JP6612600B2 - Manufacturing method by cold forging of cylindrical metal fittings with polygonal flanges - Google Patents

Description

  The present invention provides a front and rear intermediate portion in the axial direction of the cylindrical portion, such as a metal shell that is a main component of a gas sensor that measures the oxygen concentration of exhaust gas or a metal shell that is a main component of a spark plug. It is a cylindrical metal fitting (part) with a polygonal flange that is provided with a polygonal flange projecting outward from the outer peripheral surface, and the material (finished product) before machining, that is, cutting as that part The present invention relates to a manufacturing method by cold forging of a cylindrical metal fitting with a polygonal flange, which is a raw material before being processed or screwed.

  FIG. 7 is a cross-sectional view for explaining a gas sensor (for example, an oxygen sensor; hereinafter simply referred to as a sensor) 1 used in an automobile or a motorcycle (two-wheeled automobile). The sensor 1 includes a cylindrical metal shell (metal body) 10 as a whole, a cylindrical sensor element 31 with a tip (lower end in the figure) closed inside, and the inside of the element 31 and in the sensor. These are composed of a protective cylinder 41 and the like which are covered to protect terminal fittings (not shown). A metal shell 10 which is a main component constituting the sensor 1 is provided with a screw 13 to be attached by screwing into a screw hole provided in an exhaust pipe of an automobile or the like, and a cylindrical tube (cylindrical) on the tip side. And a polygonal flange (for example, a hexagonal flange) 15 having a larger diameter than that of the screw 13 for screwing (for screwing), and the polygon A cylindrical structure including a cylindrical cylindrical portion (cylindrical portion) 17 having a smaller diameter is provided behind the flange 15. In the present application, when referring to the metal shell 10 and the cylindrical metal fitting with a polygonal flange constituting the material, the lower end in FIG. 7 is referred to, and the rear end is referred to as the opposite end. In the sensor (finished product) 10 shown in FIG. 7, a protector 51 is fitted on the small diameter portion 12 at the tip of the screw 13 of the cylindrical portion (cylindrical portion) 11 on the distal end side, and the rear cylindrical portion 17. The thin cylindrical portion 19 near the rear end is bent toward the center line and caulked forward to fix the element 31 and the like.

  FIG. 8 shows a case where the cylindrical metal fitting (material) 10 with a polygonal flange before being manufactured through machining such as cutting and screw machining as a main metal fitting (part finished product) constituting the sensor 1 is cold. It shows the shape and structure of the product formed and manufactured by forging. Hereinafter, the term “cylindrical metal fitting with a polygonal flange” (hereinafter also simply referred to as “cylindrical metal fitting”) refers to these materials before machining. The shape of this material is the same or similar to that of the metal shell (part finished product) shown in FIG. 7 except for a part thereof. . That is, the cylindrical metal fitting 10 follows the shape and structure of the main metal fitting (part finished product), and the outer diameters of the cylindrical parts 11 and 17 and the intermediate parts of both cylindrical parts are larger than those. A cylindrical body structure having a polygonal flange 15 is presented. In addition, in this cylindrical flanged cylindrical metal fitting 10, the cylindrical portion 11 on the distal end side forms a small-diameter portion 12 ahead of the portion to be threaded, and the hollow portion 27 extends rearward from the distal end. A circular hole with a large diameter is formed step by step. Conventionally, a cylindrical metal fitting made of such a material has been used in a plurality of times such as upsetting, drilling, extruding, punching, etc. from a cylindrical starting material (for example, SUS430) obtained by cutting a round bar short by cold forging. After the molding process, the deformation was gradually increased. However, it is not easy to efficiently form a cylindrical metal fitting with a polygonal flange having the above-described shape and structure by cold forging, in particular, the polygonal flange portion with a designed shape and dimensional accuracy. Various manufacturing methods have been proposed for solving such problems (Patent Documents 1 to 3).

  Patent Document 1 discloses an outline of the following manufacturing method. A cylindrical body that is a starting material (hereinafter also referred to as a blank including an intermediate molded body) is swallowed to obtain an intermediate molded body in which a concave portion is provided in the center of the rear end face or the concave portion is deepened. Then, in the next step, a cylindrical mold (outer punch, outer end, which is provided in the circular hole of the mold, the end face of the mold is opposed to the front-rear gap (flange thickness) for flange formation). Using a die (mold) having an outer counter), the outer peripheral surface of the blank except for the intermediate portion is restrained by the inner peripheral surface near the end surfaces of the two cylindrical molds. . Then, under that state, the preliminary hole forming punch is pushed into the recess at the center of the rear end surface to form the preliminary hole for forming the hollow portion, and the outer peripheral surface of the intermediate portion in the blank is swallowed. By filling the space between the end surfaces of the cylindrical molds inside the circular hole with a material, for example, as a circular flange having a larger outer diameter than the polygonal flange, the circular flange is stretched and formed. . After that, the preliminary hole (concave part) is processed into a deep hole, the cylindrical part is extruded on the tip side, and in the subsequent process, the bottom surface of the deep hole (hollow part) is punched and a flange having a hollow part that penetrates is provided. Use a cylindrical fitting. Then, separately, the circular flange is trimmed into a polygonal flange to obtain a polygonal flange having a desired shape and size. That is, in this manufacturing method, in the forming process by cold forging, although it is not a polygon, it is formed into a cylindrical metal fitting with a circular flange having a larger outer diameter, and thereafter, the periphery of the flange is separately provided. The outer peripheral shape is adjusted to a polygon by shearing (cutting) it into the polygon in the axial direction of the cylindrical fitting.

  Patent Document 2 discloses the following manufacturing method. An intermediate molded body (blank) that is formed by recessing an appropriate amount in the center of the rear end surface by swallowing the starting material (cylindrical body), etc., and a polygonal flange that has a relatively large diameter behind the circular hole. It loads in the metal mold | die which has the space formed in the internal peripheral surface (polygon internal peripheral surface). Then, a preliminary hole forming punch is pushed into the concave portion of the rear end surface of the blank to form a preliminary hole, and the rear end portion is expanded and pressed against the inner peripheral surface of the mold by the material component accompanying the drilling. In this way, the outer peripheral surface of the entire rear end portion is stretched into a polygon corresponding to the outer peripheral surface of the polygon flange. Then, in this molding, for the rear end portion of the polygonal portion that has been stretched and extruded by rearward extrusion, in the next step, a mold having a circular inner peripheral surface is externally fitted and extruded. Thus, the rear end portion is extended to a small-diameter cylindrical portion. In this way, the polygonal portion is relatively shortened and formed into a polygonal flange having a predetermined front and rear length (thickness) dimension. After that, in the same way as described above, the hollow part is formed by deep drilling the preliminary hole, and finally, the bottom part of the deep hole is punched, and the cylindrical metal fitting with a polygonal flange having the hollow part penetrating is formed. Is to get. That is, in this manufacturing method, at the preliminary hole forming stage of the intermediate forming step, the entire rear end portion is made into a polygon, and then the rear end portion is narrowed down into a circle to form a polygonal flange. In addition, the manufacturing method described in Patent Document 3 is substantially the same with respect to the formation of the polygonal flange.

  As is well known, a spark plug used for ignition of an automobile engine has a cylindrical metal shell (metal fitting body) having a different diameter and a screw for mounting (screwing) to the engine on its outer peripheral surface. A cylindrical insulator that is held inside the metal fitting and protrudes at the tip and includes a center electrode inside, and a ground that is welded to the tip of the metal fitting to form a spark gap with the tip of the center electrode It consists of electrodes and the like. And, this metal shell also has a polygonal flange for screwing in. The shape and structure of the material before it is manufactured as a finished product through cutting and screwing are basically the same as that of the sensor It goes through the same cold forging process and is finally manufactured as a cylindrical metal fitting with a polygonal flange.

JP 2003-31367 A JP 04-371336 A JP 2014-198346 A

  In the manufacturing method of Patent Document 1 described above, a polygonal flange is not directly formed by cold forging, but is stretched and formed as a circular flange larger than its diagonal dimension (outer diameter). It is sheared with a trimming punch (shearing blade) so as to form a polygonal flange. For this reason, in such a manufacturing method, not only a trimming process is required, but also cutting waste generated due to the trimming is inevitably generated, and not only is there a problem in processing a large amount of waste, but also the material yield is poor. There was a problem. Moreover, such trimming requires a polygonal trimming punch (movable blade for shearing) and a fixed blade (die) as a counterpart, which are high because they are polygonal blades. In addition, there is a problem that the cost is high and the life (the duration of sharpness) is relatively short (the frequency of mold change is high). As a result, there existed a subject that cost reduction of the cylindrical metal fitting with a polygonal flange was difficult.

  However, as an alternative, Patent Document 1 discloses that the flange is formed as a polygonal flange instead of a circle, but the shape and dimensions of the polygonal flange can be increased by swaging once. It is difficult to mold while maintaining accuracy. In fact, sufficient material flow cannot be ensured depending on the shape and structure of the polygonal flange, the amount of protrusion and the thickness ratio. In addition, when the polygonal flange is projected by one up, the end surface on the space side and the outer peripheral surface of the cylindrical wall of the cylindrical mold (die) are also polygonal. The polygon must correspond to the outer peripheral surface of the flange. On the other hand, the inner peripheral surface is circular because it is necessary to match the cylindrical portion. For this reason, the wall thickness (wall thickness) in the cylindrical mold is small in the opposite direction of the polygon. In addition, when such a polygonal flange is stretched and formed by one upsetting, an extremely large pressing force is required, and thus an extremely large force acts in the thickness direction of the cylindrical wall. Thereby, a cylindrical metal mold | die is easy to be damaged in the thin part (opposite side part) of the wall, and there exists a serious subject that a lifetime is short. Moreover, due to the demand for compact products (small size and small diameter), depending on the type, the opposite side dimension of the polygonal part is only slightly larger than the outer diameter of the cylindrical part that forms the base part. For these reasons, in the manufacturing method described above, it is the actual situation that the polygonal flange is not directly stretched and formed by one upsetting.

  In the manufacturing method of Patent Document 2, there is no such problem, but by forming a preliminary hole by pushing a preliminary hole forming punch, the rear end portion is expanded and its outer peripheral surface is formed into a polygon. Therefore, if the inner diameter of the spare hole is smaller than the outer diameter of the polygon, the flow of the metal material to the outside of the radius becomes insufficient, so the outer peripheral surface near the rear end is desired. It is not possible to sufficiently overhang the polygon of shape and size. That is, in the case of forming a preliminary hole by pushing a thin punch, the metal material is sufficiently pressed without any gap on the entire inner peripheral surface (polygonal surface) of the mold and cannot be filled. As a result, there has been a problem that the shape of the polygonal flange is poor due to insufficient overhang or occurrence of shrinkage. Thus, in the manufacturing method according to Patent Documents 2 and 3, when the inner diameter of the hollow portion of the cylindrical portion is small with respect to the outer diameter of the polygonal flange, a sufficient overhang cannot be obtained, and a desired shape, There has been a problem that a polygonal flange with dimensional accuracy may not be obtained.

  In view of the above-described problems in the prior art, the present invention provides a metal mold or the like for manufacturing a cylindrical metal fitting with a polygonal flange that is a material before machining of the metal shell (finished product) by cold forging. Even if the cylindrical metal fitting with a polygonal flange has a small inner diameter of the hollow portion with respect to the outer diameter of the polygonal flange without incurring an increase in cost due to high costs, etc. It is an object of the present invention to provide a production method capable of efficiently obtaining a polygonal flange.

The present invention according to claim 1 includes a cylindrical portion having a hollow portion that penetrates, and a polygonal flange that projects outwardly on an outer peripheral surface of a front-rear intermediate portion in the axial direction of the cylindrical portion. It is a manufacturing method by cold forging of a cylindrical metal fitting with a square flange,
In the intermediate molding step in the manufacturing process of the cylindrical flanged tubular metal fitting, the polygonal flanged cylindrical metal fitting is characterized by including at least the following steps for forming the polygonal flange: It is a manufacturing method by cold forging.
(1) By forming a recess by pressing a pre-hole forming punch into the center of one end face of a cylindrical blank, or by forming a pre-hole forming punch into the recess in a blank formed by forming the recess. When forming the preliminary hole to form the hollow portion by deepening the concave portion by pushing, the blank is used for forming the preliminary hole under a state in which the outer peripheral surface except the intermediate portion is restrained. The preliminary hole is formed by pushing a punch, and an overhanging portion for a polygon flange having a leading and trailing dimension larger than the leading and trailing dimensions of the polygon flange by swaging is preliminarily formed on the outer peripheral surface of the intermediate portion of the blank. preliminary formed inside the polygon regulatory inner peripheral surface that does not exceed the outer peripheral surface and the range should be of polygonal flange in the forming die body Preforming step of.
(2) The preliminary hole in the blank after the preliminary molding using the main body of the molding die having a polygonal inner peripheral surface for molding the outer peripheral surface of the polygonal flange after the preliminary molding step. With the shape retaining punch loaded in the blank, the blank is disposed in the main mold body so that the overhanging portion for the polygon flange is surrounded by the inner peripheral surface of the polygon. A main forming step of compressing the polygon flange to a predetermined front and rear length by pressurizing the overhanging portion for the polygon flange in the front and rear direction under the arrangement state.

According to a second aspect of the present invention, in the pre-forming step, the pre-molding die main body and a separate die are used to constrain the outer peripheral surface excluding the front and rear intermediate portions of the blank. The separate die is formed in a cylindrical shape, and is arranged on the preliminary hole forming punch in an outer fitting shape through an annular gap. It is a manufacturing method by cold forging of the cylindrical metal fitting with a polygonal flange.
According to a third aspect of the present invention, in the preforming step, the regulation inner peripheral surface not exceeding the range to be the outer peripheral surface of the polygonal flange is the outer periphery of the polygonal flange in the preforming mold body. 3. The preliminarily shaped polygonal inner peripheral surface having the same dimension or less as the surface is formed between the front and rear of the inner peripheral surfaces that restrain the front and rear across the intermediate portion of the blank. It is a manufacturing method by cold forging of the cylindrical metal fitting with a polygonal flange as described in 1 above.

According to a fourth aspect of the present invention, the pressure in the front-rear direction of the overhanging portion for the polygon flange in the main molding step is performed by using separate dies having annular surfaces for molding each end surface of the polygon flange. The cylindrical flanged polygonal shape according to any one of claims 1 to 3, wherein the cylindrical surface is provided with a separate die and the annular surface provided on the main body of the main molding die. It is a manufacturing method by cold forging of a metal fitting.
In the present invention according to claim 5, the pressure in the front-rear direction of the overhanging portion for the polygon flange in the main molding step is performed by the annular surface provided on the separate mold and the main body for molding. When performing, this separate metal mold shall form a cylinder shape, and it is arranged in the shape of an external fitting to the shape-retaining punch through an annular gap. It is a manufacturing method by cold forging of the cylindrical metal fitting with a polygonal flange described in 1.

  In the present invention, the polygonal flange is not formed by a single cold forging process (pressing process), but at least by a preliminary forming process by one upsetting, the front and rear length is larger than the original polygonal flange. The overhanging part for the polygon flange is formed by overhanging, and the original polygonal flange is formed by pressurizing the overhanging part for the polygon flange in the front-rear direction in the subsequent main forming step. That is, since the polygonal flange is formed by the cold forging process (deformation process) at least twice instead of once (once) as in the past, it is possible to prevent excessive force from being applied to the mold. Therefore, damage to the mold can be reduced, high accuracy without trimming, and even if the diameter of the spare hole is small, it is finally possible to obtain a polygon flange with high dimensional accuracy without insufficient overhang. it can. As a result, a cylindrical fitting with a polygonal flange with high dimensional accuracy can be obtained efficiently and at low cost.

  The mold used for the pre-molding process can be formed by combining a plurality of molds including dies, punches, knock pins, etc. so that the space for the overhanging portion for the polygon flange can be formed and taken out after molding. What is necessary is just to comprise. In the preforming step, as described in claim 2, a preforming mold main body and a separate mold are required, and the separate mold has a cylindrical shape. It is preferable to use a thing (cylindrical mold), and to be arranged on the preliminary hole forming punch in an outer fitting shape through an annular gap. With this arrangement, this separate mold is attached to the movable plate in a suspended manner so as to move up and down simultaneously with the preliminary hole forming punch through an appropriate spring, and in the free state of the spring. The control of the blank restraint or the like is simplified by allowing the tip of the separate mold to protrude from the tip of the preliminary hole forming punch by an appropriate amount.

  The regulation inner peripheral surface that does not exceed the range to be the outer peripheral surface of the polygonal flange in the preforming step is the outer periphery of the polygonal flange in the preforming mold body as described in claim 3. A preformed polygonal inner peripheral surface having the same dimension or less as the surface is preferable because the mold structure can be simplified. In addition, the polygon flange in this invention or a polygon is a thing of the precision comparable as outer peripheral surface shapes, such as the head of a hexagon bolt, and a nut.

  In the main forming step, the pressure in the front-rear direction of the overhanging portion for the polygon flange may be performed by an appropriate combination of molds. It is a mold that has an annular surface that molds each end surface, or is performed between separate molds, or on the annular surface that is provided on the separate mold and the main body for molding. This is preferable because the structure can be simplified. In this case, as described in claim 5, the pressure applied in the front-rear direction of the overhanging portion for the polygon flange in the main molding step is provided in a separate mold and the main body for molding. In the case of carrying out on an annular surface, it is preferable that this separate mold is formed in a cylindrical shape and arranged in an external fitting shape on the shape-retaining punch through an annular gap. With this arrangement, the shape-retaining punch is attached to the movable plate so as to move up and down simultaneously with the separate cylindrical mold via an appropriate spring, and retained in the spare hole. After the loading of the punch for forming is completed, pressurization is started on the cylindrical surface provided separately and the annular surface provided on the main body for molding. The control for loading the shape retaining punch into the spare hole becomes easy.

Polygon flanged tubular product manufactured through the final forming process (blank) in each forming process step (each cold forging process) of the cylindrical flanged tubular metal fitting manufactured by the manufacturing method of the present invention The half sectional view explaining a metal fitting. It is a figure explaining the embodiment which materialized the manufacturing method of this invention, Comprising: From the 1st process molded object (A) of FIG. 1-A which carried out the end surface shaping | molding of the starting material, the 2nd process molded object of FIG. Sectional drawing for process description containing the metal mold | die of the 2nd process which shape | molds (B). Preliminary forming step (third step) for forming the third step formed body (C) of FIG. 1-C by preforming the overhanging portion for the polygon flange from the second step formed body (B) of FIG. 1-B. Sectional drawing for process description including the metal mold | die etc. of FIG. Mold of the main molding step (fourth step) in which a polygonal flange is finally molded from the third step molded body (C) of FIG. 1-C to form the fourth step molded body (D) of FIG. 1-D. Sectional drawing for process description containing these. Mold of the step (fifth step) for forming the fifth step molded body (E) in FIG. 1-E by deep drilling a preliminary hole from the fourth step molded body (D) in FIG. Sectional drawing for process description containing these. Sectional drawing for process description including the metal mold | die etc. of the process (6th process) which punches out the bottom part of the hollow part of the 5th process molded object (E) of FIG. 1-E. The schematic structure sectional view explaining an example of the conventional gas sensor. 7 is a material (raw material) before machining of the metal shell (part finished product) used in the gas sensor of FIG. 7, wherein A is a cross-sectional view of a cylindrical metal fitting with a polygonal flange formed by cold forging, B is a view of A from above, and C is a view of A from below.

  Hereinafter, the embodiment of the manufacturing method by the cold forging of the cylindrical metal fitting with a polygon flange by this invention is described in detail, referring FIGS. However, in this example, as shown in the order of A to F in FIG. 1, the end surface is adjusted from a columnar starting material (not shown) to form the first process molded body 10 a, and then this is swallowed. Then, the second process molded body 10b is formed, and then the polygon flange overhanging portion 15c is preformed to form the third process molded body 10c. As a fourth process molded body 10d, a preliminary hole of the fourth process molded body 10d is then made into a fifth process molded body 10e having a hollow portion 27 by deep drilling, and finally, the bottom surface of the hollow portion 27 is punched out. The case will be described in the case of molding and manufacturing in a six-stage molding process for obtaining a polygonal flanged tubular metal fitting (sixth process molded body) 10 that is a finished material. In addition, the code | symbol of each site | part in the molded object (10b-10e) in each process is a site | part which is substantially the same as that on the basis of this 6th process molded object 10, or does not need to be distinguished in principle. In addition to the code (number) of each part, the corresponding part, although not the same, is added with the letter (number) attached to the molded body in addition to the code (number) of each part. Hereinafter, the term “cylindrical metal fitting” refers to the material (sixth process molded body 10) immediately before being machined, and the term “metal fitting” refers to the part after the processing.

  FIG. 2 shows the molding process (second process) of the second process molded body 10b sent to the preforming process (third process) of the present invention. First, the shape and structure of the second process molded body 10b will be described. (See FIG. 1-B). The molded body (blank) 10b has a small-diameter portion 11b on the front end side (the lower end side in the figure) and is enlarged in diameter via a taper 20 toward the rear, and the rear portion has a relatively large-diameter large-diameter portion. It has a cylindrical shape with a different diameter consisting of 17b. In this blank 10b, the first process molded body 10a (see FIG. 1-A) obtained by molding and adjusting the end surface of the starting material (cylindrical body) is loaded into the mold 200 shown in FIG. It is formed by pushing the end face 22 and swallowing the portion near the rear end. In addition, the outer diameter of the small diameter part 11b respond | corresponds to the outer diameter in which a screw | thread can be formed in the front end side in a metal shell. Further, the outer diameter of the large-diameter portion 17 b corresponds to the outer diameter of the rear cylindrical portion 17 in the cylindrical metal fitting 10. Each end face is formed with a tapered tapered recess 23. The molding surface (inner peripheral surface) of the mold 200 is an inner peripheral surface made of a circular hole with a different diameter corresponding to the outer peripheral surface of the different diameter cylindrical body, and a knockout pin 240 is disposed below the inner peripheral surface. Has been.

  The above-described second process molded body 10b (see FIG. 1-B) is sent to the preforming process (third process) of the present invention shown in FIG. 3, and the third process molded body (see FIG. 1-C). First, the shape and structure of the third process molded body will be described (see FIG. 3). The formed body 10c forms a preliminary hole 25 to be the hollow portion 27 of the cylindrical metal fitting 10 by pushing the preliminary hole forming punch 330 into the concave portion 23 at the center of the rear end face 22b in the second process molded body 10b. It will be. Then, by forming the preliminary hole 25, a polygonal flange overhanging part by swaging on the outer peripheral surface of the intermediate part in the blank (near the taper 20 of the second process molded body 10b and the tip part of the large diameter portion 17b). 15c is formed. The protruding portion 15c has a front and rear length L1 larger than the front and rear dimension L2 of the polygonal flange (in this example, regular hexagon) 15 as a finished product, but the outer diameter is the outer peripheral surface of the polygonal flange 15. The size is set so as not to exceed the power range, and the overhanging volume is set so that a regular polygon can be formed. In addition, the above-described preliminary hole 25 presents a different diameter hole whose rear end side has a slightly larger diameter with respect to the front end side, and the portion of the hole 25 corresponding to the front end side (polygonal portion) The inner diameter of the hollow portion 27 formed by deep drilling is substantially the same. On the other hand, the inner diameter of the rear large-diameter portion 17b in the preliminary hole 25 is set to be substantially the same as the inner diameter of the cylindrical portion 17 on the rear end side. In this example, the bottom surface of the preliminary hole 25 is positioned in the middle of the front and back of the overhanging portion 15c, and the bottom surface has a small amount of taper with a tapered shape where the center (center) is low. Yes. And the tip part 11c of the protruding part 15c for the polygon flange, which is the tip of the bottom surface, remains substantially the same shape as the small diameter part (cylindrical part) 11b on the tip side in the second process molded body 10b.

  On the other hand, the mold used in this preforming step (third step) is composed of a preforming mold main body 300 and the like as follows. As shown in FIG. 3, the preforming mold main body 300 includes a circular hole 303 that receives the small-diameter portion 11 b on the distal end side of the second process molded body 10 b with a gap, and constrains the outer peripheral surface thereof, and the circular hole At the rear end (upper end in the figure) of 303, the diameter is increased in a polygonal shape coaxially with the circular hole 303 via a rearwardly facing annular surface 305 having a slightly tapered taper, and the polygonal shape extends rearward. A square hole 307 is provided. The inner peripheral surface of the polygonal hole 307 is the same as the outer peripheral surface of the polygonal flange 15 or is made slightly smaller in cross section than that. That is, the inner peripheral surface of the polygonal hole 307 is a regulated inner peripheral surface 309 that does not exceed the range to be the outer peripheral surface of the polygonal flange 15, and in this example, forms a polygonal inner peripheral surface for preforming. Yes. A knockout pin 340 that supports the tip surface of the third process molded body 10c is disposed in the circular hole 303 in the mold.

  On the other hand, the preliminary hole 25 of the hollow portion 27 in the cylindrical metal fitting 10 is formed in the center of the rear end surface of the blank 10b above the mold (preliminary mold body) 300 coaxially with the circular hole 303. For this purpose, a preliminary hole forming punch 330 is arranged concentrically with the circular hole 303 in a hanging shape. The front end portion of the preliminary hole forming punch 330 is relatively thin, and the rear end portion (upper end portion) is fixed to a movable plate provided to move up and down in a press device (not shown). ing. In this example, a cylindrical mold (separate mold) 350 is concentrically arranged in an outer fitting manner with respect to the preliminary hole forming punch 330 through an annular gap. The cylindrical mold 350 is formed such that the inner peripheral surface near the tip thereof can restrain the outer peripheral surface of the rear end portion (large diameter portion 17b) in the second process molded body 10b. And when the preliminary hole forming punch 330 is pushed into the center of the rear end surface 22b of the blank 10b and the preliminary hole 25 is formed, the annular gap is relatively formed in the rear cylindrical portion (cylindrical portion) 17. It is a space to be pushed out and is open toward the rear.

  Further, in the preforming process, the outer peripheral surface near the tip of the cylindrical mold 350 may be circular, but in this example, the outer periphery is fitted into the polygonal hole 307 in the preforming mold main body 300 with a clearance fit. It has a rectangular shape and is guided by guide means (not shown) so as to be inserted and fitted into the polygonal hole 307 by being moved downward. The cylindrical mold 350 is attached to the movable plate at the rear end (upper end in the drawing) via an appropriate spring 360 so as to move up and down simultaneously with the preliminary hole forming punch 330. However, in the free state of the spring 360, the cylindrical mold 350 is set so that the tip (lower end in the drawing) 353 protrudes from the tip 335 of the preliminary hole forming punch 330 by an appropriate amount. More specifically, before the front end 335 of the preliminary hole forming punch 330 presses the rear end surface 22b of the blank 10b, a cylindrical mold 350 is formed between the outer peripheral surface and the inner peripheral surface of the polygonal hole 307. The front end 353 of the cylindrical mold 350 enters a predetermined amount toward the front, and the pressing of the rear end surface 22b of the blank 10b is started, and at the same time as the upsetting of the material is started, a portion closer to the front end of the cylindrical mold 350 Due to the deformation of the material on the inner peripheral surface of the material, the outward radial pressurization occurs, the further intrusion is stopped, and the spring 360 is compressed. It is set to be performed.

  Therefore, in this example, in the drive control of the preliminary hole forming punch 330, the outer peripheral surface of the portion near the rear end of the large diameter portion 17b of the blank 10b can be constrained. It should be noted that when the entry of the portion closer to the tip of the cylindrical mold 350 is stopped, the tip 353 and the rearward-facing annular surface (annular bottom surface of the polygonal hole 307) 305 at the rear end of the circular hole 303 The interval (dimension) between them is set to be larger than the front and rear dimension L2 of the polygonal flange 15. That is, the interval (dimension) between them is set to an appropriate front and rear length L1 in relation to the inner diameter dimension of the polygonal hole 307 so as to obtain the amount of material necessary for overhanging the polygonal flange 15 in the main molding. Is set.

  Now, in the preforming process (third process) using such a mold, the second process molded body (blank) 10b is loaded into the circular hole 303 of the mold at the small diameter portion 11b (left in FIG. 3). (A). Thereby, the outer peripheral surface of the small diameter portion 11 b of the blank 10 b is restrained by the inner peripheral surface of the circular hole 303. Next, as shown in the right diagram (B) of FIG. 3, an appropriate amount of a movable platen not shown is lowered. Thereby, the front-end | tip part of the cylindrical metal mold | die 350 is between the outer peripheral surface of the rear end part part of the large diameter part 17b of the blank 10b, and the internal peripheral surface (regulation internal peripheral surface) of the polygonal hole 307. A predetermined amount enters the annular space. Further, by lowering the movable platen, the front end 335 of the preliminary hole forming punch 330 starts to be pushed into the center of the rear end surface of the blank 10b, and the material upsetting is started. At substantially the same time as this start, since the material is deformed to the inner peripheral surface near the front end of the cylindrical mold 350, the outward radial pressurization occurs, so that the further intrusion is stopped and the rear end of the blank 10b. The outer peripheral surface of the side portion is restrained. As a result, the blank 10b is constrained on the outer peripheral surface except for the intermediate portion before and after the blank 10b, and under this state, the preliminary hole forming punch 330 is pushed in, and the preliminary end portion that deepens the concave portion 23 on the rear end surface. The hole 25 is formed (drilled). At the same time, in the space between the outer peripheral surface of the intermediate portion of the blank 10b and the inner peripheral surface of the polygonal hole 307, the front and rear dimension L2 of the polygonal flange 15 is increased due to the upsetting associated with the formation of the preliminary hole 25. Although the front and rear dimensions are large, a polygon flange overhanging portion 15c is preliminarily formed so as not to exceed the range that should be the outer peripheral surface of the polygon flange 15 (see the right figure (B) in FIG. 3).

  Thus, after the preforming, the movable platen is raised, the preforming hole forming punch 330 and the cylindrical mold 350 are pulled up, and the knock pin 340 is pushed up, whereby the third process molded body 10c (FIG. 1-C). Reference) is obtained. That is, the preliminary hole 25 is formed in the blank 10b, and the outer peripheral surface of the intermediate flange portion is not swept over the outer peripheral surface of the polygonal flange 15, but the front-rear dimension is larger than the front-rear dimension L2. A protruding portion 15c for a square flange is formed. In this preliminary molding step, a concave portion is formed by pressing the pre-hole forming punch 330 into the center of one end face of a columnar (different-diameter columnar) blank 10b that is a second step molded product. As described in the case of forming the preliminary hole 25 to form the hollow portion 27, this columnar blank 10b is formed by forming a concave portion having an appropriate depth on the rear end surface, and the preliminary hole to the concave portion is formed. The preliminary hole 25 that should form the hollow portion 27 may be formed by deepening the recessed portion by pushing the forming punch 330. Further, the cylindrical blank 10b may have a cylindrical shape with the same diameter instead of a different diameter cylindrical shape depending on the cylindrical metal fitting 10.

  The third process molded body 10c preformed as described above is sent to the main molding process (fourth process) of the present invention shown in FIG. 4 and molded into the fourth process molded body 10d. In addition, this 4th process molded object 10d (refer FIG. 1-D) has the overhang | projection part 15c for polygon flanges shape | molded in the 3rd process molded object 10c in many places in the cylindrical metal fitting 10 with a polygon flange. The only difference is that the shape and dimensions of the square flange (regular hexagonal flange) 15 are adjusted and molded, and there is essentially no difference.

  That is, in the main molding step (fourth step), the polygon flange overhanging portion 15c in the third step molded body 10c described above is changed to a regular polygon flange (regular hexagon flange) 15 and the shape and dimensions thereof are adjusted. Since this is a step of forming the fourth step molded body 10d by molding, in this example, the mold used in the fourth step is configured as follows from the main body 400 for molding and the like. That is, the main body 400 for molding is provided with a circular hole 403 that can receive the tip portion 11c formed of a cylindrical portion on the tip side in the third process molded body 10c, and a polygon flange 15 at the rear end of the circular hole 403. Through the annular surface 405 facing rearward for forming the tip-facing surface, the diameter of the polygonal flange 15 is increased in diameter to form the outer peripheral surface of the polygonal flange 15 coaxially with the circular hole 403, and the polygon extends rearward. A square hole 407 is provided. The rear-facing annular surface 405 is slightly tapered and is the same as the tip-facing end surface (annular surface) 15 s of the polygonal flange 15, and the inner peripheral surface 409 of the polygonal hole (hexagonal hole) 407 is many. It is formed the same as the outer peripheral surface of the square flange 15. Thereby, the inner peripheral surface 409 of the polygonal hole (hexagonal hole) 407 forms a polygonal inner peripheral surface for molding the outer peripheral surface of the polygonal flange 15. In the circular hole 403 in the mold 400, a knockout pin 440 that supports the distal end surface of the small diameter portion (cylindrical portion) 11d on the distal end side of the fourth step molded body 10d to be molded is disposed. As described above, the molding surface of the main mold body 400 used in the fourth step is substantially the same as the molding surface of the preform main body 300 used in the third step.

  On the other hand, a shape-retaining punch (cylindrical body) 430 that is coaxial with the circular hole 403 and has a front end portion loaded in a preliminary hole 25 provided in the center of the rear end surface above the main body 400 for molding. Are arranged in a drooping manner. The front end portion of the shape-retaining punch 430 is formed so as to be loaded in the preliminary hole 25 without a substantial gap. The shape-retaining punch 430 is attached to a movable plate that moves up and down at the upper end portion of the shape-retaining punch 430 via a suitable spring 460 in this example. In this example, a cylindrical mold (separate mold) 450 is arranged concentrically in an outer fitting manner via an annular gap with respect to the shape-retaining punch 430. Portion close to the front end of the metal mold 450 is fitted between the outer peripheral surface of the rear end portion (cylindrical portion 17) of the third process molded body 10c and the inner peripheral surface of the polygonal hole 407, respectively. It is formed so that it can be externally fitted.

  That is, the outer peripheral surface near the tip of the cylindrical mold 450 is a polygon that forms a minute gap fit with the inner peripheral surface of the polygonal hole 407, and the inner peripheral surface is the third process molded body. 10c has a circular shape with a small gap fit on the outer peripheral surface of the rear end portion (cylindrical portion 17), and a guide (not shown) so as to be fitted inside the polygonal hole 407 by being moved downward. Guided by means. The cylindrical mold 450 is fixed to a movable plate to which the rear end of the shape retaining punch 430 is attached at the rear end (or rearward), and moves up and down simultaneously with the shape retaining punch 430. It is set to be. However, due to the downward movement of the movable platen, the tip 435 of the shape-retaining punch 430 is pushed into the preliminary hole 25, and the tip (lower end in the figure) of the third process molded body 10c loaded in the mold is the knockout pin 440. The tip 453 of the cylindrical mold 450 is set to start pressurization of the annular surface facing the rear end of the polygon flange overhanging portion 15c. Thus, when the tip 453 of the cylindrical mold 450 presses the annular surface facing the rear end of the overhanging portion 15c for the polygon flange, the shape retaining punch 430 presses the bottom surface of the preliminary hole 25. The spring 460 depending on it is compressed. Therefore, in this example, the drive control of the shape-retaining punch 430 can be performed in the drive control of the cylindrical mold 450 for main forming.

  The front end (surface) 453 of the cylindrical mold 450 forms an annular surface that forms the rear end-facing end surface 15k of the regular polygonal flange 15. Then, the pressing stroke of the cylindrical mold 450 is such that the flange bulge extends between the tip 453 and the rear-facing annular surface (annular bottom surface of the polygonal hole 407) 405 in the main body 400 for molding. The region 15c is set so that the polygon flange 15 having a normal front and rear dimension can be obtained by pressurizing the portion 15c. In this example, the rear-facing annular surface 405 for forming the front end face (annular surface) 15s of the polygonal flange 15 is formed integrally with the main body 400 for molding. However, as shown by the two-dot chain line in the figure, this part also incorporates a mold 480 similar to the cylindrical mold 450 (separate mold) 450 as described above, You may form. If it does in this way, the overhang | projection site | part 15c for polygon flanges will be pressurized previously between the end surfaces of two cylindrical metal mold | dies. In other words, the mold used in the main forming step can also be configured by an appropriate combination of dies (dies). The same applies to the mold used in the preforming step.

  Accordingly, in the fourth step, which is the main forming step, the polygon of the third flanged portion 10c of the third step formed body 10c coincides with the polygonal hole 407 in the main die 400 for forming. While doing so, the small-diameter portion 11c on the tip side is inserted into the circular hole 403 of the mold body (see the left figure (A) in FIG. 4). As a result, the outer peripheral surface of the portion closer to the tip (the small diameter portion 11 c on the tip side) is constrained by the inner peripheral surface of the circular hole 403, and the overhanging portion 15 c for the polygonal flange is the inner periphery of the polygonal hole 407. Surrounded by a surface (polygon inner peripheral surface). And under this arrangement state, as shown in the right figure (B) of Drawing 4, a movable board is moved down a predetermined stroke. As a result, the tip 435 of the shape retaining punch 430 is pushed into the preliminary hole 25, and the tip of the third process molded body 10 c loaded in the mold is supported by the tip of the knockout pin 440. Next, when the cylindrical mold 450 is lowered, the polygonal flange overhanging portion 15 c is pressed between the tip 453 and the annular surface 405 facing rearward in the main body 400 for molding. . Then, by lowering the cylindrical mold 450 by a predetermined stroke, the polygonal flange 15 compressed to a predetermined front and rear dimension L2 is obtained.

  Thus, after the main molding, the movable platen is raised, the cylindrical mold 450 and the shape-retaining punch 430 are pulled up, and the knock pin 440 is pushed up, whereby the polygonal flange 15 is finally molded. A four-step molded body (see FIG. 1-D) 10d is obtained. Then, as shown in FIG. 5, in the fifth step, the deep hole punch 530 is pushed into the preliminary hole 25 in the fourth step molded body 10d, and the small diameter portion 11d on the tip side is pushed out. The hollow cylindrical portion 17 is formed by extruding the rear cylindrical portion 17 backward. Thereby, the 5th process molded object 10e is obtained (refer FIG. 1-E). Then, as shown in FIG. 6, in the sixth step, the bottom surface (bottom portion) 29 of the hollow portion 27 in the molded body 10e is punched with a punching punch 630, so that the desired cylindrical flanged metal fitting ( 10) is obtained.

  Thus, the cylindrical metal fitting 10 with a polygonal flange obtained in this example is a preliminary as described above for forming the part of the polygonal flange 15 in the intermediate forming process in the manufacturing process by cold forging. Since the two steps of the forming step and the main forming step are included, the following effects can be obtained. That is, the polygonal flange 15 is not formed by a single cold forging process as in the prior art, but is formed by a pre-forming process by the first upsetting, so that the polygonal flange having a larger front and rear length than the polygonal flange 15 is used. The overhanging portion 15c is formed in advance, and then the polygonal flange 15 is formed by pressing the overhanging portion 15c for the polygon flange in the front-rear direction in the subsequent main forming step. It is said. For this reason, the press force given to a blank can be made small compared with the case where a polygon flange is fabricated by a single cold forging process. Thereby, since it is possible to prevent an excessive force from being applied to the molds including the cylindrical molds 350 and 450 as described above, damage to the molds can be reduced. Moreover, since the molding is performed through two steps, a highly accurate polygonal flange can be obtained without trimming. Further, since the two-step process is performed, even if the diameter of the preliminary hole 25 is small, the polygon flange 15 with high dimensional accuracy can be obtained without finally being insufficiently projected. Thus, according to this example manufacturing method, as a result, the cylindrical metal fitting with a polygon flange with high dimensional accuracy can be obtained efficiently and at low cost.

  In addition, the 5th process molded object 10e formed from the 4th process molded object 10d is a molded object just before becoming the cylindrical metal fitting 10 with a polygon flange punched in the 6th process, and a 6th process molded object There is no difference from the (tubular metal fitting finished product) 10 except that the bottom 29 remains. Then, in the fifth process molded body 10e, the fourth process molded body 10d is used by using the die 500 and the deep hole punch 530 as shown in FIG. It is formed by drilling (forming the hollow part). That is, in the fifth step, as shown in the left figure (A) of FIG. 5, the fourth step molded body 10d can receive the front part including the polygonal flange 15, and the fifth step molded body can be received. The mold 500 having a cavity formed corresponding to the shape of the front part 10e is loaded from the tip side, and the deep hole punch 530 is pushed in as shown in FIG. The hollow part (bottomed hole) 27 is obtained by performing deep hole drilling and is molded by extruding with a knock pin 540. Then, in the subsequent punching step (sixth step), as shown in FIG. 6, a mold 600 having the same cavity as that in the fifth step is used, and the fifth step molded body 10e is loaded therein. After that, the bottom surface 29 of the hollow portion (deep hole) 27 is punched with a punching punch 630 and extruded with a knock pin (cylinder type) 640.

  In the above-described embodiment, the third step is a pre-forming step in the case where a cylindrical metal fitting with a polygonal flange is formed by going through the six steps from the starting material and the polygonal flange is formed. However, in the present invention, the number of steps until the completion of the cylindrical fitting (cold forged product) and the order of the preforming steps are limited to this. Not. Further, the preforming step may be performed a plurality of times. That is, the pre-forming step is a plurality of appropriate steps depending on the forming difficulty based on the small inner diameter of the hollow portion, the shape of the polygonal flange (projection amount, front and rear dimensions), the deformability of the metal material, and the like. Also good. Moreover, the metal mold | die used in cold forging can use the thing of appropriate combinations including the metal mold | die body for preforming, the metal mold | die body for main molding, and another metal mold | die. Then, the driving means for moving the mold including the punch, etc., may be appropriate. In addition, the polygonal flange in the cylindrical metal fitting may be other than hexagon, and the shape and structure of the cylindrical metal fitting (material) with the polygonal flange are not limited to those in the above example, and the subsequent cutting work Depending on the location, machining allowance, etc., the different diameter state or the like may be embodied as an appropriately modified shape or structure. And such a cylindrical metal fitting with a flange can be widely applied as a material before machining of a cylindrical metal fitting for a sensor or a spark plug.

DESCRIPTION OF SYMBOLS 10 Cylindrical metal fitting 10b with a polygon flange Cylindrical blank 11, 17 Cylindrical part 15 Polygon flange 15c Polygon flange overhang | projection site | parts 15s, 15k End surface (annular surface) of a polygon flange
22b One end face 23 of the cylindrical blank 23 Recess 25 in one end face of the cylindrical blank Preliminary hole 27 Hollow part L1 Front and rear dimension L2 of the polygon flange overhanging part 300 Front and rear dimension 300 of the polygon flange 309 Restricted inner peripheral surface that does not exceed the range to be the outer peripheral surface of the polygon flange (polygonal inner peripheral surface for preforming in the preform main body)
330 Pre-hole forming punch 350 Separate mold used for pre-forming process (tubular mold)
400 Main mold body 405 Annular surface provided on the main mold body (annular surface forming the end surface of the polygonal flange)
409 Polygonal inner peripheral surface 430 for shaping the outer peripheral surface of the polygonal flange 430 Shape-holding punch 450 Separately used mold (cylindrical mold) used in the main molding process
453 End surface of a cylindrical mold used in the main forming step (annular surface for forming the end surface of the polygonal flange)

Claims (5)

Cold fitting of a cylindrical metal fitting with a polygonal flange having a cylindrical part having a hollow part penetrating through and a polygonal flange projecting outward on the outer peripheral surface of the intermediate part in the axial direction of the cylindrical part. A manufacturing method by forging,
In the intermediate molding step in the manufacturing process of the cylindrical flanged tubular metal fitting, the polygonal flanged cylindrical metal fitting is characterized by including at least the following steps for forming the polygonal flange: Manufacturing method by cold forging.
(1) By forming a recess by pressing a pre-hole forming punch into the center of one end face of a cylindrical blank, or by forming a pre-hole forming punch into the recess in a blank formed by forming the recess. When forming the preliminary hole to form the hollow portion by deepening the concave portion by pushing, the blank is used for forming the preliminary hole under a state in which the outer peripheral surface except the intermediate portion is restrained. The preliminary hole is formed by pushing a punch, and an overhanging portion for a polygon flange having a leading and trailing dimension larger than the leading and trailing dimensions of the polygon flange by swaging is preliminarily formed on the outer peripheral surface of the intermediate portion of the blank. preliminary formed inside the polygon regulatory inner peripheral surface that does not exceed the outer peripheral surface and the range should be of polygonal flange in the forming die body Preforming step of.
(2) The preliminary hole in the blank after the preliminary molding using the main body of the molding die having a polygonal inner peripheral surface for molding the outer peripheral surface of the polygonal flange after the preliminary molding step. With the shape retaining punch loaded in the blank, the blank is disposed in the main mold body so that the overhanging portion for the polygon flange is surrounded by the inner peripheral surface of the polygon. A main forming step of compressing the polygon flange to a predetermined front and rear length by pressurizing the overhanging portion for the polygon flange in the front and rear direction under the arrangement state.   In the pre-forming step, to constrain the outer peripheral surface of the blank excluding the front and rear intermediate portions, the pre-molding die main body and a separate die are used, and this separate die is used. The cylindrical metal fitting with a polygonal flange according to claim 1, wherein the cylindrical metal fitting with a polygonal flange according to claim 1, wherein the cylindrical metal fitting has a polygonal flange, and is arranged on the preliminary hole forming punch through an annular gap. Manufacturing method by cold forging.   In the preforming step, the regulation inner peripheral surface that does not exceed the range to be the outer peripheral surface of the polygonal flange is preliminarily molded in the preforming mold body with the same dimension or less as the outer peripheral surface of the polygonal flange. The cylindrical flanged cylindrical shape according to claim 2, wherein the inner peripheral surface of the blank is formed between the front and rear of the inner peripheral surfaces that constrain the front and rear across the intermediate portion of the blank. Manufacturing method by cold forging of metal fittings.   In the main molding step, the pressure applied in the front-rear direction of the overhanging portion for the polygon flange has an annular surface for molding each end face of the polygon flange, or between the separate molds or the separate mold The manufacturing method by cold forging of the cylindrical metal fitting with a polygonal flange according to any one of claims 1 to 3, wherein the method is performed on the annular surface provided on the main body of the molding die.   In the case where the pressure in the front-rear direction of the overhanging portion for the polygon flange in the main molding step is performed by a separate mold and the annular surface provided in the main mold body, this separate mold is used. The cylindrical flanged cylinder according to claim 4, wherein the mold is cylindrical, and is arranged in an externally fitted shape on the shape-retaining punch through an annular gap. Manufacturing method by cold forging of metal fittings.

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