direction, and a shaft between the tip portion and the oil hole of the cylindrical portion A groove forming punch for forming a snap ring groove on the inner peripheral side of the directional position, and the trimming punch, the punching punch and the groove forming punch in the state where the outer peripheral side of the cylindrical portion is received by the die. A drive mechanism that moves from the inside to the outside of the part, performs the processing by the trimming punch, then performs the processing by the hole punch, and then performs the processing by the groove forming punch. The features.

  According to a third aspect of the present invention, in the clutch drum manufacturing apparatus according to the second aspect, the trimming punch, the perforating punch, and the groove forming punch machine a part in the circumferential direction of the clutch drum in a single machining. The machining position is sequentially shifted in the circumferential direction, and machining is performed a plurality of times to complete machining on the entire circumference.

  According to a fourth aspect of the present invention, in the clutch drum manufacturing apparatus according to the second or third aspect, the trimming punch, the perforating punch and the groove forming punch are integrated with each other and are driven simultaneously by the driving mechanism. It is characterized by that.

  According to the first aspect of the present invention, as described below, it is possible to obtain higher processing accuracy while adopting simple press processing.

  As a result of earnestly researching the factors that deteriorate the machining accuracy, the inventors of the present invention have found that the deformation (plastic deformation) of the workpiece (in this case, the clutch drum) in each machining process affects other machining processes. It was. For example, when trimming and grooving are performed as disclosed in Patent Document 1, a relatively large deformation occurs in the workpiece in the trimming. When the trimming process and the groove forming process are performed simultaneously, the groove forming process is performed while the workpiece is deformed in the trimming process. Therefore, the deformation in the trimming process affects the formation of the snap ring groove, and the processing accuracy of the snap ring groove is lowered.

  Therefore, according to the present invention, the groove forming process is performed after the trimming process, that is, after the deformation by the trimming process is completed. Therefore, the deformation in the trimming process does not affect the formation of the snap ring groove, and the desired processing accuracy of the snap ring groove can be obtained.

  Incidentally, an oil hole penetrating in the radial direction is provided in the cylindrical surface (spline groove forming portion) of the clutch drum according to the present invention. Oil (ATF: automatic transmission oil in the case of an automatic transmission) passes through this oil hole, so that lubricity and cooling performance are improved. The oil hole is provided on the closed end side (the bottom of the bottomed cylinder) with respect to the snap ring groove.

  In the present invention, the drilling of the oil hole is performed after the trimming process and before the groove forming process. By performing the hole machining after the trimming process, it is possible to suppress the deformation of the workpiece in the trimming process from reducing the machining accuracy of the hole machining. Similarly, by performing the groove forming process after the hole processing, it is possible to suppress the deformation of the workpiece in the hole processing from lowering the processing accuracy of the groove forming process.

  The trimming process, the hole process, and the groove forming process are sequentially performed, and these processes are performed between the die receiving process and the die retracting process. That is, it is performed without retracting the die that receives the outer peripheral side of the cylindrical portion. By doing so, the retracting of the trimming punch or the punching punch can be delayed until the groove forming step is completed. If the trimming punch or punching punch is left unretracted after trimming or drilling, the workpiece in the vicinity of the processed part is in close contact with the die under the processing load. The groove forming part (snap ring groove) is between the trimming part (cylindrical tip) and the hole processing part (oil hole) in the axial direction. Therefore, at the time of the groove forming step, the workpieces on both sides in the axial direction of the processed portion are in close contact with the die due to the processing load of trimming processing or hole processing. Therefore, grooving can be performed in a stable state where the degree of constraint of the workpiece is high, and the processing accuracy can be further increased.

  Further, when machining with each punch, a phenomenon occurs in which the workpiece bites into the punch (fixes slightly). When the punch is retracted, the workpiece is dragged by the punch and slightly deforms. In the configuration of the present invention, the retraction of each punch can be delayed until the groove forming step is completed, so that the deformation due to the biting does not affect the hole processing or groove forming processing in the subsequent step. Therefore, the processing accuracy can be further increased.

  According to invention of Claim 2, the manufacturing apparatus which performs the manufacturing method of Claim 1 exactly can be obtained.

  According to the invention of claim 3, the effect of improving the machining accuracy can be obtained more remarkably as described below. According to the configuration of the present invention, the trimming process, the hole process, and the groove forming process process a part in the circumferential direction in a single process. In this way, the movement of the punch can be simplified and the apparatus can be simplified. On the other hand, however, the deformation due to each process is accumulated, and the clutch drum as a whole tends to be relatively large. In such a manufacturing apparatus, the configuration of the present invention, in particular, the configuration in which processing is performed by the trimming punch, the punching punch, and the groove forming punch without retracting the die in the middle, is for retracting the die for each processing. In comparison, the deformation at the time of punch retraction can be greatly suppressed, and a significant improvement in machining accuracy can be obtained.

  According to invention of Claim 4, each punch can be driven with one drive mechanism. Therefore, the drive mechanism can be simplified compared to the case where each punch is driven by an individual drive mechanism, and the apparatus can be miniaturized. In order to sequentially perform the processing by each punch, the radial length of each punch may be adjusted to shift the timing at which the tip of each punch reaches the inner periphery of the clutch drum cylindrical portion. Further, when the punch is retracted, all the punches are retracted at the same time. This is advantageous because the retracting of the trimming punch and the groove forming punch is delayed until after the groove forming process.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 is a partial cross-sectional view of an automatic transmission 1 including a clutch drum 10 according to an embodiment of the present invention. The automatic transmission 1 is a multi-stage transmission type and includes a clutch / brake mechanism 3 inside a mission case 2. The clutch / brake mechanism 3 includes a plurality of clutches and brakes. The clutch / brake mechanism 3 is configured to be fastened or released by a hydraulic mechanism (not shown) and achieve a predetermined shift speed by a combination thereof.

  Since the clutch / brake mechanism 3 is a known mechanism, a detailed description thereof will be omitted. The clutch / brake mechanism 3 includes a 3/4 clutch 5 that is engaged at the third speed and the fourth speed. The 3/4 clutch 5 includes a clutch drum 10 which is a bottomed cylindrical rotating body. A clutch pack 6 and a hydraulic piston 7 are built in the clutch drum 10. The clutch pack 6 includes a plurality of clutch plates. The clutch plate includes a plurality of friction plates and a plurality of metal plates to which a friction material is affixed, and these are arranged coaxially and alternately.

  In the clutch pack 6 of this embodiment, the metal plate is on the input side and the friction plate is on the output side. The clutch drum 10 is spline-fitted to the outer peripheral side of the metal plate by a spline groove 14 (see FIG. 2) formed on the inner peripheral side thereof. On the other hand, the friction plate is spline-fitted with the output side member on the inner peripheral side thereof.

  The hydraulic piston 7 is provided on the bottom side (closed side) of the clutch drum 10 with respect to the clutch pack 6. On the other hand, a snap ring 8 that receives the pressing force of the hydraulic piston 7 via the clutch pack 6 is provided on the opposite side of the hydraulic piston 7 across the clutch pack 6, that is, in the vicinity of the open end of the clutch drum 10. . The snap ring 8 is fitted and held in a snap ring groove 17 (see FIG. 2) formed on the inner peripheral side of the clutch drum 10.

  When the hydraulic piston 7 is not in operation, an appropriate gap is secured between the clutch plates of the clutch pack 6 so that they can rotate relative to each other. That is, the 3/4 clutch 5 is in the released state, and no power is transmitted from the input side to the output side.

  When the hydraulic piston 7 is operated, the hydraulic piston 7 presses the clutch pack 6. The clutch plates of the pressed clutch pack 6 are pressed against each other, and relative rotation is prohibited. That is, the clutch is engaged and power is transmitted from the input side to the output side.

  FIG. 2 is a perspective view of the clutch drum 10. The vertical direction in the figure is the axial direction of the clutch / brake mechanism 3. As described above, the clutch drum 10 is made of sheet metal and has a bottomed cylindrical shape, and a shaft hole 12 through which a shaft member is passed is provided at the bottom. A spline groove 14 extending in the axial direction is formed in the cylindrical portion of the clutch drum 10. The spline groove 14 is composed of 32 concave portions 14a and convex portions 14b arranged alternately.

  Sixteen oil holes 15 penetrating in the radial direction are formed in the cylindrical portion of the clutch drum 10 where the spline grooves 14 are formed. The oil hole 15 is provided in one jump of the 32 convex portions 14b. The oil hole 15 has an effect of improving lubricity and cooling performance of the 3/4 clutch 5 and its peripheral members by passing ATF (automatic transmission oil) through the oil hole 15.

  In the axial direction of the clutch drum 10, a snap ring groove 17 into which the snap ring 8 is fitted is formed between the open end (cylindrical tip 19) of the cylindrical portion and the oil hole 15. The snap ring groove 17 is provided over the entire circumference of the spline groove 14, but since the groove depth does not reach the convex part 14b, the groove forming process is actually performed on the concave part as shown in the figure. 14a. The snap ring groove 17 (where the groove is formed) finally receives the pressing force of the hydraulic piston 7 received by the snap ring 8 by holding the snap ring 8.

  Next, the manufacturing method and manufacturing apparatus of the clutch drum 10 will be described. As described above, the clutch drum 10 is made of sheet metal. First, a punching process and a drawing process are performed on a single metal plate by a pressing device (not shown) to form a schematic shape. That is, the bottomed cylindrical shape of the clutch drum 10, the shaft hole 12, and the spline groove 14 are formed. The axial length of the cylindrical portion in the general shape (the height of the cylindrical tip 19) is longer than the completed dimension, and the cylindrical portion has an excess portion.

  FIG. 3 is a plan view of the manufacturing apparatus 20 that performs additional machining on the clutch drum 10 having a schematic shape. Additional processes performed by the manufacturing apparatus 20 include trimming processing for trimming the cylindrical tip 19 of the clutch drum 10 to a predetermined length in a predetermined axial direction, hole processing for opening the oil hole 15, and groove forming for forming the snap ring groove 17. It is processing.

  These processes are performed by the punch 52 and the die 40. The manufacturing apparatus 20 is provided with a mechanism for causing the punch 52, the die 40, and the clutch drum 10 to be processed (hereinafter also referred to as a workpiece 10) to perform a predetermined operation.

  As a schematic configuration of the manufacturing apparatus 20, a driving mechanism 30, a die 40, a punch unit 50, and a jig 70 for fixing the workpiece 10 are provided. The drive mechanism 30 includes a first hydraulic cylinder 31 and a second hydraulic cylinder 35 whose axial centers overlap in plan view. A rod 32 is connected to the first hydraulic cylinder 31, and a rod 36 is connected to the second hydraulic cylinder 35. A die 40 and a punch 52 are connected to the rod 32, and a punch 52 is connected to the rod 36.

  The first hydraulic cylinder 31 moves the rod 32 toward the axis of the workpiece 10 (in the direction of arrow A1). And the processing load of the punch 52 which the die | dye 40 receives is received. On the other hand, the second hydraulic cylinder 35 moves the rod 36 in a direction away from the axis of the workpiece 10 (arrow A2 direction). And the workpiece | work 10 is pressed from an inner peripheral side with the punch 52, and is processed.

  The punch unit 50 includes a punch 52 and a guide 51 that supports and guides the punch 52. The punch 52 comes into contact with two peaks (one peak is a pair of recesses 14a and protrusions 14b) of the spline groove 14 of the workpiece 10 on the front end side (left side in FIG. 3) to perform processing.

  On the other hand, the die 40 is in contact with the two peaks of the spline groove 14 of the workpiece 10 from the outside on the tip side (the right side in FIG. 3), and receives a processing load by the punch 52.

  By the punch 52 and the die 40 as described above, a part of the workpiece 10 in the circumferential direction (two peaks of the spline groove 14) is processed by one processing (one stroke of the rod 36). Hereinafter, this one-time processing is referred to as a processing unit U1. The processing unit U1 includes a moving process of the die 40 and the punch 52 (see FIG. 5). The manufacturing apparatus 20 includes a table 71 (shown in FIG. 4) on which the workpiece 10 is placed. The table 71 can be moved up and down (in a direction perpendicular to the paper surface shown in FIG. 3) and around the axis of the workpiece 10. It is configured to be rotatable. The manufacturing apparatus 20 is configured to process the entire circumference (32 mountains) by the machining unit U1 for a total of 16 times while rotating the table 71 and shifting by two mountains of the spline groove 14 per machining unit U1. ing.

  4 is a cross-sectional view taken along line IV-IV in FIG. The workpiece 10 is fixed by a jig 70. The jig 70 includes the table 71, a holding jig 72 for fixing the outer peripheral side of the workpiece 10, and a pressing jig 73 for fixing the inner peripheral side. The workpiece 10 is placed on the table 71 with the end of the cylindrical portion facing upward, and is fixed by holding jigs 72 and 73.

  The punch section 50 is provided on the inner peripheral side of the workpiece 10 and includes a punch 52 with the processing section directed radially outward. Specifically, the punch 52 includes a trimming punch 53, a groove forming punch 58, and a punching punch 60 in order from the top. These punches are integrated with each other and are driven simultaneously by the drive mechanism 30.

  The trimming punch 53 is a punch that trims and aligns the open end of the cylindrical portion of the workpiece 10 to a predetermined length in the axial direction, that is, a punch that performs trimming. Inside the trimming punch 53, a pair of upper and lower eject pins 54 are provided. Each eject pin 54 is urged radially outward by a spring 55. When the trimming process is not performed and no processing load is applied to the tip 53 a of the trimming punch 53, the tip of the eject pin 54 protrudes from the tip 53 a of the trimming punch 53 by the biasing force of the spring 55. During trimming, the spring 55 contracts due to the processing load, and the eject pin 54 is completely stored in the trimming punch 53. With such a configuration, the eject pin 54 jumps the scrap generated by the trimming process to the die 40 side.

  The groove forming punch 58 is a punch for forming the snap ring groove 17 on the inner peripheral side of the cylindrical portion of the workpiece 10, that is, a punch for performing groove forming processing. The thickness of the groove forming punch 58 is the groove width of the snap ring groove 17.

  The hole punch 60 is a punch for drilling an oil hole 15 penetrating in a radial direction in a cylindrical portion of the workpiece 10 (specifically, a convex portion 14b of the spline groove 14), that is, a punch for performing hole processing. An air passage 62 that opens to the tip 60a is provided inside the punching punch 60, and compressed air is supplied to the air passage 62 from a compressed air supply unit (not shown). By the compressed air ejected from the opening of the air passage 62, scrap generated by drilling is blown off to the die 40 side.

  As described above, the trimming punch 53, the groove forming punch 58, and the punching punch 60 are integrated with each other, but the radial length of each punch is in the order of the trimming punch 53, the punching punch 60, and the groove forming punch 58. It is getting longer. Therefore, as will be described later, when these punches are simultaneously driven, trimming processing is first performed by the trimming punch 53, then hole processing is performed by the punching punch 60, and finally groove forming processing by the groove forming punch 58 is performed. Will be done.

  The die 40 is a member that receives the processing load of the punch 52 by bringing the receiving surface 41 into contact with the outer peripheral side of the workpiece 10. The die 40 is formed with a scrap discharge groove 43 and a scrap discharge hole 45. These are passages for guiding scrap generated by trimming or drilling to the outside of the die 40. A scrap collecting unit 25 that collects the discharged scrap is provided outside the die 40.

  Next, the operation of the manufacturing apparatus 20 and a method for manufacturing the clutch drum 10 by the manufacturing apparatus 20 will be described.

  FIG. 5 is a schematic manufacturing process diagram of the manufacturing apparatus 20. First, in a state where the die 40 and the punch portion 50 (punch 52) are in the retracted position shown in FIG. 4, the workpiece 10 is fixed at the position shown in FIG. 4 (process P1). In the process P1, the table 71 that can be moved up and down is lowered to a position where the workpiece 10 and the punch unit 50 do not interfere with each other. Then, the workpiece 10 is placed at a predetermined position on the table 71 and is held by the holding jig 72. In this state, the table 71 rises and is set in the state shown in FIG. 4, and the work 10 is pressed and fixed by the holding jig 73.

  Next, “1” is input to the processing unit number N (processing P2). The processing unit number N is a numerical value for counting how many times the processing unit U1 has been performed.

  Next, a die receiving process P3, a trimming process P4, a punching process P5, a groove forming process P6, a punch retracting process P7, and a die retracting process P8 are sequentially performed. A series of steps (a portion surrounded by a broken line) of the die receiving step P3 to the die retreating step P8 is a processing unit U1.

  Next, it is determined whether or not the processing unit number N = 16 (determination P9). If NO is determined here, the workpiece 10 is rotated by two peaks (1/16 rotation: 22.5 degrees) of the spline groove 14. At this time, the operations for raising and lowering the table 71 may be appropriately combined. In step P10, a process of incrementing (+1) the processing unit number N is performed. Then, the process returns to the die receiving process P3, and the processing unit U1 is repeated for the new processing part.

  On the other hand, if it is determined YES in the determination P9, it means that the entire work (32 spline grooves 14) has been processed. Therefore, the work 10 is taken out (step 11) and processed by the manufacturing apparatus 20. Is completed.

  Hereinafter, the main steps will be described in more detail.

  FIG. 6 is an explanatory view showing the die receiving process P3. The die receiving step P3 is a step of bringing the outer peripheral side of the cylindrical portion of the workpiece 10 into contact with the receiving surface 41 of the die 40. In the die receiving process P3, the die 40 and the punch 52 are moved in the arrow A1 direction by the rod 32 of the first hydraulic cylinder 31. When the receiving surface 41 of the die 40 comes into contact with the cylindrical portion side surface (spline groove 14) of the workpiece 10, the contact is electrically sensed by a sensor (not shown), and the movement of the rod 32 is stopped. P3 is completed. FIG. 6 shows a state in which the die receiving step P3 is completed and the die 40 is ready to receive a machining load.

  FIG. 7 is an explanatory diagram showing the trimming step P4. The trimming process P4 is a process for performing the trimming process. In the trimming step P4, the second hydraulic cylinder 35 moves the punch 52 in the arrow A2 direction via the rod 36. Then, when the front end 53a of the trimming punch 53 reaches the inner peripheral side of the workpiece 10, trimming is started. At this time, the eject pin 54 is completely stored in the trimming punch 53 as the spring 55 contracts, so that the processing is not adversely affected. FIG. 7 shows a state at the start of trimming in the trimming step P4.

  FIG. 8 is an explanatory diagram showing the trimming process P4 and the hole making process P5. When the punch 52 is further moved in the arrow A2 direction from the state shown in FIG. 7, the surplus portion at the tip is cut off as the scrap 19a by the shearing force between the trimming punch 53 and the die 40, and the cylindrical tip is trimmed to a predetermined length. 19 is formed. The trimming process P4 is completed when the scrap 19a is completely cut off. The front end of the eject pin 54 protrudes from the front end 53 a of the trimming punch 53 by the biasing force of the spring 55 from just before the completion of the trimming process P 4 to after the completion. Then, the scrap 19a generated by the trimming process is skipped to the die 40 side. The scrap 19 a that has been bounced off is guided to the scrap collection unit 25 via the scrap discharge groove 43.

  In the punching process P5 after the trimming process P4, the punch 52 further moves in the arrow A2 direction. When the tip 60a of the punch 60 reaches the inner peripheral side of the workpiece 10 (specifically, the convex portion 14b of the spline groove 14), drilling is started. FIG. 8 shows a state at the start of drilling in the drilling step P5.

  FIG. 9 is an explanatory view showing the hole making step P5 and the groove forming step P6. When the punch 52 further moves in the direction of the arrow A2 from the state of FIG. 8, the scrap 15a is punched by the shearing force of the punching punch 60 and the die 40, and the oil hole 15 is formed. When the scrap 15a is completely punched, the punching process P5 is completed. The punched scrap 15 a is blown off by the compressed air supplied through the air passage 62 and guided to the scrap collection unit 25 through the scrap discharge hole 45.

  Although the oil hole 15 is formed in the convex portion 14b of the spline groove 14, it is skipped by one mountain, that is, provided at two locations. Accordingly, one oil hole 15 is formed per processing unit U1.

  In the groove forming step P6 after the punching step P5, the punch 52 further moves in the direction of the arrow A2. When the tip 58a of the groove forming punch 58 reaches the inner peripheral side of the workpiece 10 (specifically, the concave portion 14a of the spline groove 14), the groove forming process is started. FIG. 9 shows a state at the time of starting the groove forming process in the groove forming process P6. When the punch 52 further moves in the arrow A2 direction from the state shown in FIG. 9, the tip 58a of the groove forming punch 58 presses the concave portion 14a of the spline groove 14, and the snap ring groove 17 is formed. In the groove forming step P6, the snap ring groove 17 is formed in the concave portions 14a on both sides of the convex portion 14b in which the oil holes 15 are formed.

  In the subsequent punch retracting process P7 after the completion of the groove forming process P6, the punch 52 (punch part 50) is retracted via the rod 36 by the second hydraulic cylinder 35. That is, the punch 52 (punch part 50) is moved in the direction opposite to the arrow A2.

  In the die withdrawal step P8 after the punch withdrawal step P7, the die 40 is withdrawn via the rod 32 by the first hydraulic cylinder 31. That is, it is moved in the direction opposite to the arrow A1 (shown in FIG. 6). The start point of the die evacuation process P8 may be before the completion of the punch evacuation process P7. That is, the punch retracting process P7 and the die retracting process P8 may partially overlap.

  Thus, the processing unit U1 is repeated until it is determined as YES (processing unit number N = 16) in the determination P9.

  As described above, according to the manufacturing apparatus 20, in one processing unit U1, the drilling process P5 is performed after the trimming process P4, and the groove forming process P6 is performed after the drilling process P5. When trimming or drilling is performed, slight deformation (plastic deformation) occurs in the workpiece 10. However, since the processes P4, P5, and P6 are performed separately as described above, the deformation due to the trimming process does not affect the subsequent hole processing or the groove forming process, and the deformation due to the hole processing is similarly performed in the subsequent groove. Does not affect the molding process. Therefore, the machining accuracy of the hole machining and the groove forming can be improved as compared with the processes P4, P5, and P6 that are performed simultaneously or overlappingly.

  Further, in one processing unit U1, the trimming process P4, the drilling process P5, and the groove forming process P6 are performed between the die receiving process P3 and the die retracting process P8. That is, it is performed without retracting the dice 40 in the middle. Further, since the punches 53, 58 and 60 are driven simultaneously, the grooving is performed in a state where the trimming punch 53 and the punching punch 60 are not retracted. When these punches 53 and 60 are in the unretracted state, the workpiece 10 near the cylindrical tip 19 and the oil hole 15 is in close contact with the die 40 due to the processing load of each punch 53 and 60. Since the groove forming process can be performed in a stable state in which the degree of restraint of the workpiece 10 is high, the processing accuracy can be further increased.

  Further, when machining is performed with each of the punches 53 and 60, a phenomenon occurs in which the workpiece 10 bites into each of the punches 53 and 60. When the punches 53 and 60 are retracted in the punch retracting process P7, the work 10 is dragged by the punches 53 and 60 due to the biting, and is slightly deformed. According to the present embodiment, since all the punches 53, 58, 60 are retracted after the groove forming step P6 is completed, the deformation due to the biting does not affect the hole processing or the groove forming processing. Therefore, the processing accuracy is further improved.

  Moreover, according to the manufacturing apparatus 20, the process for two piles of the spline groove | channel 14 is performed per process unit U1. Therefore, the movement operation of the die 40 and the punch 52 can be made a simple linear motion, and the apparatus can be simplified.

  However, when such a processing method is adopted, the deformation for each processing unit U1 is accumulated, and the workpiece 10 as a whole tends to be relatively large. However, since the manufacturing apparatus 20 does not retract the die 40 in the middle of the processing unit U1 and does not retract the pre-processed punch, the manufacturing apparatus 20 can move the die 40 for each processing (trimming processing, hole processing) as compared with the device that retracts the die 40. Ten deformations (stacking) can be greatly suppressed.

  Furthermore, since the punch 52 is integrated in the manufacturing apparatus 20, the punch 52 can be driven by one drive mechanism 30. Therefore, the drive mechanism 30 can be simplified compared with the case where the trimming punch 53, the groove forming punch 58, and the punching punch 60 are driven by individual drive mechanisms, and the apparatus can be downsized.

  As mentioned above, although each embodiment of this invention was described, the said embodiment can be suitably changed in the range which does not deviate from the summary of this invention. For example, in the above-described embodiment, the trimming punch 53, the groove forming punch 58, and the punching punch 60 are integrated with each other and driven at the same time. However, some or all of them may be separated and driven independently. good.

  The number of spline grooves 14 is not limited to 32. Further, the number of peaks processed in one processing unit is not limited to two. For example, it may be processed one mountain or three or more.

  The clutch drum 10 does not need to constitute the 3/4 clutch 5, and may be a clutch drum applied to other clutches having a similar structure. Further, the present invention is not limited to the one used in the automatic transmission, and can be applied to any clutch drum having the same mechanism.

1 is a partial cross-sectional view of an automatic transmission including a clutch drum according to an embodiment of the present invention. It is a perspective view of the clutch drum. It is a top view of the manufacturing apparatus which performs an additional process to the clutch drum in which the general shape was formed. It is the IV-IV sectional view taken on the line of FIG. It is a schematic manufacturing-process figure of the said manufacturing apparatus. It is explanatory drawing which shows the die receiving process by the said manufacturing apparatus. It is explanatory drawing which shows the trimming process following the said die receiving process. It is explanatory drawing which shows the said trimming process and the subsequent drilling process. It is explanatory drawing which shows the said drilling process and the groove | channel formation process following it.

Explanation of symbols

10 Clutch drum, work 14 Spline groove 15 Oil hole 17 Snap ring groove 19 Cylindrical tip (opening tip of cylindrical part)
20 Manufacturing Equipment 30 Drive Mechanism 40 Dies 53 Trimming Punch 58 Groove Punch 60 Hole Punch P3 Die Receiving Process P4 Trimming Process P5 Hole Drilling Process P6 Groove Forming Process P8 Die Retraction Process U1 Machining Unit (Once Processing)

Claims (4)

In the manufacturing method of the clutch drum in which the spline groove is formed in the cylindrical portion of the bottomed cylindrical shape made of sheet metal,
A die receiving step of bringing the outer peripheral side of the cylindrical portion into contact with the receiving surface of the die;
After the die receiving step, a trimming step of moving the trimming punch from the radially inner side to the outer side of the cylindrical portion and trimming the open end of the cylindrical portion to a predetermined length in the axial direction;
Moving the punch from the radially inner side to the outer side of the cylindrical portion, and after the trimming step, a drilling step of opening an oil hole penetrating in the radial direction in the cylindrical portion;
The groove forming punch is moved from the radially inner side to the outer side of the cylindrical portion, and after the drilling step, a snap ring groove is formed on the inner peripheral side of the axial position between the tip portion of the cylindrical portion and the oil hole. A groove forming process for forming,
A method for manufacturing a clutch drum, comprising: a die retreating step of retracting the die after the groove forming step. In a clutch drum manufacturing apparatus made of sheet metal and having a spline groove formed in a cylindrical portion having a bottomed cylindrical shape,
A die for receiving the outer peripheral side of the cylindrical portion;
A trimming punch that cuts and aligns the open end of the cylindrical portion to a predetermined length in the axial direction;
A punch for punching an oil hole penetrating in the radial direction in the cylindrical portion;
A groove forming punch for forming a snap ring groove on the inner peripheral side of the axial position between the tip portion and the oil hole of the cylindrical portion;
In a state where the outer peripheral side of the cylindrical portion is received by the die, the trimming punch, the punching punch, and the groove forming punch are moved from the inner side to the outer side of the cylindrical portion, and then the processing by the trimming punch is performed. An apparatus for manufacturing a clutch drum, comprising: a drive mechanism that performs processing by the hole punch and then performs processing by the groove forming punch.   The trimming punch, the hole punch, and the groove forming punch process a part of the clutch drum in the circumferential direction in a single process, and perform a plurality of processes by sequentially shifting the processing position in the circumferential direction. 3. The clutch drum manufacturing apparatus according to claim 2, wherein the machining of the entire circumference is completed.   4. The clutch drum manufacturing apparatus according to claim 2, wherein the trimming punch, the hole punch and the groove forming punch are integrated with each other and are driven simultaneously by the driving mechanism.

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