The present invention relates to a method of manufacturing an axisymmetric body including a flange portion and a method of manufacturing an axisymmetric product from the axisymmetric body obtained by the above manufacturing method.
An axisymmetric body including a flange portion is manufactured by, for example, casting or cutting of a columnar or thick cylindrical raw material. However, the casting requires high cost for manufacturing a mold, and the cutting wastes a large amount of materials.
Therefore, it is desired that a flange portion be formed later at a base metal. For example, it can be thought that a ring-shaped plate is joined to a tubular base metal by full penetration welding. However, since the amount of heat input to the base metal in the welding is extremely large, a heat affected zone (HAZ) in the base metal becomes large.
Here, the heat affected zone in the base metal can be made extremely small by using laser metal deposition (LMD) disclosed in PTL 1, for example. The technology disclosed in PTL 1 presupposes that: the base metal has a flat plate shape; and a projection having a relatively narrow width that is not more than twice a bead generated by the laser metal deposition is formed. Thus, the technology disclosed in PTL 1 is not intended to form an annular flange portion used as a structural member. Further, a flange portion having a relatively wide width cannot be formed by the technology disclosed in PTL 1.
An object of the present invention is to provide a method of manufacturing an axisymmetric body including a flange portion having a relatively wide width by using laser metal deposition and a method of manufacturing an axisymmetric product from the axisymmetric body.
To achieve the above object, a method of manufacturing an axisymmetric body according to the present invention is a method of manufacturing an axisymmetric body including a flange portion, the method including the steps of: forming an annular first layer on a peripheral surface of a base metal by laser metal deposition, the first layer being including a plurality of beads and having a width that is not less than twice a width of the bead, the peripheral surface facing outward or inward in a radial direction; and stacking a plurality of annular height raising layers on the first layer by the laser metal deposition, the height raising layers each being including a plurality of beads.
According to the above configuration, the axisymmetric body including the flange portion having a relatively wide width can be manufactured while making a heat affected zone in the base metal extremely small.
The first layer may be formed in such a manner that the beads extending in a circumferential direction of the base metal are lined up in an axial direction of the base metal, and each of the plurality of height raising layers may be formed in such a manner that the beads extending in the circumferential direction of the base metal are lined up in the axial direction of the base metal. Each of the first layer and the height raising layers can also be formed in such a manner that short beads extending in the axial direction of the base metal are lined up in the circumferential direction of the base metal by moving a nozzle, which emits a laser beam, zigzag relative to the peripheral surface of the base metal. However, in this case, a time from when one bead is formed until when a new bead is adjacently formed is extremely short. Therefore, the amount of heat accumulated in the base metal may become large, and the distortion of the base metal may become large. Further, the amount of heat accumulated in the base metal that is a base of the axisymmetric body and is continuous in the circumferential direction becomes large, and the distortion of the base metal becomes significant. In contrast, in a case where the beads extending in the circumferential direction of the base metal are lined up in the axial direction of the base metal as in the above configuration, a time from when one bead is formed until when a new bead is adjacently formed becomes extremely long. Therefore, the amount of heat accumulated in the base metal is decreased, and the distortion of the base metal can be made small.
The first layer may be formed while cooling the base metal, and each of the plurality of height raising layers may be formed while cooling the base metal. According to this configuration, oxidation of elements in a fusion zone of the base metal and the supply metal (wire or metal powder) can be suppressed. Especially, when the base metal is made of a titanium alloy, and the fusion zone is high in temperature, the fusion zone tends to have porosity because of oxidization of the titanium. Therefore, this configuration is useful especially when the base metal is made of the titanium alloy.
Each of the plurality of height raising layers may be formed under a condition different from a condition under which the first layer is formed. States (depressions and projections, temperature, etc.) of an immediately-before formed layer (the first layer or the height raising layer formed previously) that is a layer formed immediately before one height raising layer are different from states of the peripheral surface of the base metal on which the first layer is formed. Therefore, when the condition under which the first layer is formed and the condition under which each of the height raising layers is formed are made different from each other, quality of all the first layers and the height raising layers can be made uniform.
For example, the base metal may be made of a titanium alloy.
Metal powder may be used in the laser metal deposition. In the LMD, a wire can also be used as the supply metal. However, by using the metal powder as in this configuration, advantages are that, for example, a generation speed of the beads and the shape of the bead can be controlled easily.
The base metal may include a tapered body portion and an annular wall projecting inward from a large-diameter end of the body portion, and the first layer may be formed at an intermediate position of the body portion and on an inner peripheral surface of the base metal. According to this configuration, a shape that is difficult to manufacture by casting using a mold can be realized.
Further, a method of manufacturing an axisymmetric product from the axisymmetric body obtained by the above method according to the present invention includes the step of cutting the axisymmetric body by machine work. According to this configuration, a highly accurate axisymmetric product can be manufactured at low cost.
The present invention can manufacture the axisymmetric body including the flange portion having a relatively wide width by using the laser metal deposition.
PTL 1: Japanese Laid-Open Patent Application Publication No. 2007-301980
A method of manufacturing an axisymmetric body according to one embodiment of the present invention is a method of manufacturing an axisymmetric body 1 having a shape that is symmetrical around a central axis 10 as shown in
However, the shape of the axisymmetric body 1 is not limited to the shape shown in
According to the manufacturing method of the present embodiment, the first flange portions 14 are formed later at the base metal 2 by the LMD. In the present embodiment, metal powder is used as supply metal for the LMD. However, a wire may be used instead of the metal powder. Specifically, as shown in
The base metal 2 has a shape obtained by removing the first flange portions 14 from the axisymmetric body 1. More specifically, the base metal 2 includes: a disk-shaped wall 23 that defines the ceiling wall 11 of the axisymmetric body 1; a tapered body portion 21 that defines the peripheral wall 12 of the axisymmetric body 1; and an annular wall 22 that defines the second flange portion 13 of the axisymmetric body 1 and projects inward from a large-diameter end of the body portion 21. The base metal 2 can be produced in such a manner that, for example, a disk-shaped plate is formed in a tapered shape by spinning forming, and a tip end portion of the tapered shape is then pushed inward in the radial direction.
A material constituting the base metal 2 is not especially limited but is, for example, a titanium alloy. The metal powder may have the same composition as the base metal or may have a different composition from the base metal. For example, when the base metal 2 is made of the titanium alloy, the metal powder may be a titanium alloy different from the base metal 2 or may be an alloy other than the titanium alloy.
As shown in
The first layer 31 includes a plurality of beads 35 and has a width W (axial width of the base metal 2) that is not less than twice the width of the bead 35. In the present embodiment, the first layer 31 is formed in such a manner that the beads 35 extending in the circumferential direction of the base metal 2 are lined up in the axial direction of the base metal 2. For example, the beads 35 may be formed in a path order shown in
Referring back to
However, as shown in
It is desirable that the first layer 31 and each of the height raising layers 32 be formed while cooling the base metal 2. This is to maintain the temperature of the base metal 2 within a certain range R as shown in
For example, when the fan 6 is used as shown in
By forming the first layer 31 and each of the height raising layers 32 while cooling the base metal 2, oxidation of elements in a fusion zone of the base metal 2 and the metal powder can be suppressed. Especially, when the base metal 2 is made of a titanium alloy, and the fusion zone is high in temperature, the fusion zone tends to have porosity because of oxidization of the titanium. Therefore, the cooling of the base metal 2 is useful especially when the base metal 2 is made of the titanium alloy.
It is desirable that each of the height raising layers 32 be formed under a condition different from a condition under which the first layer 31 is formed. States (depressions and projections, temperature, etc.) of an immediately-before formed layer (the first layer 31 or the height raising layer 32 formed previously) that is a layer formed immediately before one height raising layer 32 are different from states of the inner peripheral surface 2a of the base metal 2 on which the first layer 31 is formed. Therefore, when the condition under which the first layer 31 is formed and the condition under which each of the height raising layers 32 is formed are made different from each other, quality of all the first layers 31 and the height raising layers 32 can be made uniform.
For example, when depressions and projections on the first layer 31 are large, and each of the height raising layers 32 is formed, heat energy input to the immediately-before formed layer is increased (for example, the output of the laser beam is increased), and this increases the amount of penetration. Or, for example, when the amount of heat accumulated in the base metal 2 is large, and each of the height raising layers 32 is formed, the heat energy input to the immediately-before formed layer is decreased (for example, the output of the laser beam is decreased), and this decreases the amount of penetration.
When stacking the height raising layers 32, it is desirable that: the shape of the first flange portion 14 in the middle of the forming be monitored by a camera or the like; and when the shape of the first flange portion 14 is different from an ideal shape, the position of the nozzle 4 be corrected.
The above-explained manufacturing method of the present embodiment can manufacture the axisymmetric body 1 including the first flange portion 14 having a relatively wide width while making the heat affected zone in the base metal 2 extremely small.
As explained above in reference to
Further, in the present embodiment, the metal powder is used as the supply metal for the LMD. Therefore, advantages are that, for example, a generation speed of the beads 35 and 36 and the shape of the bead can be controlled more easily than when the wire is used.
By using the base metal 2 including a radially retreating portion covered with the body portion 21 and the annular wall 22 at both axial sides, a shape which is difficult to manufacture by casting using a mold can be realized.
The axisymmetric body 1 obtained by the manufacturing method of the present embodiment may be used as a product. However, as shown in
The present invention is not limited to the above embodiment, and various modifications may be made within the scope of the present invention.
The present invention is widely applicable to the manufacture of the axisymmetric body used in various applications.
1 axisymmetric body
14 first flange portion
2 base metal
2
a inner peripheral surface
2
b outer peripheral surface
21 body portion
22 annular wall
31 first layer
32 height raising layer
35, 36 bead
42 metal powder
5 axisymmetric product
Number | Date | Country | Kind |
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2014-124105 | Jun 2014 | JP | national |
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PCT/JP2015/002813 | 6/3/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/194113 | 12/23/2015 | WO | A |
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