Source: https://patents.google.com/patent/JP4929408B1/en
Timestamp: 2020-08-09 15:02:57
Document Index: 326457615

Matched Legal Cases: ['art 14', 'art 12', 'art 14', 'art 15', 'art 14', 'art 12', 'art 14', 'art 14', 'art 16', 'art 12', 'art 12', 'art 13', 'art 14', 'art 15', 'art 21', 'art 22', 'art 23', 'art 31', 'arts 64']

JP4929408B1 - Method for manufacturing hollow engine valve - Google Patents
Method for manufacturing hollow engine valve Download PDF
JP4929408B1
JP4929408B1 JP2011062198A JP2011062198A JP4929408B1 JP 4929408 B1 JP4929408 B1 JP 4929408B1 JP 2011062198 A JP2011062198 A JP 2011062198A JP 2011062198 A JP2011062198 A JP 2011062198A JP 4929408 B1 JP4929408 B1 JP 4929408B1
JP2011062198A
JP2012197718A (en
豹治 吉村
健一郎 平尾
宏和 森井
株式会社 吉村カンパニー
2011-03-22 Application filed by 三菱重工業株式会社, 株式会社 吉村カンパニー filed Critical 三菱重工業株式会社
2011-03-22 Priority to JP2011062198A priority Critical patent/JP4929408B1/en
2012-02-17 Priority claimed from KR20137022997A external-priority patent/KR101512919B1/en
2012-05-09 Publication of JP4929408B1 publication Critical patent/JP4929408B1/en
2012-10-18 Publication of JP2012197718A publication Critical patent/JP2012197718A/en
239000011265 semifinished products Substances 0.000 claims abstract description 65
238000004519 manufacturing process Methods 0.000 claims abstract description 23
A hollow engine valve manufacturing method capable of relatively easily manufacturing a hollow engine valve having a shaft portion having a desired thickness.
A method of manufacturing a hollow engine valve having a hollow portion formed from a shaft portion to an enlarged diameter portion of a valve head portion, comprising a shaft portion 11 and a valve head portion forming portion 12 connected to the shaft portion. By performing rotational plastic processing on the valve body semi-finished product 10 of the hollow engine valve in which the cylindrical hole portion 13 is formed from the shaft portion to the enlarged diameter portion of the valve head portion forming portion, A rotational plastic working step for reducing the diameter of the portion, and a necking step for reducing the outer diameter and the inner diameter of the shaft portion by performing necking on the valve body semi-finished product of the hollow engine valve following this step, Subsequently to this step, a sealing step of sealing the tip of the shaft portion to obtain a hollow engine valve is provided.
The present invention relates to a method for manufacturing a hollow engine valve in which a hollow portion is formed from a shaft portion (body portion) to an enlarged diameter portion of a valve head portion.
Various methods for manufacturing hollow engine valves (valves) have been developed, and there are methods for forming hollow engine valves by forging. For example, Patent Document 1 discloses a method for manufacturing a valve head portion of a hollow engine valve and a hollow engine valve.
In the manufacturing method described in Patent Document 1, a cup-shaped intermediate member is formed by punching a cylindrical hole with a punch on the upper surface of a solid round bar (cylindrical billet material) by hot forging, and forging the lower part. The diameter of the valve head part is formed by expanding the diameter of the head part, and necking is performed several times on the part to gradually squeeze the upper part of the part of the head part of the valve head part so that the valve head part and the hollow shaft part connected thereto are formed. Molded to obtain a hollow engine valve body.
Japanese Patent No. 430291 (for example, see [Example 1], [FIG. 1] to [FIG. 4], etc.)
In the above-described method for manufacturing a hollow engine valve, as shown in FIG. 6, a valve body semi-finished product of a hollow engine valve is molded to obtain a valve body. First, as shown in FIG. 6A, a semifinished valve body 100 of a hollow engine valve having a shaft portion (body portion) 101 having a wall thickness t 0 and a valve head portion forming portion 102 connected thereto is prepared. In the semifinished product 100 of the hollow engine valve, a hole portion 103 having a diameter d 0 is formed from the shaft portion 101 to the enlarged diameter portion of the valve head portion forming portion 102. Subsequently, by performing the first necking, as shown in FIG. 6B, the shaft portion 104 has a wall thickness t 1 (> t 0 ) and the hole portion 105 has a diameter d 1 (<d 0 ). It becomes. Subsequently, by performing the second necking process, as shown in FIG. 6C, the shaft portion 106 has a thickness t 2 (> t 1 ) and the hole portion 107 has a diameter d 2 (<d 1 ). It becomes. By repeating the necking process a plurality of times and performing the n-th necking process in this way, as shown in FIG. 6D, the shaft portion 108 has a wall thickness t n (> t (n−1) ), The hole 109 has a diameter d n (<d (n−1) ).
In the necking process described above, a mandrel (core) cannot be placed in the hole of the semifinished product of the hollow engine valve. For this reason, when the shaft portion is drawn up by necking, the thickness of the shaft portion increases in accordance with the number of times of this processing. Therefore, the thickness of the shaft portion of the valve body of the hollow engine valve is restricted by the thickness of the shaft portion of the semifinished product of the hollow engine valve and the number of times of necking. Further, the thickness of the shaft portion of the semifinished hollow valve body of the hollow engine valve has to be a predetermined size or more so that the shaft portion is not buckled and deformed. Thus, it has been difficult to obtain a hollow engine valve having a shaft portion having a desired thickness by the above-described method for manufacturing a hollow engine valve.
In view of the above, the present invention has been made to solve the above-described problems, and it is possible to manufacture a hollow engine valve having a shaft portion having a desired thickness relatively easily. It aims to provide a method.
A method for manufacturing a hollow engine valve according to a first invention for solving the above-described problem is as follows.
A method of manufacturing a hollow engine valve in which a hollow portion is formed from a shaft portion to a diameter-enlarged portion of a valve head portion,
A valve body of a hollow engine valve comprising a shaft portion and a valve head portion forming portion connected to the shaft portion, and having a cylindrical hole formed from the shaft portion to the enlarged diameter portion of the valve head portion forming portion. A first rotational plastic working step for reducing the diameter of the shaft portion by performing rotational plastic working on the semi-finished product;
Continuing from this step, for the semifinished product of the hollow engine valve body, a die hole for pressing the enlarged portion and the shaft portion of the valve head portion forming portion of the semifinished product of the hollow engine valve. Necking that reduces the outer diameter and inner diameter of the shaft by performing necking that gradually reduces the inner diameter of the shaft by using the number of dies that are gradually reduced as the stage progresses. Processing steps,
Subsequent to this step, a sealing step of obtaining a hollow engine valve by sealing the tip of the shaft portion is provided.
A method for manufacturing a hollow engine valve according to a second invention for solving the above-described problem is as follows.
A method for manufacturing a hollow engine valve according to a first invention,
The rotary plastic working is performed by inserting a core into the hole of the semifinished hollow engine valve body and rotating the shaft of the semifinished hollow engine valve body and the core together. Rotary swaging that strikes the outer periphery of the shaft with a swaging die, or inserts a core into the hole of the semifinished hollow engine valve body, and the hollow engine valve body half It is a spinning process in which a spinning die is pressed against the outer peripheral part of the shaft part while rotating the finished product and the core together.
A method for manufacturing a hollow engine valve according to a third invention for solving the above-described problem is as follows.
The rotary plastic working is a rotary swaging process in which a semi-finished product of the hollow engine valve body is axially rotated, and the outer periphery of the shaft part is hit by a swaging die, or the hollow engine valve Spinning processing that rotates a semifinished product of the valve body while pressing a spinning die on the outer periphery of the shaft portion;
Subsequent to this processing, a core is inserted into the hole of the semifinished hollow engine valve body, and the shaft of the semifinished hollow engine valve body and the core is rotated together. Rotary swaging that gives a blow with a swaging die to the outer periphery of the part, or insert a core into the hole of the semi-finished product of the hollow engine valve body, semi-finished of the hollow engine valve body It is a combination with spinning processing in which a spinning die is pressed against the outer peripheral portion of the shaft portion while rotating the product and the core together.
A method for manufacturing a hollow engine valve according to a fourth invention for solving the above-described problem is as follows.
After performing the necking process on the valve body semi-finished product of the hollow engine valve, a rotary plastic process is performed to reduce the outer diameter while maintaining the inner diameter of the shaft part. It further comprises a rotational plastic working process.
A method for manufacturing a hollow engine valve according to a fifth invention for solving the above-described problem is as follows.
A method for manufacturing a hollow engine valve according to a fourth invention,
In the second rotational plastic working step, the rotational plastic working inserts a core into the hole of the semifinished hollow engine valve body, and the semifinished hollow engine valve body and the core. Rotating the shaft together, rotary swaging processing that gives a blow with a swaging die to the outer periphery of the shaft portion, or inserting a core into the hole of the semi-finished valve body of the hollow engine valve A spinning process in which a spinning die is pressed against the outer peripheral portion of the shaft portion while rotating the valve body semi-finished product of the hollow engine valve and the core together.
A method for manufacturing a hollow engine valve according to a sixth invention for solving the above-described problem is as follows.
The rotational plastic working of the second rotational plastic working step is performed only on a portion other than the upper portion of the shaft portion, and the outer diameter is maintained while maintaining the size of the inner diameter outside the upper portion of the shaft portion. While reducing the diameter, the outer diameter at the upper part of the shaft part is a large diameter part while maintaining the size before processing,
In the sealing step, the hollow engine valve is obtained by pressing the large-diameter portion and sealing the tip of the shaft portion.
A method for manufacturing a hollow engine valve according to a seventh invention for solving the above-described problem is as follows.
A valve body of a hollow engine valve comprising a shaft portion and a valve head portion forming portion connected to the shaft portion, and having a cylindrical hole formed from the shaft portion to the enlarged diameter portion of the valve head portion forming portion. For semi-finished products, the diameter of the enlarged portion of the valve head portion forming portion of the semifinished hollow engine valve body and the inner diameter of the die hole of the die that presses the shaft portion are gradually reduced as the stages progress. A first necking step of reducing the outer diameter and the inner diameter of the shaft portion by performing necking processing to gradually reduce the diameter of the die using the number of drawing steps;
Subsequent to this step, by performing rotational plastic processing on the valve body semi-finished product of the hollow engine valve, a rotational plastic processing step of reducing the diameter of the shaft portion;
A method for manufacturing a hollow engine valve according to an eighth invention for solving the above-described problem is as follows.
A method for manufacturing a hollow engine valve according to a seventh invention,
A method for manufacturing a hollow engine valve according to a ninth invention for solving the above-described problem is as follows.
A die that presses the diameter-enlarged portion and the shaft portion of the valve head portion forming portion of the valve body semi-finished product of the hollow engine valve after performing the rotational plastic working on the valve engine semi-finished product of the hollow engine valve. The outer diameter and the inner diameter of the shaft portion are reduced by performing necking processing in which the inner diameter of the die hole is gradually reduced by the number of the drawing-up steps, each time the die is gradually reduced. It is further characterized by further comprising a second necking step for diameter.
A method for manufacturing a hollow engine valve according to a tenth aspect of the invention for solving the above-described problem is as follows.
The rotational plastic working is performed only on a portion other than the upper portion of the shaft portion, and the outer diameter is reduced while maintaining the size of the inner diameter outside the upper portion of the shaft portion. The outer diameter at the upper part is the large diameter part while maintaining the size before processing,
According to the method for manufacturing a hollow engine valve according to the first or second aspect of the invention, the thickness of the shaft portion is made uniform in the circumferential direction and the axial direction by performing the rotational plastic processing before performing the necking processing. It is possible to improve the yield in the next necking process. Further, only the necking is performed after the rotational plastic working, and a hollow engine valve having a shaft portion with a desired thickness can be manufactured relatively easily.
According to the method for manufacturing a hollow engine valve according to the third aspect of the invention, the same effects as the method for manufacturing the hollow engine valve according to the first aspect of the invention can be achieved, and a rotary swaging process or spinning process using a core. By performing the rotary swaging process or the spinning process without using the core, the outer diameter and thickness of the shaft portion of the semifinished hollow engine valve body can be adjusted.
According to the method for manufacturing a hollow engine valve according to the fourth invention, the same effect as the method for manufacturing the hollow engine valve according to the first invention is achieved, and the rotational plastic processing is performed after the necking processing. Accordingly, the outer diameter of the shaft portion of the semifinished hollow engine valve body can be adjusted to a desired size. Further, the machining accuracy of the inner diameter of the shaft portion of the hollow engine valve can be improved as compared with the method of manufacturing the hollow engine valve that performs necking at the end.
According to the method for manufacturing a hollow engine valve according to the fifth aspect of the invention, the same effect as the method for manufacturing the hollow engine valve according to the fourth aspect of the invention can be obtained. By performing the swaging process or the spinning process, the outer diameter of the shaft portion of the hollow engine valve can be adjusted to a desired size. Further, the machining accuracy of the inner diameter of the shaft portion of the hollow engine valve can be improved as compared with the method of manufacturing the hollow engine valve that performs necking at the end.
According to the method for manufacturing a hollow engine valve according to the seventh or eighth invention, the shaft of the hollow engine valve is obtained by performing rotational plastic working after making the inner diameter of the shaft portion a desired size by performing necking. The outer diameter of the part can be adjusted to a desired size. Further, the machining accuracy of the inner diameter of the shaft portion of the hollow engine valve can be improved as compared with the method of manufacturing the hollow engine valve that performs necking at the end.
According to the method for manufacturing a hollow engine valve according to the ninth aspect of the present invention, the rotational plastic working is performed after the necking process, and the necking process is performed after the necking process. Compared to the case where the shaft portion of the hollow engine valve is formed, a core having a large diameter can be used in the rotational plastic working, and the complication of the manufacturing operation can be suppressed.
According to the method for manufacturing a hollow engine valve according to the sixth or tenth invention, the end portion of the shaft portion can be closed by a series of processing operations, and there is no need to separately prepare a member for closing the end portion of the shaft portion. Therefore, the manufacturing process can be simplified.
BRIEF DESCRIPTION OF THE DRAWINGS It is a figure for demonstrating the manufacturing method of the hollow engine valve which concerns on 1st Example of this invention, Comprising: FIG. 1A shows the perspective view of the valve body semi-finished product of the hollow engine valve before a process, FIG. FIG. 1C shows a state during the first necking, FIG. 1D shows a state during the n-th necking, and FIG. 1E shows a perspective view of the finished product of the hollow engine valve. Indicates. It is a graph which shows the relationship between the process by the manufacturing method of the hollow engine valve which concerns on this invention, and the magnitude | size of the internal diameter of an axial part, and an outer diameter. It is a figure for demonstrating the manufacturing method of the hollow engine valve which concerns on the 6th Example of this invention, Comprising: A top is shown to FIG. 3A, and a perspective view is shown to FIG. 3B. It is a figure for demonstrating the manufacturing method of the hollow engine valve which concerns on 6th Example of this invention, Comprising: The cross section of the hollow engine valve before edge part processing is shown to FIG. 4A, FIG. 2 shows a cross section of a hollow engine valve. It is a figure for demonstrating the other example of the manufacturing method of the hollow engine valve which concerns on this invention, Comprising: The perspective view of the valve body semi-finished product of the hollow engine valve before a process is shown to FIG. 5A, FIG. FIG. 5C shows the state during the first necking, FIG. 5D shows the state during the n-th necking, and FIG. 5E shows a perspective view of the finished product of the hollow engine valve. It is a figure for demonstrating the manufacturing method of the conventional hollow engine valve, Comprising: The cross section of the valve body semi-finished product of the hollow engine valve before a process is shown to FIG. 6A, The cross section after the 1st necking process to FIG. 6B 6C shows a cross section after the second necking process, and FIG. 6D shows a cross section after the nth necking process.
The method for producing a hollow engine valve according to the present invention will be specifically described in each example.
A method for manufacturing a hollow engine valve according to a first embodiment of the present invention will be described with reference to FIGS. In FIG. 2, the horizontal axis indicates the process, and the vertical axis indicates the inner diameter and the outer diameter of the shaft portion of the valve body semifinished product of the hollow engine valve and the valve body after each process. Moreover, the cross mark indicates the valve body semi-finished product of the hollow engine valve and the valve body according to the first embodiment, and the triangle mark indicates the hollow engine valve semi-finished product and the valve body. The magnitude | size of the internal diameter of a axial part is shown, and a continuous line shows the case of Example 1. FIG. In addition, in the process S0 (initial state), the size of the inner diameter and the outer diameter of the shaft portion in the semifinished product of the hollow engine valve body are shown.
In this embodiment, the necking process is performed after the rotary swaging process (rotational plastic process) is performed on the semifinished hollow engine valve body. Specifically, as shown in FIG. 2, rotary swaging is performed on the semifinished hollow engine valve body in the first step S1 to the second step S2 (first rotational plastic working step). Subsequently, necking is performed in a process (necking process) from the third process S3 to the eighth process S8.
Prepare semi-finished hollow engine valve body. As shown in FIG. 1A, the hollow engine valve valve body semi-finished product 10 includes a shaft portion (body portion) 11 and a valve head portion forming portion 12 a connected to the lower end portion of the shaft portion 11. A cylindrical hole portion 13 is formed from the shaft portion 11 to the enlarged diameter portion of the valve head portion forming portion 12a.
First, rotary swaging is performed on the shaft part of the semifinished hollow engine valve body. For example, as shown in FIG. 1B, a core 52 is placed in the shaft portion 11 of the semifinished hollow engine valve body 10, and the direction R about the axis of the semifinished hollow engine valve body 10 is centered. In addition, while the valve body semifinished product 10 and the core 52 of the hollow engine valve are rotated together, the outer peripheral portion 11a of the shaft portion 11 is hit by a die (swaging die) 51. As a result, the outer diameter of the shaft portion 11 is reduced. Here, two dies 51 are used as one set, and four dies 51 are used. A pair of dies 51, 51 are opposed to each other with the shaft portion 11 as the center. The tip portion 51 a of the die 51 is formed in a curved shape along the shaft portion 11. This processing is performed until the outer diameter of the shaft portion of the semifinished hollow engine valve body becomes a predetermined size. In this example, rotary swaging using a core is performed from the first step S1 to the second step S2. Thereby, it has the shaft part 14 and the valve head part formation part 12b connected to the lower end part of the shaft part 14, and the hole part 15 is formed ranging from the shaft part 14 to the enlarged diameter part of the valve head part formation part 12b. Semi-finished product of hollow engine valve body is obtained. The outer diameter of the shaft portion 14 of the semifinished hollow engine valve body is formed to a predetermined size (> d1).
Subsequently, necking is performed on the semifinished hollow engine valve body obtained by the rotary swaging process described above. That is, with respect to the semifinished hollow engine valve body, the inner diameter of the die diameter hole of the die that presses the shaft portion and the enlarged diameter portion of the valve head portion forming portion of the semifinished hollow engine valve body Each time the stages progress, necking is performed in which the diameter is gradually reduced by using the number of dies that are gradually reduced in diameter for the number of the drawing-up steps. For example, in the first drawing process, necking is performed using a die 61 as shown in FIG. 1C. First, the die 61 is disposed above the semi-finished valve body of the hollow engine valve. The die 61 has a cylindrical shape, and a die hole 62 is formed from the lower surface portion 61a to the upper surface portion 61b. The die hole 62 is opened to the lower surface portion 61a and has a reduced diameter portion 63 that is reduced in diameter as it goes upward, and a same diameter portion 64 that is connected to the reduced diameter portion 63 and extends from the lower portion to the upper portion with the same diameter. Have By forming the reduced diameter portion 63 by opening the lower surface portion 61 a of the die 61, the shaft portion 14 of the semifinished hollow engine valve body can be smoothly guided to the same diameter portion 64 of the die 61. Subsequently, the shaft part 14 of the semifinished hollow engine valve body and the shaft center of the die hole 62 of the die 61 are aligned and pressed against the semifinished hollow engine valve body. The shaft portion 14 of the semifinished hollow engine valve body is squeezed out by the die 61. Thereby, the axial part 14 is extended in an axial direction. Further, the shaft portion 14 is thicker than before the necking process. The inner diameter and outer diameter of the hole 15 in the shaft portion 14 are smaller than those before necking.
When the outer diameter of the shaft portion becomes smaller, the die is replaced with a die corresponding to the size of the outer diameter of the shaft portion, and the shaft portion is squeezed up using this die. For example, in the n-th throttling step, necking is performed using a die 65 as shown in FIG. 1D. However, n is a positive number of 2 or more. First, the die 65 is disposed above the semifinished product of the hollow engine valve obtained in the (n-1) -th throttling step. The die 65 has a cylindrical shape like the die 61, and a die hole 66 is formed from the lower surface portion 65a to the upper surface portion 65b. The die hole 66 is open to the lower surface portion 65a and has a reduced diameter portion 67 that is reduced in diameter as it goes upward, and a same diameter portion 68 that is connected to the reduced diameter portion 67 and extends from the lower portion to the upper portion with the same diameter. Have The die hole 66 has a smaller diameter than the die hole 62, and the same diameter portion 68 is formed to have a smaller diameter than the same diameter portion 64. Subsequently, the shaft portion 16 of the semifinished hollow engine valve body and the shaft center of the die hole 66 of the die 65 are aligned and pressed against the semifinished hollow engine valve body. The shaft portion 16 of the semifinished hollow engine valve body is squeezed out by the die 65. Thereby, the axial part 16 is extended in an axial direction. Further, the shaft portion 16 is thicker than before necking. The inner diameter and outer diameter of the hole 17 in the shaft portion 16 are smaller than before the necking process.
In other words, the necking process described above is performed using a die having a die hole formed in accordance with the outer diameter of the shaft part of the semifinished hollow engine valve body, and the shaft part has a predetermined outer diameter. The process is performed until the size becomes d1 and the inner diameter of the shaft portion reaches a predetermined size d2 (<d1). Thereby, the outer diameter of the shaft portion 18 is d1, and the diameter of the hole portion 19 of the shaft portion 18 is the valve body of the hollow engine valve. In this embodiment, necking is performed from the third step S3 to the eighth step S8.
Subsequently, the shaft portion is machined into a predetermined length as necessary with respect to the valve body of the hollow engine valve obtained by the necking process described above. And a hollow engine valve is obtained by sealing the front-end | tip (upper end) of a axial part at a sealing process. For example, as shown in FIG. 1E, a hollow engine valve (finished product) is obtained by welding a cylindrical sealing member 31 to the tip of the shaft 18 and sealing the tip of the shaft. Can do.
Therefore, according to the method for manufacturing the hollow engine valve according to the present embodiment, the thickness of the shaft portion is made uniform in the circumferential direction and the axial direction by performing the rotary swaging process before performing the necking process. It is possible to improve the yield in the necking process of the next process. Further, only the necking process is performed after the rotary swaging process, and a hollow engine valve having a shaft portion having a desired thickness can be manufactured relatively easily.
A method for manufacturing a hollow engine valve according to a second embodiment of the present invention will be specifically described with reference to FIG. In FIG. 2, the cross mark indicates the semifinished product of the hollow engine valve according to the second embodiment and the outer diameter of the shaft portion of the valve body, and the triangle mark indicates the semifinished product of the hollow engine valve body. The magnitude | size of the internal diameter of the axial part in a valve main body is shown, and the dashed-two dotted line shows the case of Example 2. FIG.
In this embodiment, the rotary swaging process (rotational plastic working) in the method for manufacturing the hollow engine valve according to the first embodiment described above is performed in two steps. First, a rotary swaging process is performed without using a core, and then a rotary swaging process is performed by inserting the core into a shaft part of a semifinished hollow engine valve body. Specifically, as shown in FIG. 2, the core is not used in the first to third steps S3 (first rotational plastic working step) for the semifinished hollow engine valve body. Next, rotary swaging is performed, followed by rotary swaging using a core in the fourth step S4 and fifth step S5 (second rotational plastic working step), Necking is performed in steps S6 to S8 (necking step).
First, a rotary swaging process is performed on the shaft part of the semifinished hollow engine valve body without using a core. Thereby, the inner diameter and outer diameter of the shaft portion of the semifinished product of the hollow engine valve are reduced. This is because there is no core in the shaft part of the semifinished hollow engine valve body, and there is no member that receives this force inside the shaft part when the die strikes the outer peripheral part of the shaft part. This process is performed until the inner diameter and outer diameter of the shaft portion of the semifinished hollow engine valve body become a predetermined size. In this embodiment, the rotary swaging process is performed from the first step S1 to the third step S3 without using the core. Subsequently, the core is placed in the shaft portion of the semifinished hollow engine valve body obtained by the above-described rotary swaging process without using the core, and the rotary swaging process is performed. As a result, the outer diameter is reduced while maintaining the inner diameter of the shaft portion. The rotary swaging process using the core is performed until the outer diameter of the shaft portion of the semifinished hollow engine valve body becomes a predetermined size. In this embodiment, rotary swaging using a core is performed from the fourth step S4 to the fifth step S5.
Subsequently, the valve engine semi-finished product of the hollow engine valve obtained by the rotary swaging process using the above-described core is necked in the same manner as the hollow engine valve manufacturing method according to the first embodiment described above. Processing. That is, for the semifinished product of the hollow engine valve body, each time the step proceeds, the die hole for pressing the valve head part and the shaft part of the semifinished product of the hollow engine valve body Necking is performed by gradually reducing the diameter of the dies, which are gradually reduced, by the number of squeezing steps. This processing is performed until the outer diameter of the shaft portion of the semifinished hollow engine valve body reaches a predetermined size d1 and the inner diameter of the shaft portion reaches a predetermined size d2 (<d1). Thereby, the outer diameter of the shaft portion 18 is d1, and the diameter of the hole portion 19 of the shaft portion 18 is the valve body of the hollow engine valve. In this embodiment, necking is performed from the sixth step S6 to the eighth step S8.
Subsequently, the length of the shaft portion of the valve body of the hollow engine valve obtained by the necking process described above is adjusted as necessary, and in the same manner as the method for manufacturing the hollow engine valve according to the first embodiment described above, By sealing the tip (upper end) of the shaft portion of the valve body of the hollow engine valve, a hollow engine valve (finished product) can be obtained.
Therefore, according to the method for manufacturing a hollow engine valve according to the present embodiment, the same effects as the method for manufacturing the hollow engine valve according to the first embodiment described above can be obtained, and rotary swaging can be performed using a core. By performing rotary swaging without using a core before processing, the outer diameter and thickness of the shaft portion of the semifinished valve body of the hollow engine valve can be adjusted.
A method for manufacturing a hollow engine valve according to a third embodiment of the present invention will be specifically described with reference to FIG. In FIG. 2, the cross mark indicates the semifinished product of the hollow engine valve according to the third embodiment and the outer diameter of the shaft portion of the valve body, and the triangle mark indicates the semifinished product of the hollow engine valve body. The magnitude | size of the internal diameter of the axial part in a valve main body is shown, and a dotted line shows the case of Example 3. FIG.
In this embodiment, rotary swaging processing (rotational plastic processing) using a core, necking processing, and rotary swaging processing (rotational plastic processing) using a core are performed in the order described. Specifically, as shown in FIG. 2, rotary swaging using a core is performed in the first step S1 (first rotational plastic working step) on a semifinished hollow engine valve body. Subsequently, necking is performed in the second step S2 to the seventh step S7 (necking step), and then the core is used in the eighth step S8 (second rotational plastic working step). The rotary swaging process that had been done. That is, in this embodiment, in the first step S1, a core is used as in the first step S1 to the second step S2 in the method for manufacturing the hollow engine valve according to the first embodiment described above. Rotary swaging is performed, and in the second step S2 to the seventh step S7, as in the third step S3 to the eighth step S8 in the first embodiment described above, necking is performed. The description is omitted.
In the present embodiment, necking is performed on the semifinished hollow engine valve body, and the inner diameter of the shaft of the semifinished hollow engine valve body is in the vicinity of a predetermined size d2 (≧ d2). When the outer diameter is in the vicinity of a predetermined size (> d1), the core is inserted into the shaft portion and rotary swaging is performed. In this processing, a core corresponding to the size of the inner diameter of the shaft portion of the semifinished hollow engine valve body adjusted by necking is used. As a result, the outer diameter is reduced while maintaining the inner diameter of the shaft portion. The rotary swaging process using the core is performed until the outer diameter of the shaft portion of the semifinished hollow engine valve body reaches a predetermined size d1. Thereby, it becomes a valve body of a hollow engine valve. In the present embodiment, rotary swaging using a core is performed in the eighth step S8.
Subsequently, the length of the shaft portion of the valve body of the hollow engine valve obtained by the rotary swaging process described above is adjusted as necessary, and is the same as the method for manufacturing the hollow engine valve according to the first embodiment described above. Furthermore, a hollow engine valve (finished product) can be obtained by sealing the tip (upper part) of the shaft portion of the valve body of the hollow engine valve.
Therefore, according to the method for manufacturing a hollow engine valve according to the present embodiment, the same effects as the method for manufacturing the hollow engine valve according to the first embodiment described above can be obtained, and in addition, the rotary engine valve can be rotated after necking. By performing the aging process, the outer diameter of the shaft portion of the semifinished hollow engine valve body can be adjusted to a desired size. Further, the machining accuracy of the inner diameter of the shaft portion of the hollow engine valve can be improved as compared with the method of manufacturing the hollow engine valve that performs necking at the end.
A method for manufacturing a hollow engine valve according to a fourth embodiment of the present invention will be described with reference to FIGS. In FIG. 2, the cross marks indicate the valve body semi-finished product of the hollow engine valve according to Example 4 and the outer diameter of the shaft portion of the valve body, and the triangle marks indicate the semi-finished product of the hollow engine valve valve body. The magnitude | size of the internal diameter of the axial part in a valve main body is shown, and the dashed-dotted line shows the case of Example 4. FIG.
In the present embodiment, the rotary swaging process (rotational plastic processing) is performed after necking the semifinished hollow engine valve body. Specifically, as shown in FIG. 2, the semifinished hollow engine valve body is subjected to necking in the first step S1 to the sixth step S6 (first necking step), followed by Thus, rotary swaging using a core is performed in the seventh step S7 to the eighth step S8 (rotational plastic working step).
As in the case of the hollow engine valve manufacturing method according to the first embodiment described above, a semifinished product of the hollow engine valve body is prepared. As shown in FIG. 1A, the semifinished product 10 of the hollow engine valve has a shaft portion (body portion) 11 and a valve head portion forming portion 12 a connected to the lower end portion of the shaft portion 11. A cylindrical hole 13 is formed from 11 to the enlarged diameter portion of the valve head portion 12a.
First, necking is performed on the semifinished hollow engine valve body in the same manner as the hollow engine valve manufacturing method according to the first embodiment described above. That is, for the semifinished product of the hollow engine valve body, each time the step proceeds, the die hole for pressing the valve head part and the shaft part of the semifinished product of the hollow engine valve body Necking is performed by gradually reducing the diameter of the dies, which are gradually reduced, by the number of squeezing steps. As the dice, for example, dice 61 and 65 shown in FIGS. 1C and 1D are used. This processing is performed until the inner diameter of the shaft part of the semifinished hollow engine valve body becomes a predetermined size d2 (≧ d2) and the outer diameter reaches a predetermined size (> d1). . In the present embodiment, necking is performed from the first step S1 to the sixth step S6.
Subsequently, a core is inserted into the shaft portion of the semifinished hollow engine valve body obtained by the necking process described above, and a rotary swaging process is performed. In this processing, a core corresponding to the size of the inner diameter of the shaft portion of the semifinished hollow engine valve body adjusted by necking is used. This reduces the outer diameter of the hollow engine valve while maintaining the inner diameter of the shaft portion of the semifinished product of the valve body. The rotary swaging process using the core is performed until the outer diameter of the shaft portion of the semifinished hollow engine valve body described above reaches a predetermined size d1 (> d2). Thereby, it becomes a valve body of a hollow engine valve. In this embodiment, the rotary swaging process is performed on the core from the seventh step S7 to the eighth step S8.
Subsequently, the length of the shaft portion of the valve body of the hollow engine valve obtained by the rotary swaging process described above is adjusted as necessary, and is the same as the method for manufacturing the hollow engine valve according to the first embodiment described above. Further, a hollow engine valve (finished product) can be obtained by sealing at the tip (upper end) of the shaft portion of the valve body of the hollow engine valve.
Therefore, according to the method for manufacturing a hollow engine valve according to the present embodiment, the shaft portion of the hollow engine valve is obtained by performing rotary swaging after making the inner diameter of the shaft portion a desired size by performing necking. Can be adjusted to a desired size. Further, the machining accuracy of the inner diameter of the shaft portion of the hollow engine valve can be improved as compared with the method of manufacturing the hollow engine valve that performs necking at the end.
A method for manufacturing a hollow engine valve according to a fifth embodiment of the present invention will be described with reference to FIG. In FIG. 2, the cross mark indicates the semifinished product of the hollow engine valve body according to the fifth embodiment and the outer diameter of the shaft portion of the valve body, and the triangle mark indicates the semifinished product of the hollow engine valve body. The magnitude | size of the internal diameter of the axial part in a valve main body is shown, and the dashed-two dotted line shows the case of Example 5. FIG.
In this embodiment, necking, rotary swaging using a core (rotary plastic processing), and necking are performed in the order described. Specifically, as shown in FIG. 2, necking is performed on the semifinished hollow engine valve body from the first step S1 to the third step S3 (first necking step), and then Then, in the fourth step S4 to the fifth step S5 (rotational plastic working step), rotary swaging using a core having a predetermined diameter (> d2) is performed, and then from the sixth step S6. Necking is performed in the eighth step S8 (second necking step). That is, in this embodiment, the first step S1 to the third step S3 are the same as the first step S1 to the sixth step S6 in the method for manufacturing the hollow engine valve according to the fourth embodiment described above. In addition, in the fourth step S4 to the fifth step S5, as in the seventh step S7 to the eighth step S8 in the fourth embodiment described above, the rotary machine using the core is performed. Aging processing is performed, and the description thereof is omitted.
In this embodiment, the semi-finished hollow engine valve body is subjected to rotary swaging after the necking, and the inner diameter of the shaft of the hollow engine valve semi-finished body is a predetermined size (> d2). When the outer diameter reaches a predetermined size (> d1), the hollow engine valve semi-finished product of the hollow engine valve obtained by the rotary swaging process is hollowed according to the first embodiment described above. Necking is performed in the same manner as the engine valve manufacturing method. That is, for the semifinished product of the hollow engine valve body, each time the step proceeds, the die hole for pressing the valve head part and the shaft part of the semifinished product of the hollow engine valve body Necking is performed by gradually reducing the diameter of the dies, which are gradually reduced, by the number of squeezing steps. This processing is performed until the outer diameter of the shaft portion of the semifinished hollow engine valve body reaches a predetermined size d1 and the inner diameter of the shaft portion reaches a predetermined size d2 (<d1). Thereby, it becomes a valve body of a hollow engine valve. In this embodiment, necking is performed from the sixth step S6 to the eighth step S8.
Subsequently, the length of the shaft portion of the valve body of the hollow engine valve obtained by the necking process described above is adjusted as necessary, and in the same manner as the method for manufacturing the hollow engine valve according to the first embodiment described above, A hollow engine valve (finished product) can be obtained by sealing at the tip (upper end) of the shaft portion of the valve body of the hollow engine valve.
Therefore, according to the manufacturing method of the hollow engine valve according to the present embodiment, the rotary swaging process is performed after the necking process, and the necking process is further performed subsequently to this process. Compared with the case where the shaft portion of the hollow engine valve is formed by performing aging processing, a core having a large diameter can be used in the rotary swaging processing, and the complication of the manufacturing operation can be suppressed.
A method for manufacturing a hollow engine valve according to a sixth embodiment of the present invention will be described with reference to FIGS.
In this embodiment, the rotary swaging process after the necking process in the method for manufacturing the hollow engine valve in the third or fourth embodiment described above is performed, and the shaft of the semifinished product of the valve body of the hollow engine valve is used. This is performed not on the entire part but only on the part other than the upper part. Following this processing, the upper part of the shaft part is pressed to seal the tip of the shaft part.
In the present embodiment, necking is performed on the semifinished hollow engine valve body, and the inner diameter of the shaft of the semifinished hollow engine valve body is in the vicinity of a predetermined size d2 (≧ d2). When the outer diameter reaches a predetermined size (> d1), a core is inserted into the shaft portion and rotary swaging is performed. Specifically, as shown in FIGS. 3A and 3B, a core 56 is placed in the hole 23 of the shaft portion 21 of the valve body semi-finished product of the hollow engine valve after necking, and the hollow body is hollow. While rotating in the direction R about the shaft center of the semifinished engine valve body, only a portion other than the upper portion of the shaft portion 21 is hit by a die (swaging die) 55. Thereby, the outer diameter is reduced while maintaining the size of the inner diameter other than the upper portion of the shaft portion 21. On the other hand, the outer diameter of the upper portion of the shaft portion 21 is the large diameter portion 22 while maintaining the size before processing. Note that the inner diameter of the upper portion of the shaft portion 21 is also maintained at the size before processing.
Subsequently, when the outer diameter of the portion other than the upper portion of the shaft portion 21 of the semifinished hollow engine valve body becomes a predetermined size d1, in the sealing step, as shown in FIG. The large diameter portion 22 is pressed in the direction of arrow Y toward the axis of the shaft portion 21. As a result, as shown in FIG. 4B, the large-diameter portion 22 is pressed to form an end sealing portion 24 that seals the tip of the shaft portion 21.
Therefore, according to the method for manufacturing the hollow engine valve according to the present embodiment, the same effect as the method for manufacturing the hollow engine valve according to the third embodiment and the fourth embodiment can be obtained, and a series of processing operations can be performed. Since the end of the shaft portion 21 can be closed and there is no need to separately prepare a member for closing the end portion of the shaft portion 21, the manufacturing process can be simplified.
In the first to sixth embodiments described above, the case where the rotational plastic processing is rotary swaging processing has been described. However, spinning processing is used as rotational plastic processing, or rotary swaging processing and spinning processing are used in combination. It is also possible to do. In such a case, the same effects as those of the method for manufacturing the hollow engine valve described above are obtained. For example, as shown in FIG. 5, a spinning process can be performed instead of the rotary swaging process in the rotational plastic working process of the method for manufacturing the hollow engine valve according to the first embodiment described above. Specifically, as shown in FIG. 5B, a core 54 is inserted into the hole 13 of the semifinished hollow engine valve body 10, and the axial center of the semifinished hollow engine valve body 10 is centered. The die (spinning die) 53 is pressed against the outer peripheral portion 11a of the shaft portion 11 while rotating the valve body semifinished product 10 of the hollow engine valve 10 and the core 54 together in the direction R. Thereby, the outer diameter can be reduced while maintaining the size of the inner diameter of the shaft portion of the semifinished hollow engine valve body.
According to the method for manufacturing a hollow engine valve according to the present invention, a hollow engine valve having a shaft portion having a desired thickness can be manufactured relatively easily, and thus can be beneficially used in the automobile industry and the like.
DESCRIPTION OF SYMBOLS 10 Valve body semi-finished product of hollow engine valve 11 Shaft part 12a-12c Valve head part formation part 12d Valve head part 13 Hole part 14, 16, 18 Shaft part 15, 17, 19 Hole part 21 Shaft part 22 Large diameter part 23 Hole 24 End sealing part 31 Sealing member 51 Die 52 Core (mandrel)
55 Dice 56 Core (Mandrel)
61, 65 Dies 62, 66 Holes 63, 67 Reduced diameter parts 64, 68 Same diameter parts
A method for manufacturing a hollow engine valve, comprising: a sealing step of obtaining a hollow engine valve by sealing the tip of the shaft portion subsequent to this step.
It is a manufacturing method of the hollow engine valve according to claim 1,
The rotary plastic working is performed by inserting a core into the hole of the semifinished hollow engine valve body and rotating the shaft of the semifinished hollow engine valve body and the core together. Rotary swaging that strikes the outer periphery of the shaft with a swaging die, or inserts a core into the hole of the semifinished hollow engine valve body, and the hollow engine valve body half A method for manufacturing a hollow engine valve, comprising: a spinning process in which a spinning die is pressed against an outer peripheral part of the shaft part while rotating the finished product and the core together.
Subsequent to this processing, a core is inserted into the hole of the semifinished hollow engine valve body, and the shaft of the semifinished hollow engine valve body and the core is rotated together. Rotary swaging that gives a blow with a swaging die to the outer periphery of the part, or insert a core into the hole of the semi-finished product of the hollow engine valve body, semi-finished of the hollow engine valve body A method of manufacturing a hollow engine valve, which is a combination of a spinning process in which a spinning die is pressed against an outer peripheral part of the shaft part while rotating an article and the core together.
After performing the necking process on the valve body semi-finished product of the hollow engine valve, a rotary plastic process is performed to reduce the outer diameter while maintaining the inner diameter of the shaft part. A method for producing a hollow engine valve, further comprising a rotational plastic working step.
It is a manufacturing method of the hollow engine valve according to claim 4,
In the second rotational plastic working step, the rotational plastic working inserts a core into the hole of the semifinished hollow engine valve body, and the semifinished hollow engine valve body and the core. Rotating the shaft together, rotary swaging processing that gives a blow with a swaging die to the outer periphery of the shaft portion, or inserting a core into the hole of the semi-finished valve body of the hollow engine valve The hollow engine valve is manufactured by a spinning process in which a semifinished product of the hollow engine valve body and the core are axially rotated together and a spinning die is pressed against an outer peripheral part of the shaft part. Method.
In the sealing step, the hollow engine valve is obtained by pressing the large diameter portion and sealing the tip of the shaft portion.
It is a manufacturing method of the hollow engine valve according to claim 7,
A die that presses the diameter-enlarged portion and the shaft portion of the valve head portion forming portion of the valve body semi-finished product of the hollow engine valve after performing the rotational plastic working on the valve engine semi-finished product of the hollow engine valve. The outer diameter and the inner diameter of the shaft portion are reduced by performing necking processing in which the inner diameter of the die hole is gradually reduced by the number of the drawing-up steps, each time the die is gradually reduced. A method for producing a hollow engine valve, further comprising a second necking step for diameter.
A method for producing a hollow engine valve according to claim 7,
JP2011062198A 2011-03-22 2011-03-22 Method for manufacturing hollow engine valve Active JP4929408B1 (en)
JP2011062198A JP4929408B1 (en) 2011-03-22 2011-03-22 Method for manufacturing hollow engine valve
CN201280009242.6A CN103403305B (en) 2011-03-22 2012-02-17 The manufacture method of hollow engine valve
EP12760300.9A EP2690262B1 (en) 2011-03-22 2012-02-17 Method for manufacturing hollow engine valve
PCT/JP2012/053751 WO2012127947A1 (en) 2011-03-22 2012-02-17 Method for manufacturing hollow engine valve
US14/001,994 US9302317B2 (en) 2011-03-22 2012-02-17 Method for manufacturing hollow engine valve
KR20137022997A KR101512919B1 (en) 2011-03-22 2012-02-17 Method for manufacturing hollow engine valve
JP4929408B1 true JP4929408B1 (en) 2012-05-09
JP2012197718A JP2012197718A (en) 2012-10-18
ID=46261531
JP2011062198A Active JP4929408B1 (en) 2011-03-22 2011-03-22 Method for manufacturing hollow engine valve
US (1) US9302317B2 (en)
EP (1) EP2690262B1 (en)
JP (1) JP4929408B1 (en)
CN (1) CN103403305B (en)
WO (1) WO2012127947A1 (en)
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2011-03-22 JP JP2011062198A patent/JP4929408B1/en active Active
2012-02-17 EP EP12760300.9A patent/EP2690262B1/en active Active
2012-02-17 US US14/001,994 patent/US9302317B2/en active Active
2012-02-17 WO PCT/JP2012/053751 patent/WO2012127947A1/en active Application Filing
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