JP2011025277A - Method of producing metallic member - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of producing a metallic member that reduces the burden on a mold during molding. <P>SOLUTION: The method of producing the metallic member includes: the step of forming a cup-like member 11-2 by applying to a metallic plate member 11-1, a load having a component that is perpendicular to a surface of the plate member 11-1; and the step of forming a plurality of protrusions at an opening end portion 51 of the cup-like member 11-2 by placing the cup-like member into a mold and applying to the cup-like member 11-2, a load having a component that is perpendicular to the bottom surface of the cup-like member 11-2. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a method for manufacturing a metal member. In particular, the present invention relates to a method for manufacturing a metal member having a plurality of protrusions such as a vibrating body or a gear member for a vibration wave driving device.

  As a metal member in which a plurality of protrusions are arranged, there is a vibrating body for a vibration wave driving device as shown in Patent Document 1. This vibrating body has an annular shape or a disk shape, and has a plurality of comb-like projections on one surface (upper surface) side, and a base portion without comb teeth on the opposite surface (lower surface) side. A ring-shaped piezoelectric element is bonded to the surface (lower surface). This type of vibrator has a large number of protrusions formed by a method of cutting a large number of radial grooves using a disk-shaped milling cutter or a grindstone tool (a cutting process or a grinding process) or a method using a forging process. Yes. Note that the role of the comb-like projections is to increase vibration displacement when the vibration of the vibrating body is transmitted to the moving body by frictional force to rotate the moving body. Depending on the application, a hole for penetrating the output shaft may be provided at the center of the vibrating body.

  On the other hand, as another example of the metal member having a plurality of protrusions, there is a gear as shown in Patent Document 2. A gear (for example, a bevel gear (bevel gear)) having teeth as a plurality of protrusions has a hole that is cored to pass the shaft therethrough. Such a gear also has a case where a tooth portion is formed by using cutting or grinding, and a case where a tooth portion is formed by forging using a press device.

JP 07-135785 A JP 2001-205385 A

  Compared with a method using cutting or grinding, a method using forging is a low-cost processing method because the processing can be simplified.

  In order to form a large number of protrusions by forging, a ring or disk work piece obtained by cutting a pipe or a round bar is prepared, and the protrusions are formed by directly pressing the work piece. It is conceivable to form. FIG. 6 is a schematic diagram for explaining a state in which a protrusion is formed on a workpiece by forging. 6A is a cross-sectional view, and FIG. 6B is a perspective view. As shown in FIG. 6, the workpiece 111 is inserted into the inner diameter portion of the die ring 123 that is the outer frame of the fixing mold (female die) using the disk-shaped workpiece 111. Form the protrusion.

  However, this method has the following problems. As soon as the punch 122, which is a pressurizing mold (male mold), comes into contact with the workpiece 111, the stress applied to the female mold increases momentarily, so that the female mold is easily damaged. Moreover, since the force for reducing the thickness of the workpiece 111 sandwiched between the punch 122 and the female mold is applied to the mold simultaneously with the pressurization, the total load necessary for molding increases. In this respect, the mold is easily damaged. In particular, in the die 124 on which the projections and depressions are formed, stress is particularly concentrated on the thin portion 124a for forming a groove (a groove between the protrusions) on the outer peripheral lower surface of the disk-shaped workpiece. As the width of the groove is reduced, the thin portion 124a is thinned and the strength is reduced, and the thin portion is more likely to be damaged during forging. Therefore, in order to maintain the strength of the thin-walled portion 124a, the width of the groove between the protrusions has to be increased to some extent, and there is a restriction on the circumferential width of the protrusions of the gear and the vibrating body.

  Therefore, an object of the present invention is to easily mold a plurality of protrusions with an arbitrary width on a metal workpiece, and to reduce the burden on the mold during molding. .

  The method for producing a metal member of the present invention is a method for producing a metal member having a plurality of protrusions, and a cup is applied by applying a load having a component in a direction perpendicular to the surface of the plate member to the metal plate member. Applying a load having a component in a direction perpendicular to the surface of the bottom of the cup-shaped member to the cup-shaped member, and applying a plurality of the plurality of pieces to the opening end of the cup-shaped member by a mold. And a step of forming a protrusion.

  According to the present invention, when forming a metal member having a plurality of protrusions, it is possible to reduce the load applied to the mold when forming the protrusions without requiring cutting or grinding. . Moreover, it becomes possible to form the groove | channel between the projection parts of a molded article by arbitrary widths.

The schematic diagram which shows a mode that the cup-shaped member in 1st Embodiment is produced. The schematic diagram which shows a mode that the projection part in 1st Embodiment is formed. The schematic diagram which shows the cup-shaped member in 2nd Embodiment. Schematic diagram showing a state of producing a preform in the second embodiment The schematic diagram which shows a mode that the final shaping | molding in 2nd Embodiment is carried out. Schematic diagram showing conventional forging

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. Examples of the metal member used in the present invention include a vibration body for a vibration wave driving device having a protrusion for expanding vibration displacement, a gear having a tooth portion for output transmission, and the like.

(Embodiment 1)
In the present embodiment, as a metal member provided with a plurality of protrusions protruding in the same direction, a vibration body for a vibration wave drive device having a vibration expansion protrusion formed on the surface is taken as an example, and a manufacturing method thereof Will be explained. The vibration wave driving device has a vibrating body including a piezoelectric element that is one of electro-mechanical energy conversion elements, and generates a traveling wave on the surface of the vibrating body by supplying an alternating signal to the piezoelectric element. This traveling wave is used to drive the moving body that contacts the vibrating body.

  As shown in FIG. 1 (a), in this embodiment, a stainless steel (SUS420J2) disk 11-1, which is a plate member punched out by press working, is used as an inner diameter portion of a die forming positioning plate 26. Install in. Examples of the plate member include, in addition to stainless steel, a metal plate member made of SPC material, low alloy steel, high alloy steel, non-ferrous metal alloy, or the like. The die for drawing is composed of a male punch 22 and a female die. The female mold includes a die 24 in which a concave portion is formed, a die ring 23 as an outer frame that is a holding portion of the die 24, a knockout 25 for releasing a molded product from the female mold, and a positioning plate 26. .

  As shown in FIG. 1 (b), the punch 22 is pushed down to draw a load having a component in the out-of-plane direction (component in a direction perpendicular to the surface of the plate member). A cup-shaped member 11-2 as shown is formed. In the present invention, the cup-shaped member indicates a container-like shape having a bottom portion 52 and a side surface 53 formed on the outer periphery of the bottom portion, and the bottom portion 52 may be formed with a hole or a recess. As shown in FIG. 1C, the cup-shaped member has a width in the radial direction of the opening end portion 51 that is larger than the radial width of the projection of the final molded product (55 shown in FIG. 2D). It is preferable that the side surface 53 be formed to be higher than the height (the length in the direction perpendicular to the radial direction) of the projection of the final molded product. Although details will be described later, by forming in this way, the radial width of the opening end 51 is also increased at the same time in the process of reducing the height of the side surface 53, so that a mold for forming a projection in a later process is formed. Such a load is reduced. Moreover, it leads also to ensuring of the volume of a projection part.

  Furthermore, by forming the side surface 53 into an inclined surface that spreads outward with respect to the bottom portion 52, that is, by forming the outer diameter of the opening end portion 51 of the cup-shaped member larger than the outer diameter of the bottom portion 52 of the cup-shaped member, This is preferable because the molding load is reduced in the step of forming the protrusion in the subsequent step. This is because, as shown in FIG. 2 (b), the cup-shaped member is deformed so as to spread outward in the molding process, so that the load applied in the height direction of the thin portion 34a is reduced.

  Next, in order to soften the cup-shaped member 11-2, annealing heat treatment is performed at 750 ° C., for example. This heat treatment is for reducing the molding load and facilitating plastic deformation in the forging process for forming the protrusions in the subsequent process. Depending on the degree of drawing, the annealing and heat treatment may be omitted because the work hardening of the material does not progress so much and the deformation resistance does not increase so much. Thereafter, the surface of the cup-shaped member 11-2 may be lubricated. As the lubricating treatment, for example, a lubricant mainly composed of molybdenum disulfide is applied.

  FIG. 2A shows a state in which the cup-shaped member 11-2 is placed and positioned in a projection molding die. The mold for forming the protrusion includes a female mold including a die ring 33, a die 34, and a knockout 35, and a punch 32 that is a male mold. In the die 34, a groove into which the cup-shaped member is inserted is formed on the circumference, and thin portions 34a arranged at equal intervals in the circumferential direction are provided in the groove on the circumference. The inner peripheral wall of the groove is an inclined surface, and the closer to the bottom of the groove, the closer to the outer peripheral wall and the inner peripheral wall, the narrower the groove width in the radial direction. By making such a groove, as can be seen from FIGS. 2 (a) and 2 (b), when the punch is lowered, the opening end of the cup-shaped member tends to spread outward, and the inner peripheral wall is an inclined surface. It is preferable because it is difficult to inhibit plastic flow. By making the mold shape difficult to inhibit plastic flow, the possibility of mold breakage and defects (cracks, folds, etc.) of the molded product is reduced.

  The cup-shaped member is positioned at the inner diameter portion of the die ring 33, and the opening end portion thereof is disposed in contact with the upper end of the thin portion 34a (a part of the die 34) for forming a groove between the protruding portions.

  FIG. 2B shows a state in which the cup-shaped member is being deformed by applying a load having a component perpendicular to the bottom of the cup-shaped member as the punch 32 is lowered. At this stage, the load applied to the punch 32 and the thin portion 34a is relatively small, but the cup-shaped member is still deformed as a whole and compressed as indicated by 11-3, and the cup-shaped member 11- 3 is starting to form protrusions. Then, the load gradually increases as the punch 32 descends, and the entire molding is completed at the bottom dead center as shown in FIG. 2C, and the final molded product 11- as shown in FIG. 4 is obtained.

  By compression molding by this forging process, a projection 55 is formed at the opening end 51 of the cup-shaped member, and the width of the projection 55 in the radial direction is larger than the width of the opening end of the cup-shaped member. Further, the thickness of the bottom 54 of the final molded product is smaller than the thickness of the bottom 52 of the cup-shaped member. Thus, in the present embodiment, the stress applied to each part of the mold, particularly the thin part 34a, gradually increases during the molding process, and the circumferential force applied to the thin part is small, so that the thin part 34a is not damaged. The possibility decreases. In addition, since the excess thickness generated by thinning the bottom of the cup-shaped member escapes to the protrusion on the outer peripheral side (used for forming the protrusion), the load on the die and knockout is reduced, and deformation and breakage are prevented. The possibility is reduced. The shape of the side surface of the cup-shaped member and the protruding portion is not limited to the shape shown in the present embodiment as long as it can be deformed so as to increase the radial width of the protruding portion, that is, the plate thickness, by forging. For example, the protrusion may be inclined not only on the inner peripheral side but also on the outer peripheral side, or may have a uniform width.

  Furthermore, in the present embodiment, as a plate member that is a workpiece, a plate member that is thinner than the radial width in the groove of the die 34 (that is, the radial width of the projection of the molded product) can be used. Cost is also reduced. The reason will be described below.

  In the conventional method shown in FIG. 6, in order to make a disk of a workpiece, a round bar is cut using a band saw instead of cutting, but the thickness of the workpiece varies greatly, The parallelism was not good. Furthermore, there was a saw mark on the rounded surface, and the surface roughness was large. For this reason, variations in the partial thickness of the molded product were caused, and in particular, variations in individual protrusion heights were likely to occur. In addition, the saw mark of the workpiece remains on the molded end face, and grinding or the like is necessary to remove it. On the other hand, as described above, in the present embodiment, the work piece is larger than the diameter of the vibrating body that is the final molded product, such as a disk 11-1 shown in FIG. A plate member having a thickness 11-1 thinner than the thickness of the protrusion of the vibrating body can be used. Therefore, since a cheap rolled plate can be used compared with a round bar etc., the parallelism and raw material roughness of both surfaces are improved, and it becomes possible to reduce cost. In addition, since the thickness of the plate member is small, there is little change in the plate thickness when the bottom is set to a predetermined thickness (height), so work hardening does not progress so much and it is necessary to reduce the thickness of the bottom. Stress is also reduced, and die and knockout deformation and breakage are less likely to occur.

  In addition, the vibrating body manufactured according to the present embodiment can secure the mass of the protruding portion of the vibrating body in order to secure vibration energy, and can reduce the circumferential width of the thin-walled portion. It is possible to make the width of the groove formed between the two portions as small as possible. That is, the circumferential width of the protrusion can be increased, and the wear resistance of the protrusion that contacts the moving body can be improved.

  Further, in the vibration wave driving device, increasing the width in the circumferential direction of the protrusion by compression molding has an effect not only in improving wear resistance but also in suppressing unnecessary vibration. This is because the natural vibration frequency of the protrusion itself increases, so that unnecessary vibration due to the protrusion itself is less likely to occur.

  In the present invention, a method of forming a cup-shaped member by applying a load having a component in a direction perpendicular to the surface of the plate member to the plate member is not limited to drawing, but a method of three-dimensionally deforming the plate member. Any burring process, bulging process (embossing process), dish extrusion process (slip-shaped process), or the like may be used.

  The method of forming a protrusion by applying a load having a component perpendicular to the surface of the bottom of the cup-shaped member to the cup-shaped member is not limited to cold forging, hot forging, warm forging, or The plate member may be formed by forging.

  Also, using this embodiment, a vibrating body made of stainless steel (SUS420J2) having an outer diameter of 48 mm, a bottom thickness of 2.5 mm, a protruding portion radial width of 5 mm, and a protruding portion height of 4.5 mm is manufactured. did. The mold used for forming the protrusions has a width (the thinnest part) in the circumferential direction of the thin part of the die of 0.6 mm and a height of 4.5 mm. When manufacturing such a vibrating body, if a conventional method as shown in FIG. 6 is used, a load of 3 t or more is required, and since a large pressure is momentarily applied to the thin wall portion, there is a high possibility of breakage. It was. However, when the protrusion is created using the method of the present embodiment, an instantaneous load is not applied to the thin portion, and the total load is reduced, so that the burden on the mold during molding is reduced.

(Embodiment 2)
Next, a method for forming the protrusion of the vibrating body in the second embodiment will be described. In the present embodiment, the step of preforming the cup-shaped member between the point where the hole is provided in the center of the bottom of the cup-shaped member and the step of manufacturing the cup-shaped member and the step of manufacturing the final molded product This is different from the second embodiment.

  FIG. 3 shows the cup-shaped member 41-1 after drawing. This cup-shaped member is the same as the cup-shaped member of the first embodiment except that a circular hole 41-1a is opened by press punching in the center of the bottom 52. The circular hole may be opened at the stage of the plate member before being formed into the cup-shaped member, or may be opened when forming into the cup-shaped member or after being formed. This circular hole is for determining the center position in the next molding step. Therefore, it may be a dent instead of such a through hole.

  FIG. 4A shows a state in which the protrusion is formed by applying a load having a component in a direction perpendicular to the surface of the bottom 52 of the cup-shaped member to the cup-shaped member. The circular hole of the cup-shaped member is engaged with the positioning convex portion 42a at the tip of the punch 42 so that the center of the cup-shaped member 41-1 coincides with the center of the mold. This prevents the cup-shaped member from being eccentric while being compressed. The opening end 51 of the cup-shaped member is constrained by the inner diameter portion of the die ring 43, and the bottom 52 of the cup-shaped member, that is, the portion in contact with the punch 42 is parallel to the bottom surface in FIG. It can be fixed so as not to slip.

  The reason for constraining the center position by providing the circular hole in this way is related to the shape accuracy of the cup-shaped member 41-1 and the uniformity of its plastic deformation characteristics. In drawing, the shape accuracy of the molded product is often influenced by the degree of anisotropy when focusing on the plastic deformability of the material itself. Anisotropy results from the fact that the texture differs depending on the crystal orientation and the like depending on the material. For example, the properties of elongation, work hardening coefficient, elastic limit value, and Young's modulus differ between the rolling direction and the direction orthogonal thereto. As a result, there are also differences in the Rankford value (characteristic value representing the anisotropy of the plate material) and the springback amount (the amount that returns slightly to the state before processing due to the reaction force after bending). When a plate member having a strong anisotropy is drawn, there is a possibility that the opening end 51 of the cup-shaped member has a swell called an ear. Moreover, the round part of the opening 51 of such a cup-shaped member is unlikely to be good.

  Therefore, in the present embodiment, even a highly anisotropic material can be handled. That is, in this embodiment, the cup-shaped member is provided with means such as a hole for restraining the center position as described above. Thereby, the deformation in the radial direction is equalized during the deformation. As a result, the thickness variation in the circumferential direction of the molded product formed by compression is reduced.

  FIG. 4B shows a state 41-2 in which the cup-shaped member is compressed. This molding process is a preforming process, and is not a final molded product shape. The preform 41 has a low projection as shown in FIG. 4C, that is, a shallow groove between the projections. -2 only. When preforming in this way, when the final protrusion is formed, a side force is hardly generated in the thin portion, so that the possibility of breakage can be further reduced. This is similar to the case where a mortar-shaped dent is provided in a drilling position in advance when drilling with a drill, so that the tip position of the drill is fixed and the drill can be prevented from being bent and damaged. If a shallow groove is provided at a position where the groove is provided in advance, it becomes a guide and a final deep groove, that is, a high protrusion can be easily formed.

  Further, it is desirable that this preform is subjected to an intermediate heat treatment (annealing treatment) before the final protrusion is formed. This heat treatment softens the preform and increases the total elongation, thereby reducing the deformation resistance in the final process. As a result, the burden on the mold used in the final process and the risk of seizure can be reduced, and the possibility of occurrence of cracks in the molded product itself can be reduced. As the recrystallization progresses, there is an effect that the above-described adverse effects due to anisotropy are reduced.

  In addition, it is desirable to newly lubricate the preform 41-2 in which the volume of the protrusion is small (the groove between the protrusions is shallow). This is because the stress burden on the mold, particularly seizure at the thin wall portion, is reduced in the final molding process. As the lubricating treatment, for example, a lubricant mainly composed of molybdenum disulfide is applied.

  FIG. 5A shows a state where the preform is set in a mold for forming the preform into the shape of the final vibrator. At this time, it is preferable that the width in the circumferential direction of the groove between the projections of the preformed product is wider than the width in the circumferential direction at the distal end portion of the corresponding thin portion 44a. By forming the preform in this way, it becomes easy to align the groove between the protrusions of the preform 41-2 and the thin portion 44a of the die 44 in the circumferential direction. Furthermore, the thin-walled portion of the preforming mold can be thickened, and there is an effect that it is difficult to break.

  FIG. 5B shows a state in which the preform 41-2 is crushed to a final shaped product 41-3. At this time, the circular hole 41-2a in the center of the preformed product becomes the hole 41-3a of the final molded product shown in FIG. 5C, and the diameter is smaller than that of the circular hole 41-2a.

  As described above, in the present embodiment, the circular hole 41-2a is provided at the center of the bottom of the cup-shaped member, and the preforming step is provided before the step of forming the final protrusion. By providing the circular hole, the center position can be constrained and the variation in the width in the circumferential direction of the molded product can be reduced. In addition, even in the final molding step, the presence of this circular hole may cause excess metal to escape into the circular hole portion when a load having a component in the out-of-plane direction is applied, and an excessive stress is applied to the mold. Is prevented. In addition, by providing a preforming step, when the final protrusion is formed, a side force is hardly generated in the thin portion, so that the possibility of breakage can be further reduced.

  In each embodiment, although the example which forms the projection part for vibration expansion in a vibrator was explained, the present invention is not limited to this. That is, if the metal workpiece has a shape including a plurality of protrusions protruding in the same direction, the above-described forming method can be applied to a similarly shaped part such as a bevel gear or a hypoid gear.

11-1 Disc 11-2, 41-1 Cup-shaped member 11-3 Cup-shaped member in the middle of deformation 11-4 Final molded product 22, 32, 42, 122 Punch 23, 33, 43, 123 Die ring 24, 34 , 44, 124 Die 25, 35, 45, 125 Knockout 26 Positioning plate 34a, 44a, 124a Thin portion 41-1a, 41-2a, 41-3a Circular hole 41-2 Pre-formed product 41-3 Final formed product 111 Covered Workpiece (disc)
51 Open end 52 Bottom of cup-shaped member 53 Side surface 54 Bottom of vibrating body 55 Projection

Claims (9)

A method for producing a metal member having a plurality of protrusions,
Adding a load having a component in a direction perpendicular to the surface of the plate member to a metal plate member to produce a cup-shaped member;
Adding a load having a component in a direction perpendicular to the surface of the bottom of the cup-shaped member to the cup-shaped member, and forming the plurality of protrusions at the opening end of the cup-shaped member by a mold;
The manufacturing method of the metal member characterized by having.   2. The method for producing a metal member according to claim 1, wherein the cup-shaped member is manufactured such that an outer diameter of an opening end portion of the cup-shaped member is larger than an outer diameter of a bottom portion of the cup-shaped member. .   2. A step of preforming a groove shallower than a groove between the plurality of protrusions between the step of forming the cup-shaped member and the step of forming the plurality of protrusions. Or the manufacturing method of the metal member of 2.   The method of manufacturing a metal member according to claim 3, further comprising a step of performing a heat treatment between the step of preforming the groove and the step of forming the plurality of protrusions.   The method for manufacturing a metal member according to any one of claims 1 to 4, wherein a hole or a recess is provided in the center of the bottom of the cup-shaped member.   The method for manufacturing a metal member according to any one of claims 1 to 5, wherein a plate member having a thickness smaller than a radial width of the protrusion is used.   The metal member according to any one of claims 1 to 6, wherein a radial width of an opening end portion of the cup-shaped member is formed to be thinner than a radial width of the protruding portion. Manufacturing method.   The metal member according to any one of claims 1 to 7, wherein the step of producing the cup-shaped member is performed by any one of drawing, burring, stretch forming, and dish pressing. Manufacturing method.   The method for producing a metal member according to any one of claims 1 to 8, wherein the step of forming the protrusion is performed by forging or forging.

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