JP2010279958A - Method of manufacturing sealed container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of manufacturing a sealed container, wherein joining strength and sealing performance of a joined part are improved. <P>SOLUTION: In the method of manufacturing the sealed container by fixing a lid body 30 for sealing the opening to the opening of a cylindrical body 10 by means of friction stir welding, on the outer periphery of the lid body 30, an abutting face 31 on the inner periphery of the cylindrical body 10 is formed downward inside from the outer periphery of the lid body 30, with a recessed groove 32 formed in the abutting face 31, and the abutting face 31 of the lid body 30 is abutted on the inner periphery of the cylindrical body 10 and, in a state where the difference-in-level side surface 33 of the lid body 30 is butted against the opening end surface 13 of the cylindrical body 10, a rotating tool 50 is made to go around along the butted part 2 of the difference-in-level side surface 33 and the opening end surface 13, and while a plasticized region 3 is formed in the butted part 2, plastically fluidized metal is made to flow in the recessed groove 32, so that the lid body 30 is fixed to the cylindrical body 10. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a method for manufacturing a sealed container.

  As electronic devices such as mobile devices such as mobile phones and notebook personal computers and AV devices become smaller and lighter, there is an increasing demand for reducing the size and weight of batteries used as power sources. .

  Thin batteries include lithium ion secondary batteries, nickel cadmium batteries, nickel metal hydride batteries, etc. These battery casings are formed by sealing and fixing a lid to the opening of a bottomed cylindrical body. Yes. Previously, laser welding was used to fix the lid to the cylinder. However, it is difficult to secure a sufficient sealing degree because it is easy to cause poor penetration and root cracks in the welded part. There was a problem that the electrolyte solution was adversely affected by heat.

  Therefore, in recent years, the cylinder and the lid are sometimes fixed by friction stir welding (see, for example, Patent Document 1). Friction Stir Welding (FSW = Friction Stir Welding) is a method of joining metal members together, moving the rotary tool along the abutting part between the metal members while rotating the rotary tool, and generating frictional heat between the rotary tool and the metal member. Thus, a plasticized region is formed by plastic flow of the metal at the abutting portion, and the metal members are solid-phase bonded.

Japanese Patent No. 3,719,496

  However, since batteries in recent years have been miniaturized, the thickness of the cylinder and the lid is thin, and only a small rotating tool can be used. For this reason, the plasticized region to be formed is small, and there may be a case where sufficient bonding strength between the cylinder and the lid cannot be obtained. Furthermore, since the battery is often provided in precision electronic equipment such as a personal computer, it is required to improve the sealing performance at the joint between the cylinder and the lid in order to further improve the reliability.

  Then, this invention makes it a subject to provide the manufacturing method of the airtight container which can improve the joint strength and sealing performance of a junction part.

  As means for solving the above-mentioned problems, the present invention provides a closed container manufacturing method in which a lid for sealing the opening is fixed to the opening of a cylinder by friction stir welding. A contact surface with the inner peripheral surface of the cylindrical body is formed on the outer peripheral surface of the body so as to drop inward from the outer peripheral surface of the lid body, and a concave groove is formed on the contact surface. Rotate along the abutting portion between the step side surface and the opening end surface in a state where the contact surface is in contact with the inner peripheral surface of the cylinder body and the step side surface of the lid body and the opening end surface of the cylinder body abut each other A closed vessel characterized in that the tool is rotated around, and a plasticized region is formed in the abutting portion, while plastic fluidized metal is allowed to flow into the concave groove to fix the lid body to the cylindrical body. It is a manufacturing method.

  According to such a method, the plastic fluidized metal flows into the concave groove formed on the abutting surface, so that the metal in the plasticized region becomes a ridge that engages with the lid. The forming region and the lid mesh with each other. Accordingly, the bonding strength between the cylinder and the lid can be increased, and the sealing performance at the bonded portion can be improved, and the reliability of the sealed container is increased.

  And this invention is characterized by the said recessed groove being formed near the said level | step difference side surface of the said contact surface.

  According to such a method, since the abutting portion and the concave groove are close to each other, the plastic fluidized metal easily flows into the concave groove.

  Further, the present invention is characterized in that the cylindrical body has a bottomed cylindrical shape with one opening.

  According to such a method, it is only necessary to fix the lid to only one of the cylinders, and it is possible to reduce the time and labor of joining work and to further improve the sealing performance.

  Furthermore, the present invention is characterized in that the outer peripheral surface of the lid and the outer peripheral surface of the cylindrical body are flush with each other in a state where the step side surface of the lid and the opening end surface of the cylindrical body are abutted. And

  According to such a method, since the surface into which the rotary tool is inserted is a flat surface, the rotary tool can be easily inserted.

  Further, the present invention is characterized in that the outer peripheral surface of the cylindrical body is located on the outer side of the outer peripheral surface of the lid body in a state where the step side surface of the lid body and the opening end surface of the cylindrical body face each other. And

  According to such a method, since the thickness at the position above the groove is increased, the amount of metal flowing into the groove can be ensured.

  Furthermore, the present invention is characterized in that after the rotating tool makes one turn along the abutting portion, the rotating tool is moved along the starting end portion of the first turn to overlap a part of the plasticizing region. And

  According to such a method, since a part of the plasticized region is overlapped, the cylindrical body and the lid can be favorably joined without a gap, so that the sealing performance of the joint is further improved. Can do.

  In the present invention, the length dimension of the stirring pin of the rotary tool is equal to or smaller than the thickness dimension of the cylindrical portion of the cylindrical body.

  According to such a method, since the stirring pin does not enter the concave groove, deformation of the peripheral portion of the concave groove can be suppressed. As a result, the contact area between the metal and the inner wall surface of the groove is increased, so that the engagement between the plasticized region and the lid can be improved.

  Furthermore, the present invention is characterized in that a shoulder diameter dimension of the rotary tool is larger than a width dimension of the concave groove.

  According to such a method, since the upper part of the concave groove can be covered with the shoulder portion of the rotary tool, the entire upper part of the concave groove becomes a plasticized region, and the plastic fluidized metal easily flows into the concave groove. .

  Further, in the present invention, after rotating the rotating tool once, the rotating tool is shifted to the lid body side so that the stirring pin of the rotating tool moves on the outer peripheral surface of the lid body. The tool is further rotated along the abutting portion.

  According to such a method, even if a cavity defect occurs in the plasticized region in the first round, it is possible to reduce the cavity defect by stirring by movement in the second round, and in the unlikely event, plasticization occurs in the second round. Even if a cavity defect occurs in the region, it occurs in a portion separated from the abutting portion on the outer peripheral surface of the lid, so that the sealing performance of the joint portion is not deteriorated.

  Further, according to the present invention, a plasticizing region formed in the second turn of the rotating tool and a plasticizing region formed in the first turn of the rotating tool are part of the width direction over the entire periphery. The rotation tool is moved so as to overlap each other.

  According to such a method, since a part in the width direction of each plasticized region overlaps, the cylindrical body and the lid body can be favorably joined. Can be improved.

  In the present invention, when the lid is located on the left side facing the traveling direction from the rotating tool, the rotating tool is rotated to the right, and the lid is located on the right side facing the traveling direction from the rotating tool. When rotating, the rotation tool is rotated to the left.

  According to such a method, the shear side of the rotary tool is positioned on the thick lid side. For this reason, even if a cavity defect occurs, it will occur on the lid side and on the outer side of the abutting part (shear side), and the internal contents will be difficult to leak to the outside. The sealing performance is not degraded.

  Furthermore, prior to the step of forming the plasticized region with the rotary tool, a part of the abutting portion is temporarily joined using a temporary joining rotary tool smaller than the rotary tool.

  According to such a method, by temporarily joining the cylinder and the lid, the lid does not move with respect to the cylinder during the main joining, and the main body is easily joined. The positioning accuracy is improved. In addition, since the rotary tool for temporary welding is smaller than the rotary tool for main welding, the rotary tool for temporary bonding is formed by the rotary tool for temporary welding simply by moving the rotary tool for main welding over the temporary bonding portion and stirring the friction. Since the plasticized region does not protrude after being re-stirred, the main joining is finished.

  Further, the present invention provides an inner peripheral portion of the opening end surface of the cylindrical body in a method for manufacturing a sealed container configured by fixing a lid body that seals the opening to the opening of the cylindrical body by friction stir welding. The support surface of the lid is formed to be lowered from the opening end surface, a concave groove is formed in the support surface, the lid is placed on the support surface, and the step side surface of the cylindrical body and the In a state where the outer peripheral surface of the lid is abutted, the rotating tool makes one turn along the abutting portion between the step side surface and the outer peripheral surface of the lid, and the concave groove is formed while forming a plasticized region in the abutting portion. A method of manufacturing a hermetically sealed container is characterized in that a plastic fluidized metal is allowed to flow into and the lid is fixed to the cylinder.

  In this method, the above-described invention forms a concave groove in the lid, whereas in the present invention, the concave groove is formed in the cylindrical body. Also by such a method, the plastic fluidized metal flows into the concave groove formed in the opening end face, so that the metal in the plasticized region becomes a ridge that engages with the cylindrical body. And the cylinder mesh with each other. Accordingly, the bonding strength between the cylinder and the lid can be increased, and the sealing performance at the bonded portion can be improved, and the reliability of the sealed container is increased.

  Furthermore, the present invention is characterized in that the concave groove is formed in an outer peripheral portion of the support surface.

  According to such a method, since the abutting portion and the concave groove are close to each other, the plastic fluidized metal easily flows into the concave groove.

  Further, the present invention is characterized in that the opening end surface of the cylindrical body and the surface of the lid body are flush with each other in a state where the step side surface of the cylindrical body and the outer peripheral surface of the lid body are abutted. To do.

  According to such a method, since the surface into which the rotary tool is inserted is a flat surface, the rotary tool can be easily inserted.

  Furthermore, the present invention is characterized in that the lid projects from the opening end surface of the cylindrical body in a state where the step side surface of the cylindrical body and the outer peripheral surface of the lid are abutted.

  According to such a method, since the thickness at the position above the groove is increased, the amount of metal flowing into the groove can be ensured.

  Further, in the present invention, after rotating the rotating tool once, the rotating tool is shifted to the cylindrical body side so that the stirring pin of the rotating tool moves on the opening end surface of the cylindrical body. The rotating tool is further rotated along the abutting portion.

  According to such a method, even if a cavity defect occurs in the plasticized region in the first round, it is possible to reduce the cavity defect by stirring by movement in the second round, and in the unlikely event, plasticization occurs in the second round. Even if a cavity defect occurs in the region, it occurs in a portion separated from the abutting portion on the outer peripheral surface of the lid, so that the sealing performance of the joint portion is not deteriorated.

  Further, in the present invention, when the lid is positioned on the right side facing the traveling direction from the rotating tool, the rotating tool is rotated to the right, and the lid is positioned on the left side facing the traveling direction from the rotating tool. When rotating, the rotation tool is rotated to the left.

  According to such a method, the shear side of the rotary tool is located on the thick cylindrical body side. For this reason, even if a cavity defect occurs, it will occur on the cylindrical body side and at a position away from the abutting part (shear side), and the internal contents are less likely to leak to the outside. The sealing performance is not degraded.

  Further, the present invention is characterized in that, prior to the step of forming the plasticized region with the rotary tool, a part of the abutting portion is temporarily joined using a rotary tool for temporary joining smaller than the rotary tool. And

  According to such a method, by temporarily joining the cylinder and the lid, the lid does not move with respect to the cylinder during the main joining, and the main body is easily joined. The positioning accuracy is improved. In addition, since the rotary tool for temporary welding is smaller than the rotary tool for main welding, the rotary tool for temporary bonding is formed by the rotary tool for temporary welding simply by moving the rotary tool for main welding over the temporary bonding portion and stirring the friction. Since the plasticized region does not protrude after being re-stirred, the main joining is finished.

  Further, according to the present invention, the abutting portion has a rectangular frame shape, and in the step of temporarily joining the abutting portion with the temporary joining rotary tool, one diagonal of the abutting portion is temporarily joined first. Later, the other diagonals are temporarily joined together.

  According to such a method, the lid body can be temporarily joined with good balance, and the positioning accuracy of the lid body with respect to the cylinder body is improved.

  Further, according to the present invention, the abutting portion has a rectangular frame shape, and in the step of temporarily joining the abutting portion with the temporary joining rotary tool, an intermediate portion of one opposite side of the abutting portion is temporarily placed. After joining, the intermediate part of the other opposite side is temporarily joined.

  According to such a method, the lid body can be temporarily joined with good balance, and the positioning accuracy of the lid body with respect to the cylinder body is improved. Furthermore, since temporary joining is performed linearly, processing becomes easy.

  According to this invention, the outstanding effect that the joint strength and sealing performance of the junction part of a cylinder and a cover body can be improved is exhibited.

It is the disassembled perspective view which showed the airtight container which concerns on 1st Embodiment. It is the partial cross section side view which showed the state before the friction stir welding of the airtight container which concerns on 1st Embodiment. (A)-(d) is the top view which showed the friction stir welding process of the manufacturing method of the airtight container which concerns on 1st Embodiment. (A)-(c) is sectional drawing which showed the friction stir welding process of the manufacturing method of the airtight container which concerns on 1st Embodiment. It is the perspective view which showed the temporary joining process of the manufacturing method of the airtight container which concerns on 1st Embodiment. (A)-(c) is sectional drawing which showed the friction stir welding process of the 1st modification of the manufacturing method of the airtight container which concerns on 1st Embodiment. It is sectional drawing which showed the friction stir welding process of the 2nd modification of the manufacturing method of the airtight container which concerns on 1st Embodiment. It is the disassembled perspective view which showed the airtight container which concerns on 2nd Embodiment. (A), (b) is the top view which showed the friction stir welding process of the manufacturing method of the airtight container which concerns on 2nd Embodiment. (A), (b) is the top view which showed the friction stir welding process of the manufacturing method of the airtight container which concerns on 2nd Embodiment. (A)-(c) is sectional drawing which showed the friction stir welding process of the manufacturing method of the airtight container which concerns on 2nd Embodiment. (A) is the top view which showed the temporary joining process of the manufacturing method of the airtight container which concerns on 2nd Embodiment, (b) is the top view which showed the subsequent main joining process. (A) is the top view which showed the temporary joining process of the manufacturing method of the airtight container which concerns on 2nd Embodiment, (b) is the top view which showed the subsequent main joining process. (A)-(c) is sectional drawing which showed the friction stir welding process of the modification of the manufacturing method of the airtight container which concerns on 2nd Embodiment.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings as appropriate. First, the sealed container formed by the closed container manufacturing method according to the first embodiment will be described. The hermetic container is a component used as a case of a thin battery used as a power source for mobile devices such as mobile phones and notebook personal computers and electronic devices such as AV devices.

  As shown in FIGS. 1 and 2, in the sealed container 1 (see FIG. 3D), a lid 30 that seals the opening 11 is fixed to the opening 11 of the cylindrical body 10 by friction stir welding. (See FIG. 3). In the first embodiment, an abutment surface 31 is formed on the outer peripheral surface of the lid body 30, which is composed of a stepped bottom surface that is lowered inward from the surface, and abuts against the inner peripheral surface 12 of the cylindrical body 10. A concave groove 32 is formed in the. The contact surface 31 of the lid body 30 is inserted into the cylindrical body 10 and is in contact with the inner peripheral surface 12 of the cylindrical body 10. At this time, the stepped side surface 33 of the lid 30 and the opening end surface 13 of the cylinder 10 are abutted to form the abutting portion 2. By rotating the rotary tool 50 (see FIGS. 4B and 4C) along the abutting portion 2, friction stir welding is performed, and the plasticizing region 3 (see FIG. 3) is formed in the abutting portion 2. Is formed. At the time of this friction stir welding, the plastic fluidized metal flows into the groove 32, and a part of the plasticized region 3 is located in the groove 32 (FIGS. 4B and 4C). )reference). As a result, the metal in the plasticized region 3 becomes a protrusion that engages with the lid 30, so that the plasticized region 3 and the lid 30 mesh with each other.

  The cylindrical body 10 according to the present embodiment has a bottomed cylindrical shape with one open and the other closed, and the lid 30 is fixed to only one axial direction (opening 11) of the cylindrical body 10. ing. The cylinder 10 has a cylindrical shape. The cylinder 10 is produced by die casting, casting, forging, or the like, for example. The cylinder 10 is formed from aluminum or an aluminum alloy. Thereby, the airtight container 1 has achieved weight reduction and is easy to handle.

  Corresponding to the cylindrical body 10 having a bottomed cylindrical shape, the lid body 30 has a disk shape having a large diameter portion 34 and a small diameter portion 35. The large diameter portion 34 and the small diameter portion 35 of the lid 30 are formed concentrically. As shown in FIG. 2, the small diameter portion 35 is inserted into the cylindrical body 10. The small diameter portion 35 has an outer peripheral diameter equivalent to the inner peripheral diameter of the cylindrical body 10, and constitutes a contact surface 31 in which the outer peripheral surface of the small diameter portion 35 contacts the inner peripheral surface 12 of the cylindrical body 10. . The concave groove 32 is formed to descend from the outer peripheral surface of the small diameter portion 35 by a predetermined depth. As shown in FIG. 4A, the groove 32 is formed near the step side surface 33 of the contact surface 31. Specifically, the concave groove 32 is formed in a ring shape along the contact surface 31 and has a rectangular cross section. The side surface 32 a on the large diameter portion 34 side of the concave groove 32 is flush with the step side surface 33, and the concave groove 32 is adjacent to the step side surface 33. The concave groove 32 has a width dimension W1 set smaller than a shoulder diameter (diameter of the shoulder portion 51) dimension R1 of the rotary tool 50 used for friction stir welding (the shoulder diameter dimension R1 of the rotary tool 50 is It is larger than the width dimension W1 of the concave groove 32). In particular, in this embodiment, half (radius dimension) of the shoulder diameter dimension R1 is larger than the width dimension W1 of the concave groove 32. Further, the width dimension W1 of the groove 32 is about 1/4 of the axial length dimension (length from the step side surface 33 to the tip of the small diameter portion 35) W2. The concave groove 32 preferably has a smaller volume considering the amount of metal movement. That is, if the volume of the concave groove 32 is small, the amount of metal movement inflow is reduced, so that the occurrence of cavity defects can be suppressed. In the drawing, the concave grooves 32 are drawn larger for the sake of clarity, but may be formed smaller in the implementation stage.

  As shown in FIG. 2 and FIG. 4A, the large diameter portion 34 has an outer diameter equal to the outer diameter of the cylindrical body 10, and the stepped side surface 33 of the lid 30 and the opening of the cylindrical body 10. The outer peripheral surface of the lid body 30 (the outer peripheral surface of the large-diameter portion 34) and the outer peripheral surface of the cylindrical body 10 are configured to be flush with each other with the end surfaces 13 in contact with each other. In other words, the thickness dimension T1 of the cylindrical body 10 is equal to the step dimension H1 between the contact surface 31 (the outer peripheral surface of the small diameter portion 35) of the lid body 30 and the outer peripheral surface of the large diameter portion 34 (see FIG. a)).

  The lid 30 is also made of aluminum or an aluminum alloy, like the cylinder 10. Thereby, the airtight container 1 has achieved weight reduction and is easy to handle. The lid body 30 is produced by forming a small diameter portion 35 and a concave groove 32 by cutting a block formed of aluminum or an aluminum alloy. Note that the manufacturing method is not limited to this, and it may be manufactured by die casting, casting, forging, or the like.

  Next, the manufacturing method of the airtight container 1 is demonstrated centering on the process of fixing the cover body 30 to the cylinder 10 by friction stir welding.

  First, as shown in FIG. 2, the lid body 30 is moved toward the cylinder body 10, and the small diameter portion 35 is inserted into the inside of the opening section 11 (see FIG. 1) of the cylinder body 10. Then, the stepped side surface 33 of the lid body 30 and the opening end surface 13 of the cylindrical body 10 are abutted to form the abutting portion 2. At this time, the concave groove 32 formed in the contact surface 31 is covered by the inner peripheral surface 12 of the cylindrical body 10, and a rectangular space is defined.

  Next, the rotary tool 50 for friction stir welding is moved along the abutting portion 2. The rotary tool 50 is made of a metal material harder than the cylindrical body 10 and the lid body 30, and as shown in FIGS. 4B and 4C, a shoulder portion 51 having a cylindrical shape, It comprises a stirring pin (probe) 52 that protrudes from the lower end surface. What is necessary is just to set the dimension and shape of the rotary tool 50 according to the material, thickness, etc. of the cylinder 10 and the cover body 30. FIG. In this embodiment, the stirring pin 52 has a truncated cone shape with a reduced diameter at the lower portion, and the protruding length dimension L1 is equal to or less than the thickness dimension T1 of the cylindrical body 10. Further, the shoulder diameter dimension R1 of the rotary tool 50 is larger than the width dimension W1 of the concave groove 32. At the time of friction stir welding, the rotary tool 50 is pushed so that the tip of the stirring pin 52 is located at substantially the same height as the surface of the contact surface 31 or is located above the surface. Further, the amount of pressing of the rotary tool 50 is determined according to the volume of the concave groove 32, and is set so that the metal plastically fluidized by friction stirring flows into the entire concave groove 32. The rotational speed of the rotary tool 50 is 500 to 15000 (rpm), the feed rate is 0.05 to 2 (m / min), and the pushing force for pressing the abutting portion 2 is about 1 to 20 (kN). The lid 30 is appropriately selected according to the material, plate thickness, and shape.

  Hereinafter, the movement of the rotary tool 50 will be specifically described. As shown in FIG. 3A, first, the rotary tool 50 is inserted into the insertion position 53 while being rotated. The insertion position 53 of the rotary tool 50 is on the outer peripheral surface of the large-diameter portion 34 that is disengaged from the abutting portion 2 toward the large-diameter portion 34 side of the lid 30. A pilot hole (not shown) may be formed in advance at the insertion position 53 of the rotary tool 50. If it does in this way, the insertion time (pressing time) of the rotation tool 50 can be shortened.

  Thereafter, the rotary tool 50 is moved while rotating from the insertion position 53 to a position directly above the abutting portion 2 (a position where the center of the rotating tool 50 is on the abutting portion 2). Thereafter, the rotation tool 50 is moved along the abutting portion 2 by changing the moving direction of the rotating tool 50 so that the center (axial center) of the rotating tool 50 moves on the abutting portion 2. At this time, the cylindrical body 10 and the lid body 30 around the abutting portion 2 are integrally plastically fluidized to become the plasticized region 3. Here, the “plasticization region” includes both a state in which the rotary tool 50 is heated by frictional heat and is actually plasticized, and a state in which the rotary tool 50 passes and returns to room temperature. A part of the metal of the cylindrical body 10 and the lid body 30 plastically fluidized by the rotary tool 50 flows into the concave groove 32 (see FIG. 4B). And the metal which flowed in into the ditch | groove 32 returns to normal temperature after the rotation tool 50 passes, and is hardened.

  At this time, the shear side 50b (see the arrow Y2 in FIG. 3) in which the rotary tool 50 rotates (see the arrow Y2 in FIG. 3) in the same direction as the moving direction of the rotary tool 50 (see the arrow Y1 in FIG. 3). The large-diameter portion 34 of the lid 30 is thicker in the axial direction of the rotary tool 50) where the relative peripheral speed is a value obtained by adding the magnitude of the moving speed to the magnitude of the tangential speed at the outer circumference of the rotary tool 50). The rotation tool 50 is rotated and moved so as to be positioned above. That is, when the lid 30 (the large-diameter portion 34 exposed to the outside of the lid 30) is located on the right side facing the traveling direction from the rotary tool 50 as in the present embodiment, the rotary tool 50 is rotated counterclockwise. Let When the lid 30 (the large-diameter portion 34 exposed to the outside of the lid 30) is located on the left side in the traveling direction from the rotary tool 50, the rotary tool 50 is rotated to the right. By doing so, the shear side 50b of the rotary tool 50 is positioned on the thick lid 30 side. The axially thin cylindrical body 10 side of the rotary tool 50 has a flow side 50a of the rotary tool 50 (the relative speed of the outer periphery of the rotary tool 50 with respect to the joined portion is the magnitude of the tangential velocity at the outer periphery of the rotary tool 50. The value obtained by subtracting the magnitude of the moving speed from the above). For this reason, on the cylinder 10 side, the stirring temperature is low, the amount of metal flow is small, and the amount of burrs is small, so that cavity defects are less likely to occur. And even if a cavity defect occurs due to frictional stirring, it will occur not on the thin cylindrical body 10 side, but on the lid body 30 side and at a position away from the abutting part 2 and in the sealed container 1. This makes it difficult for the fluid to leak to the outside, so that the sealing performance of the joint is not deteriorated.

  Subsequently, the rotation and movement of the rotary tool 50 are continued, and as shown in FIG. 3B, the rotary tool 50 is caused to make one turn along the abutting portion 2 to form the plasticized region 3. After rotating the rotary tool 50 once, the rotary tool along the start end including the start end 54a of the first turn (a portion from the start end 54a to a position advanced by a predetermined length in the moving direction of the rotary tool 50 (the same position as the end end 54b)). 50 is moved by a predetermined length. Accordingly, the start end 54a and the end end 54b in the circumferential movement of the rotary tool 50 overlap each other, and a part of the plasticizing region 3 is configured to overlap.

  After that, as shown in FIG. 3C, the movement trajectory of the rotary tool 50 is shifted from the end 54b of the first round to the large diameter portion 34 side of the lid 30 and then the friction agitation of the second round is performed. . The rotary tool 50 is shifted by moving obliquely so as to move toward the large-diameter portion 34 side of the lid body 30 in the moving direction. The amount of deviation of the rotary tool 50 is such that the shoulder 51 (see FIG. 4B) of the rotary tool 50 is at least a part in the width direction of the plasticizing region 3 formed by the movement of the first round of the rotary tool 50. The shear side 50b of the plasticizing region 3 is re-stirred by frictional stirring on the second round of the rotary tool 50. Thereafter, the rotary tool 50 moves in parallel with the plasticizing region 3 along the abutting portion 2. When entering the second round of movement, the rotating tool 50 is not exchanged and remains inserted in the plasticized region 3, and the moving direction and the rotating direction are the same as in the first round ((c) and ( d) During this, the state of arrows Y1 and Y2) is continued, and the pushing amount is not changed. Note that the rotation speed, movement speed, and the like of the rotary tool 50 may be changed as appropriate according to the shape and material of the cylinder 10 and the lid 30. As a result, the second plasticizing region where the rotating tool 50 moves in the same direction as the first round and rotates in the same direction overlaps with a part in the width direction of the plasticizing zone 3 formed in the first round. 4 (see FIG. 3D) is formed.

  Then, as shown in FIG. 3D, when the second rotation of the rotary tool 50 is completed, the rotary tool 50 is detached from the second plasticizing region 4 toward the large diameter portion 34 of the lid 30. Then, the rotary tool 50 is pulled out to the pulling position 55 on the outer peripheral surface of the large-diameter portion 34. Since the drawing position 55 is a position deviated to the outside from the abutting portion 2, a drawing trace (not shown) is not formed in the abutting portion 2, and the joining property between the cylindrical body 10 and the lid body 30. Can be further enhanced. In addition, you may make it repair a drawing trace.

  As described above, the rotary tool 50 is rotated around the opening portion 11 of the cylindrical body 10 along the abutting portion 2 and friction stir welding is performed to form the plasticized region 3 and the second plasticized region 4. The airtight container is formed by fixing the lid body 30 to the cylindrical body 10.

  According to the manufacturing method of the hermetic container 1 according to the present embodiment, a part of the metal of the cylindrical body 10 and the lid body 30 plastically fluidized by the rotary tool 50 flows into the concave groove 32 and reaches room temperature. Since it returns and hardens, the metal that has flowed into the groove 32 becomes a protrusion that engages with the cylinder 10. As a result, the plasticized region 3 and the lid 30 are engaged with each other, and the engagement is enhanced. In particular, in the present embodiment, since the protrusions protrude from the plasticized region 3 in a direction orthogonal to the axial direction (drawing direction) of the lid 30, the engagement between the plasticized region 3 and the lid 30 is high. Therefore, the sealing performance at the joint between the cylinder 10 and the lid 30 can be improved, and the reliability of the sealed container 1 can be increased.

  Furthermore, since the metal that has flowed into the concave groove 32 constitutes a wall surface that hangs perpendicular to the contact surface 31, this wall surface serves as a weir, and the liquid at the junction between the cylinder 10 and the lid body 30. Denseness can be improved.

  Moreover, in this embodiment, since the ditch | groove 32 is formed near the level | step difference side surface 33 of the contact surface 31, the abutting part 2 and the ditch | groove 32 become near. As a result, the metal fluidized plastically by the frictional stirring of the first round by the rotary tool 50 moved on the abutting portion 2 is likely to flow into the concave groove 32. Furthermore, the shoulder diameter dimension R1 of the rotary tool 50 is larger than the width dimension W1 of the concave groove 32. In particular, in this embodiment, the radius of the shoulder portion 51 is larger than the width dimension W1 of the concave groove 32. The upper part of the groove 32 can be covered with the shoulder 51 of the rotary tool 50, and the entire upper part of the groove 32 becomes the plasticized region 3, and the plastic fluidized metal easily flows into the groove 32. Therefore, the plastic fluidized metal flows into the entire inside of the concave groove 32, and the sealing performance at the joint portion between the cylindrical body 10 and the lid body 30 can be improved.

  Furthermore, since the length dimension L1 of the stirring pin 52 of the rotary tool 50 is equal to or smaller than the thickness dimension T1 of the cylindrical body 10, the tip of the stirring pin 52 does not enter the concave groove 32. As a result, the deformation of the peripheral portion of the groove 32 can be suppressed, and the engagement area between the plastic fluidized metal and the inner wall surface of the groove 32 is increased. Therefore, the engagement between the plasticized region 3 and the lid 30 is increased. Can be improved.

  In addition, after rotating the rotary tool 50 along the abutting portion 2, the rotating tool 50 is moved along the starting end portion of the first round, and a part of the plasticizing region 3 is overlapped, so that the abutting portion 2 The plasticized region 3 is not interrupted around. Therefore, since the cylinder 10 and the lid body 30 are reliably bonded over the entire circumference of the abutting portion 2, the sealing performance of the bonded portion can be further improved.

  Further, in the present embodiment, when the lid 30 is positioned on the right side facing the traveling direction from the rotary tool 50, the rotary tool 50 is rotated counterclockwise, and the rotary tool 50 is rotated around the rotary tool 50. Shifting to the large diameter portion 34 side of the lid 30, and further rotating the rotary tool 50 along the abutting portion 2 so that the stirring pin 52 of the rotary tool 50 moves on the outer peripheral surface of the large diameter portion 34. Therefore, the portion near the large-diameter portion 34 of the plasticizing region 3 that becomes the shear side 50 b is re-stirred by the second movement of the rotary tool 50. Therefore, even if a cavity defect is generated near the large-diameter portion 34 of the plasticized region 3, the cavity defect can be reduced by the second round movement. Furthermore, since the shear side 50b in the second movement of the rotary tool 50 is a portion separated from the abutting portion 2 on the outer peripheral surface of the large diameter portion 34, even if a cavity defect occurs, the abutting portion 2 Occurs in the part away from. Therefore, the fluid accommodated inside is hard to leak to the outside, and the sealing performance of the joint portion is not deteriorated. Further, the plasticized region 3 and the second plasticized region 4 have a part in the width direction that overlaps the entire circumference of the abutting portion 2, so that the cylindrical body 10 and the lid body 30 are not spaced apart. Good bonding can be achieved. Therefore, the sealing performance of the joint can be further improved.

  Furthermore, since the lid body 30 includes the large diameter portion 34 and the small diameter portion 35, the axial length is increased and the rigidity is increased. Therefore, it is possible to prevent the lid body 30 from being deformed by the heat of the friction stir welding. Thereby, the abutting state of the opening end surface 13 of the cylindrical body 10 and the stepped side surface 33 of the lid body 30 becomes good, and the sealing performance of the joint portion can be further improved.

  In the above-described embodiment, the rotary tool 50 is rotated twice along the abutting portion 2 to perform frictional stirring. However, the present invention is not limited to this. Since a part of the plastic fluidized metal flows in, the movement of the rotary tool 50 may be completed in only one round. Further, friction stirring may be performed by rotating the rotary tool 50 three or more times.

  Next, in the method for manufacturing the sealed container 1 according to the first embodiment, prior to the step of forming the plasticized region 3 and the second plasticized region 4 with the rotary tool 50 and finally joining the lid 30 to the cylindrical body 10. The case where the lid 30 is temporarily joined to the cylinder 10 will be described.

  As shown in FIG. 5, the temporary joining is performed on a part of the abutting portion 2 between the cylindrical body 10 and the lid body 30 and using a temporary joining rotating tool (not shown) smaller than the rotating tool 50. Done. After the temporary bonding, the main bonding is performed using the rotary tool 50 as shown in FIG.

  The temporary joining rotary tool includes a shoulder portion and a stirring pin (not shown) having a diameter smaller than that of the rotary tool 50, and the plasticized region 5 (see FIG. 5) to be formed is the rotary tool 50 in a later step. It has a width smaller than the width of the plasticized region 3 (see FIG. 3) formed by. And the plasticization area | region 5 is formed in the position which does not protrude from the position where the plasticization area | region 3 is formed in a next process. As a result, the plasticizing region 5 in the temporary joining is completely covered with the plasticizing region 3, so that the trace of the drawing of the rotary tool for temporary joining remaining in the plasticizing region 5 and the trace of the plasticizing region 5 remain. Absent.

  In the present embodiment, the abutting portion 2 has a circular shape in a side view, and in the step of temporarily joining the abutting portion 2 with a temporary joining rotary tool, both end portions 6a and 6b having an arbitrary diameter S1 are temporarily joined first. Later, both ends 6c, 6d of the second diameter S2 orthogonal to the diameter are temporarily joined. By temporarily joining in such an order, the lid 30 can be temporarily joined to the cylinder 10 in a balanced manner, positioning accuracy of the lid 30 with respect to the cylinder 10 is improved, and deformation of the lid 30 is prevented. it can. Moreover, by performing temporary joining of the lid 30, it is possible to prevent the lid 30 from being displaced during the main joining by the rotary tool 50, and to further improve the sealing performance of the joint portion.

  Next, a first modification of the method for manufacturing the sealed container 1 according to the first embodiment will be described with reference to FIG. In the first embodiment, as shown in FIG. 4A, the outer peripheral surface (large diameter) of the lid body 30 with the stepped side surface 33 of the lid body 30 and the opening end surface 13 of the cylinder body 10 abutting each other. The outer peripheral surface of the portion 34 and the outer peripheral surface of the cylindrical body 10 are configured to be flush with each other, whereas the first modified example is a cylindrical body as shown in FIG. The outer peripheral surface of 10 'is located outside the outer peripheral surface of the lid body 30 (the outer peripheral surface of the large diameter portion 34). Specifically, the outer diameter of the cylinder 10 ′ is formed to be larger than the outer diameter of the large diameter portion 34 of the lid 30. In other words, the thickness T2 of the cylindrical body 10 ′ is formed to be larger than the step height H1 between the contact surface 31 (the outer peripheral surface of the small diameter portion 35) of the lid body 30 and the outer peripheral surface of the large diameter portion 34. ing.

  As shown in FIG. 6B, the thickness dimension T <b> 2 of the cylindrical body 10 ′ is appropriately set according to the volume of the concave groove 32 and the pushing amount of the rotary tool 50. Specifically, the thickness of the cylindrical body 10 ′ is such that the value obtained by subtracting the volume of the metal serving as a burr from the volume of the metal pushed by the shoulder portion 51 of the rotary tool 50 is substantially equal to the volume of the concave groove 32. The length T2 is determined.

  As described above, according to this modification in which the thickness dimension T2 of the cylinder 10 ′ is increased, the amount of metal of the cylinder 10 ′ that is plastically fluidized increases. The pushing amount can be reduced. Thereby, generation | occurrence | production of a burr | flash can be reduced and the material loss of cylinder 10 'and the cover body 30 can be reduced. Further, the lid 30 side is the shear side 50b of the rotary tool 50. However, since the pushing action of the shear side 50b is reduced, the stirring action of the metal is reduced, so that the occurrence of cavity defects can be suppressed. Furthermore, in this embodiment, as shown in FIG. 6C, the pushing amount in the second turn of the rotary tool 50 is also reduced, so that the material loss of the lid 30 can be further reduced.

  Next, a second modification of the method for manufacturing the sealed container 1 according to the first embodiment will be described with reference to FIG. In the first modification of the first embodiment, as shown in FIG. 6, the pressing direction of the rotary tool 50 is the depth direction of the abutting portion 2 (the opening end surface 13 of the cylindrical body 10 ′ and the step between the lid 30. In the second modified example, the pushing direction of the rotary tool 50 is inclined with respect to the depth direction of the abutting portion 2. As shown in (a) of FIG. 7, the rotary tool 50 is inclined so that the tip thereof is directed to the cylinder 10 ′ side with respect to the abutting portion 2, and the bottom surface of the shoulder portion 51 is the cylinder 10 ′. Are arranged along a slope connecting the outer peripheral surface of the cover 30 and the outer peripheral surface of the large-diameter portion 34 of the lid 30, and friction stir welding is performed. The inclination angle of the rotary tool 50 is preferably 5 degrees or less with respect to the vertical line.

  As described above, according to the present modification in which the pushing direction of the rotary tool 50 is inclined with respect to the abutting portion 2, the surface of the plasticized region 3 ′ formed by the friction stir welding is the outer periphery of the cylindrical body 10 ′. Is formed so as to connect the surface and the outer peripheral surface of the large-diameter portion 34 of the lid 30, so that a large step can be prevented from being formed at the joint between the cylinder 10 ′ and the lid 30, and a smooth surface is formed. can do.

(Second Embodiment)
Next, a second embodiment of the present invention will be described in detail with appropriate reference to the drawings. First, the sealed container formed by the closed container manufacturing method according to the second embodiment will be described. In the closed container manufacturing method of the first embodiment, the concave groove 32 is formed in the contact surface 31 of the lid body 30, whereas in the second embodiment, the concave groove 114 is formed in the cylindrical body 110. It is characterized by.

As shown in FIG. 8, the sealed container 101 is configured by fixing a lid 130 that seals the opening 111 to the opening 111 of the cylindrical body 110 by friction stir welding. In the second embodiment, a support surface 113 of the lid body 130 is formed on the inner peripheral portion of the opening end surface 112 of the cylindrical body 110, and a step bottom surface is lowered from the surface, and a concave groove 114 is formed on the support surface 113. Has been.
As shown in FIGS. 9A and 11A, when the lid 130 is placed on the support surface 113, the stepped side surface 115 of the cylindrical body 110 and the outer peripheral surface 131 of the lid 130 are brought into contact with each other. A butt portion 102 is formed. Friction stir welding is performed by making the rotary tool 50 make a round along the abutting portion 102, and a plasticized region 103 is formed in the abutting portion 102 (see FIG. 9B). During the friction stir welding, the plastic fluidized metal flows into the concave groove 114, and a part of the plasticized region 103 is located in the concave groove 114. As a result, the metal in the plasticized region 103 becomes a protrusion that engages with the cylindrical body 110, so that the plasticized region 103 and the cylindrical body 110 are engaged with each other (see FIG. 11B).

  As shown in FIG. 8, the cylindrical body 110 according to the present embodiment has a bottomed cylindrical shape in which one side is open and the other side is closed, and the lid body 130 includes only one side of the cylindrical body 110 (opening portion). 111). The cylinder 110 has a rectangular cross section. The cylindrical body 110 is produced by, for example, die casting, casting, forging, or the like. The cylinder 110 is made of aluminum or an aluminum alloy. Thereby, the airtight container 101 has been reduced in weight and is easy to handle.

  A support surface 113 is formed on the inner peripheral portion of the opening end surface 112 of the cylindrical body 110 (the opening peripheral edge portion of the opening 111). As shown in FIG. 11A, the height difference (depth dimension) H3 between the opening end surface 112 of the cylindrical body 110 and the support surface 113 is set to the same dimension as the thickness dimension T3 of the lid body 130. . The support surface 113 is a surface that supports the lid 130, and the peripheral portion 130 a of the lid 130 is placed on the support surface 113.

  As shown in FIGS. 8 and 11, a concave groove 114 is formed in an annular shape on the support surface 113 along the peripheral edge of the opening 111. In this embodiment, the concave groove 114 is formed on the outer peripheral portion of the support surface 113 and has a rectangular cross section. The outer side surface 114 a of the concave groove 114 is flush with the stepped side surface 115 of the cylindrical body 110. The concave groove 114 has a width dimension W1 set smaller than a shoulder diameter (diameter of the shoulder portion 51) dimension R1 of the rotary tool 50 used for friction stir welding (the shoulder diameter dimension R1 of the rotary tool 50 is It is larger than the width dimension W1 of the concave groove 114). In particular, in this embodiment, half (radius dimension) of the shoulder diameter dimension R1 is larger than the width dimension W1 of the concave groove 114. Further, the width dimension W1 of the concave groove 114 is about ¼ of the width dimension W2 of the support surface 113.

  As shown in FIGS. 8 and 9, the lid body 130 is formed in a plate shape having the same outer shape (rectangular shape in the present embodiment) as the step side surface 115 (see FIG. 8) of the cylindrical body 110. As shown in FIG. 11, the thickness 130 of the lid 130 is set to be equal to or larger than the length L1 of the stirring pin 52 of the rotary tool 50 (see FIG. 11). The length dimension L1 of the stirring pin 52 of the rotary tool 50 is equal to or smaller than the thickness dimension T3 of the lid 130).

  Similarly to the cylindrical body 110, the lid body 130 is also made of aluminum or an aluminum alloy. Thereby, the airtight container 101 has been reduced in weight and is easy to handle.

  Next, a method for fixing the lid 130 to the cylinder 110 by friction stir welding will be described with reference to FIGS. 9 to 11.

  First, as shown in FIG. 9A, the lid body 130 is inserted into the opening 111 of the cylindrical body 110, and the peripheral edge portion 130 a of the lid body 130 is placed on the support surface 113. Then, the stepped side surface 115 of the cylindrical body 110 and the outer peripheral surface 131 of the lid body 130 are abutted to form the abutting portion 102. At this time, the concave groove 114 formed on the support surface 113 is covered by the peripheral edge portion 130a of the lid 130, and a space having a rectangular cross section is formed (see FIG. 3A).

  Next, after the rotational tool 50 for friction stir welding is inserted into the insertion position 153, the rotational tool 50 is moved onto the abutting portion 102, and then the moving direction of the rotating tool 50 is changed to move the rotating tool 50 along the abutting portion 102. To move. At this time, it is preferable that a jig 151 (see FIG. 11) surrounding the cylindrical body 110 from four directions is applied in advance to the outer peripheral surface of the peripheral wall 116 of the cylindrical body 110. According to this, the thickness of the peripheral wall 116 is thin, and the distance (gap) between the outer peripheral surface of the shoulder 51 (see FIG. 11B) of the rotary tool 50 and the outer peripheral surface of the peripheral wall 116 is, for example, 2 Even if it is 0.0 mm or less, the peripheral wall 116 is hardly deformed outward by the pressing force of the rotary tool 50. In addition, when the thickness of the surrounding wall 116 is thick, the said jig | tool 151 does not need to be installed.

  Hereinafter, the movement of the rotary tool 50 will be specifically described. First, the rotary tool 50 is inserted into the insertion position 153 while rotating. As shown in FIG. 9A, the insertion position 153 of the rotary tool 50 is the upper surface of the peripheral wall 116 that is outside the abutting portion 102. A pilot hole (not shown) may be formed in advance at the insertion position 153 of the rotary tool 50. If it does in this way, the insertion time (pressing time) of the rotation tool 50 can be shortened.

  Thereafter, the rotary tool 50 is moved while being rotated from the insertion position 153 to a position directly above the abutting portion 102 (a position where the center of the rotating tool 50 is on the abutting portion 102). Thereafter, the rotation tool 50 is moved along the abutting portion 102 by changing the moving direction of the rotating tool 50 so that the center (axial center) of the rotating tool 50 moves on the abutting portion 102. At this time, the cylindrical body 110 and the lid body 130 around the abutting portion 102 are integrally plastically fluidized to become a plasticized region 103. Here, a part of the metal of the cylindrical body 110 and the lid body 130 plastically fluidized by the rotating tool 50 flows into the concave groove 114. And the metal which flowed in into the ditch | groove 114 returns to normal temperature after the rotation tool 50 passes, and it hardens | cures (refer FIG.11 (b)).

  At this time, the shear side 50b on which the rotary tool 50 rotates (see the arrow Y4 in FIG. 9) in the same direction as the moving direction of the rotary tool 50 (see the arrow Y3 in FIG. 9) is located on the outer cylinder 110. The rotary tool 50 is rotated and moved so as to be positioned. That is, as in the present embodiment, when the lid body 130 is positioned on the right side from the rotary tool 50 in the traveling direction, the rotary tool 50 is rotated to the right. In addition, when the cover body 130 is located on the left side facing the traveling direction from the rotary tool 50, the rotary tool 50 is rotated counterclockwise. By doing so, the shear side 50b of the rotary tool 50 is positioned on the thick-walled cylinder 110 side. Then, the thin lid 130 side has a flow side 50a of the rotary tool 50 (the relative speed of the outer periphery of the rotary tool 50 with respect to the joined portion is the magnitude of the moving speed from the magnitude of the tangential speed on the outer periphery of the rotary tool 50). Is the value obtained by subtracting. For this reason, on the thin lid 130 side, the stirring temperature is low, the amount of metal flow is small, and the amount of burrs generated is small, so that cavity defects are less likely to occur. And even if a cavity defect occurs due to frictional stirring, it will occur not on the thin lid body 130 side, but on the thick cylindrical body 110 side and at a position farther away from the abutting portion 102, Since the fluid in the container 1 is difficult to leak to the outside, the sealing performance of the joint is not deteriorated.

  Subsequently, the rotation and movement of the rotary tool 50 are continued, and as shown in FIG. 9B, the rotary tool 50 is made to make a round around the opening 111 to form the plasticized region 103. After rotating the rotary tool 50 once, the rotary tool along the start end (the portion from the start end 154a to a position advanced by a predetermined length in the moving direction of the rotary tool 50 (the same position as the end 154b)) including the start end 154a of the first turn. 50 is moved by a predetermined length. Accordingly, the start end 154a and the end end 154b in the circumferential movement of the rotary tool 50 overlap each other, and a part of the plasticizing region 103 is configured to overlap.

  After that, as shown in FIG. 10A, the movement trajectory of the rotary tool 50 is shifted outward from the end 154b of the first round, and then the friction agitation of the second round is performed. The rotary tool 50 is shifted by moving obliquely so as to go outward as it goes in the moving direction. The amount of deviation of the rotary tool 50 is such that the shoulder 51 of the rotary tool 50 overlaps at least a part of the plasticizing region 103 formed by the movement of the first round of the rotary tool 50 in the width direction. The shear side 50 b of the region 103 is re-stirred by the frictional stirring of the second turn of the rotary tool 50. Thereafter, the rotary tool 50 moves in parallel with the plasticizing region 103 along the abutting portion 102. When entering the second round of movement, the rotary tool 50 is not exchanged and remains inserted in the plasticizing region 103, and the movement direction and the rotation direction are the right rotations (arrows in FIG. 10) as in the first round. (Refer to Y3 and Y4) and the push-in amount is not changed. Note that the rotation speed, movement speed, and the like of the rotary tool 50 may be changed as appropriate according to the shapes and materials of the cylinder 110 and the lid 130. As a result, the second plasticization region where the rotation tool 50 moves in the same direction as the first round and rotates in the same direction overlaps with a part of the plasticization region 103 formed in the first round in the width direction. 104 is formed.

  Then, as shown in FIG. 10B, when the movement of the second turn of the rotary tool 50 is completed, the drawing position of the upper surface of the peripheral wall 116 that has moved the rotary tool 50 outward from the second plasticizing region 104. The rotary tool 50 is pulled out at that position. Since the drawing position 155 is a position that is outside the abutting portion 102, a drawing trace is not formed in the abutting portion 102, and the joining property between the cylindrical body 110 and the lid body 130 is further improved. it can. In addition, you may make it repair a drawing trace.

  As described above, the rotation tool 50 is rotated around the opening portion 111 of the cylindrical body 110 along the abutting portion 102 and friction stir welding is performed to form the plasticized region 103 and the second plasticized region 104. The sealed container 101 is formed by fixing the lid body 130 to the cylinder body 110.

  According to the manufacturing method and the friction stir welding method of the sealed container 101 according to the present embodiment, a part of the metal of the cylindrical body 110 and the lid body 130 plastically fluidized by the rotary tool 50 flows into the concave groove 114. And since it returns to normal temperature and hardens | cures, the metal which flowed into the ditch | groove 114 becomes a protruding item | line engaged with the cylinder 110. FIG. As a result, the plasticized region 103 and the cylindrical body 110 are engaged with each other, and the engagement is increased. Therefore, the sealing performance at the joint between the cylinder 110 and the lid 130 can be improved, and the reliability of the sealed container 101 can be increased.

  Furthermore, since the metal into which the concave groove 114 has flowed constitutes a wall surface that hangs perpendicularly to the surface of the support surface 113, this wall surface serves as a weir, and at the joint between the cylinder 110 and the lid body 130. Liquid tightness can be improved.

  Moreover, in this embodiment, since the ditch | groove 114 is formed in the outer peripheral part of the support surface 113, the abutting part 102 and the ditch | groove 114 become near. As a result, the metal plasticized by the frictional stirring in the first round by the rotary tool 50 that has moved on the abutting portion 102 is likely to flow into the concave groove 114. Furthermore, the shoulder diameter dimension R1 of the rotary tool 50 is larger than the width dimension W1 of the concave groove 114. In particular, in the present embodiment, the radius of the shoulder portion 51 is larger than the width dimension W1 of the concave groove 114. The upper portion of 114 can be covered with the shoulder portion 51 of the rotary tool 50, and the entire upper portion of the concave groove 114 becomes the plasticized region 103, and the plastic fluidized metal easily flows into the concave groove 114. Therefore, the plastic fluidized metal flows into the entire inside of the concave groove 114, and the sealing performance at the joint between the cylindrical body 110 and the lid body 130 can be improved.

  Furthermore, since the length dimension L1 of the stirring pin 52 of the rotary tool 50 is equal to or smaller than the thickness dimension T1 of the lid 130, the tip of the stirring pin 52 does not enter the concave groove 114. As a result, deformation of the peripheral portion of the concave groove 114 can be suppressed, and the engagement area between the plastic fluidized metal and the inner wall surface of the concave groove 114 is increased, so that the engagement between the plasticized region 103 and the cylindrical body 110 is increased. Can be improved.

  Further, after rotating the rotary tool 50 once along the abutting portion 102, the rotating tool 50 is moved along the starting end portion of the first round, and a part of the plasticizing region 103 is overlapped, thereby The plasticized region 103 is not interrupted on the way. Therefore, since the cylindrical body 110 and the lid body 130 are reliably joined over the entire circumference of the abutting portion 102, the sealing performance of the joined portion can be further improved.

  Further, in the present embodiment, when the lid 130 is positioned on the right side facing the traveling direction from the rotary tool 50, the rotary tool 50 is rotated to the right, and the rotary tool 50 is rotated once, and then the rotary tool 50 is rotated. Since the rotating tool 50 is further rotated along the abutting portion 102 so that the stirring pin 52 of the rotating tool 50 moves on the cylindrical body 110 by shifting to the outside of the abutting portion 102, the shear side 50b is obtained. The outer peripheral side of the plasticizing region 103 is re-stirred by the second movement of the rotary tool 50. Therefore, even if a cavity defect is generated on the outer peripheral side of the plasticized region 103, the cavity defect can be reduced by the second movement. Further, the shear side 50b in the second movement of the rotary tool 50 is a part separated from the abutting part 102 on the surface of the cylindrical body 110. Therefore, even if a cavity defect occurs, the shear side 50b is separated from the abutting part 102. Occurs in the part. Therefore, it is difficult for the heat transport fluid to leak to the outside, and the sealing performance of the joint portion is not deteriorated. Further, the plasticizing region 103 and the second plasticizing region 104 are overlapped over the entire circumference of the abutting portion 102 between the cylindrical body 110 and the lid body 130 without a gap. Good bonding can be achieved. Therefore, the sealing performance of the joint can be further improved.

  In the embodiment described above, the rotary tool 50 is rotated twice around the opening 111 to perform frictional stirring. However, the present invention is not limited to this. Since a part of the plastic fluidized metal flows in, the movement of the rotary tool 50 may be completed in only one round.

  Next, in the manufacturing method of the sealed container 101 according to the second embodiment, prior to the step of forming the plasticized region 103 and the second plasticized region 104 with the rotary tool 50 and finally joining the lid body 130 to the cylindrical body 110. The case where the lid 130 is temporarily joined to the cylinder 110 will be described.

  The temporary joining is performed on a part of the abutting portion 2 between the cylindrical body 10 and the lid body 30 and is performed using a temporary joining rotating tool (not shown) smaller than the rotating tool 50. After the temporary bonding, the main bonding is performed using the rotary tool 50 as shown in FIGS. 9 and 10.

  As the temporary bonding rotary tool, the same one as in the first embodiment is used. The plasticizing region 105 (see FIGS. 12 and 13) formed by the temporary bonding rotary tool has a width smaller than the width of the plasticizing region 103 (see FIG. 9) formed by the rotating tool 50 in a later step. Will have. And the plasticization area | region 105 is formed in the position which does not protrude from the position where the plasticization area | region 103 is formed in a next process. As a result, the plasticizing region 105 in the temporary joining is completely covered with the plasticizing region 103, so that the trace of the temporary tool rotation tool and the plasticizing region 105 remaining in the plasticizing region 105 remain. Absent.

  In the embodiment of temporary joining shown in FIG. 12, the abutting portion 102 has a rectangular shape (rectangular frame shape), and after first temporarily joining one of the diagonals 106 a and 106 b of the abutting portion 102, the other diagonal 106c and 106d are temporarily joined. By temporarily joining in this order, the lid 130 can be temporarily joined to the cylinder 110 in a well-balanced manner, positioning accuracy of the lid 130 with respect to the cylinder 110 is improved, and deformation of the lid 130 is prevented. it can. Further, by performing the temporary joining of the lid body 130, it is possible to prevent the lid body 130 from being displaced during the main joining by the rotary tool 50, and it is possible to further improve the sealing performance of the joint portion.

  In the embodiment of the temporary joining shown in FIG. 13, the abutting portion 102 has a rectangular shape (rectangular frame shape), and is linearly performed by friction stir welding at the intermediate portion of each side. Specifically, in the step of temporarily joining the abutting portion 102 with the temporary joining rotary tool, the intermediate portions 107a, 107b of one opposite side 107, 107 of the abutting portion 102 are temporarily joined first and then the other opposite side 108. , 108 are temporarily joined together. At this time, the plasticized regions 105 formed by the temporary bonding rotary tool are linearly formed with the same length. In addition, the plasticized region 105 is formed at a position that does not protrude from the position where the plasticized region 103 is formed in a later step.

  If the temporary bonding is performed in the order as described above, the same effect as the temporary bonding step shown in FIG. 12 can be obtained, and the friction stir welding of the temporary bonding is linear. It can be easily processed by simply moving it.

  Next, a modified example of the manufacturing method of the sealed container 101 according to the second embodiment will be described with reference to FIG. In the second embodiment, as shown in FIG. 11, the opening end surface 112 of the cylindrical body 110 and the surface of the lid body 130 with the stepped side surface 115 of the cylindrical body 110 and the outer peripheral surface 131 of the lid body 130 abutting each other. 14 is configured such that the lid body 130 ′ protrudes from the opening end surface 112 of the cylindrical body 110, as shown in FIG. 14. . That is, the lid body 130 ′ is formed such that the thickness dimension T <b> 4 is larger than the height difference (depth dimension) H <b> 3 between the opening end surface 112 of the cylindrical body 110 and the support surface 113.

  As shown in FIG. 14B, the thickness dimension T4 of the lid body 130 ′ is appropriately set according to the volume of the concave groove 114 and the pressing amount of the rotary tool 50. Specifically, the thickness of the lid 130 ′ is such that the value obtained by subtracting the volume of the metal that becomes a burr from the volume of the metal pushed by the shoulder portion 51 of the rotary tool 50 is substantially equal to the volume of the concave groove 114. The dimension T4 is determined.

As described above, according to this modification in which the thickness dimension T4 of the lid body 130 ′ is increased, the amount of metal of the lid body 130 ′ that is plastically fluidized increases, so that the rotation tool 50 on the cylindrical body 110 side is increased. The pushing amount can be reduced. Thereby, generation | occurrence | production of a burr | flash can be reduced and the material loss of the cylinder 110 and lid 130 'can be reduced. In addition, the cylindrical body 110 side becomes the shear side 50b of the rotary tool 50. However, since the amount of pushing of the shear side 50b is reduced, the stirring action of the metal is reduced, so that generation of cavity defects can be suppressed. Furthermore, in this embodiment, as shown in FIG. 14C, the amount of pushing in the second turn of the rotary tool 50 is also reduced, so that the material loss of the cylindrical body 110 can be further reduced.

  Although not shown, also in the second embodiment, the pressing direction of the rotary tool may be inclined with respect to the depth direction of the abutting portion. In this case, the rotary tool is inclined so that the tip thereof faces the center side of the cylinder 10. The inclination angle is preferably 5 degrees or less with respect to the vertical direction.

  The embodiment of the present invention has been described above. However, the embodiment of the present invention is not limited to this, and can be changed as appropriate without departing from the spirit of the present invention. The cross-sectional shapes of the cylinders 10 and 110 are circular or rectangular. However, the present invention is not limited to this, and any of the cylinders 10 and 110 may have other shapes such as a rectangle, a polygon, a circle, and an ellipse. May be. Moreover, in the said 1st Embodiment and 2nd Embodiment, although the cylinders 10 and 110 are exhibiting bottomed cylindrical shape, it is not limited to this, The both ends may open. . In this case, lids are attached to both ends of the cylinder.

  Moreover, in the said embodiment, although the abutting parts 2 and 102 are orthogonally formed with respect to the surface of the cylinders 10 and 110 and the cover bodies 30 and 130, it is not limited to this. When the cylindrical bodies 10 and 110 and the lid bodies 30 and 130 are produced by die casting, if they are formed so as to be inclined so that the upper side of the stepped side is widened, it is easy to extract from the mold and the production thereof becomes easy.

DESCRIPTION OF SYMBOLS 1 Sealing container 2 Butting part 3 Plasticization area | region 10 Cylindrical body 11 Opening part 12 Inner peripheral surface 13 Opening end surface 30 Cover body 31 Contact surface 32 Concave groove 33 Step side surface 50 Rotating tool 51 Shoulder part 52 Stirring pin 101 Sealing container 102 Butting Part 103 Plasticized region 110 Cylindrical body 111 Opening part 112 Opening end face 113 Support surface 114 Concave groove 115 Step side surface 130 Lid

Claims (21)

In the manufacturing method of the sealed container constituted by fixing the lid body sealing the opening to the opening of the cylindrical body by friction stir welding,
On the outer peripheral surface of the lid body, a contact surface with the inner peripheral surface of the cylindrical body is formed inwardly from the outer peripheral surface of the lid body, and a concave groove is formed on the contact surface.
The abutting surface of the step body and the opening end surface in a state where the abutting surface of the lid body is in contact with the inner peripheral surface of the cylinder body and the step side surface of the lid body and the opening end surface of the cylinder body are butted together A rotating tool is made to make a round along the section, and a plasticized region is formed in the abutting portion, and plastic fluidized metal is allowed to flow into the concave groove to fix the lid body to the cylindrical body. A method for producing a sealed container. The method for manufacturing a liquid cooling jacket according to claim 1, wherein the concave groove is formed closer to the step side surface of the contact surface. The said cylindrical body is exhibiting the bottomed cylinder shape which one side opened. The manufacturing method of the airtight container of Claim 1 or Claim 2 characterized by the above-mentioned. The outer circumferential surface of the lid body and the outer circumferential surface of the cylinder body are flush with each other in a state where the step side surface of the lid body and the opening end surface of the cylinder body face each other. The manufacturing method of the airtight container of any one of Claim 3. The outer peripheral surface of the cylindrical body is located outside the outer peripheral surface of the lid body in a state where the step side surface of the lid body and the opening end surface of the cylindrical body face each other. The manufacturing method of the airtight container of any one of Claim 3. The rotating tool is moved around along the starting end of the first turn after the rotating tool makes a round along the abutting portion, and a part of the plasticizing region is overlapped. The manufacturing method of the airtight container of any one of Claim 5. The length dimension of the stirring pin of the said rotary tool is equivalent to the thickness dimension of the cylinder part of the said cylinder, or smaller than the said thickness dimension, The any one of Claim 1 thru | or 6 characterized by the above-mentioned. Method for manufacturing hermetically sealed containers. The method for manufacturing an airtight container according to any one of claims 1 to 7, wherein a shoulder diameter dimension of the rotary tool is larger than a width dimension of the concave groove. After rotating the rotating tool once, the rotating tool is shifted to the lid body side, and the rotating tool is moved to the abutting portion so that the stirring pin of the rotating tool moves on the outer peripheral surface of the lid body. The manufacturing method of the sealed container according to any one of claims 1 to 8, wherein the circuit further makes a round. The plasticizing region formed in the second round of the rotating tool and the plasticizing region formed in the first round of the rotating tool are arranged so that a part of the width direction overlaps over the entire circumference. The method for manufacturing a sealed container according to claim 9, wherein the rotating tool is moved. When the lid is located on the left side facing the direction of travel from the rotating tool, rotate the rotating tool to the right,
The sealed container according to any one of claims 1 to 10, wherein when the lid body is positioned on the right side facing the traveling direction from the rotating tool, the rotating tool is rotated counterclockwise. Production method. Prior to the step of forming the plasticized region with the rotary tool, a part of the abutting portion is temporarily joined using a rotary tool for temporary joining that is smaller than the rotary tool. The manufacturing method of the airtight container of any one of Claim 11. In the manufacturing method of the sealed container constituted by fixing the lid body sealing the opening to the opening of the cylindrical body by friction stir welding,
On the inner peripheral portion of the opening end surface of the cylindrical body, a support surface of the lid body is formed to be lowered from the opening end surface, and a concave groove is formed on the support surface,
The lid body is placed on the support surface, and the stepped side surface of the cylindrical body and the outer peripheral surface of the lid body are butted together along the abutting portion between the stepped side surface and the outer peripheral surface of the lid body. A hermetically sealed container characterized in that a rotating tool is turned around, a plasticized region is formed in the abutting portion, and a plastic fluidized metal is introduced into the concave groove to fix the lid body to the cylindrical body. Manufacturing method. The method for manufacturing a sealed container according to claim 13, wherein the concave groove is formed in an outer peripheral portion of the support surface. The opening end surface of the cylinder and the surface of the lid are flush with each other in a state where the step side surface of the cylinder and the outer peripheral surface of the lid are abutted. Item 15. The method for producing a sealed container according to any one of Items 14 to 14. The said cover body protrudes from the said opening end surface of the said cylinder body in the state which face | matched the level | step difference side surface of the said cylinder body, and the outer peripheral surface of the said cover body, Either of Claim 13 or Claim 14 characterized by the above-mentioned. The manufacturing method of the airtight container as described in a term. After rotating the rotating tool once, the rotating tool is shifted to the cylindrical body side so that the stirring pin of the rotating tool moves on the opening end surface of the cylindrical body. The manufacturing method of the airtight container according to any one of claims 13 to 16, wherein it makes a further round along. When the lid is located on the right side facing the direction of travel from the rotating tool, rotate the rotating tool to the right,
The sealed container according to any one of claims 13 to 17, wherein when the lid body is positioned on the left side facing the traveling direction from the rotating tool, the rotating tool is rotated counterclockwise. Production method. 14. Prior to the step of forming the plasticized region with the rotary tool, a part of the abutting portion is temporarily joined using a rotary tool for temporary joining smaller than the rotary tool. The manufacturing method of the airtight container of any one of Claim 18. The abutting portion has a rectangular frame shape,
In the step of temporarily joining the abutting portion with the temporary tool for temporary joining, after temporarily joining one diagonal of the abutting portion first, the other diagonal is temporarily joined. 19. A method for producing a sealed container according to 19. The abutting portion has a rectangular frame shape,
In the step of temporarily joining the abutting portion with the temporary tool for temporary joining, the intermediate portions of one opposite side of the abutting portion are temporarily joined first, and then the intermediate portions of the other opposite side are temporarily joined. The method for producing a sealed container according to claim 19.

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