JP2021065914A - Liquid-cooled jacket manufacturing method - Google Patents

Abstract

To provide a liquid-cooled jacket manufacturing method that can appropriately weld aluminium alloy made of different materials to each other.SOLUTION: The liquid-cooled jacket manufacturing method includes a main welding step in which a tip-side pin F3 of a rotary tool F that rotates is inserted into a sealing body 3, and a first butted part J1 is subjected to friction-stir welding by circling the part around the sealing body 3 at a predetermined depth along a set movement route L1 set inside an outer periphery side surface 3c, in a state where an outer peripheral surface of a base end-side pin F2 is contacted with a surface 3a of the sealing body 3 while slightly contacting an outer peripheral surface of the tip-side pin F3 with a first inclined step side surface 12b of a peripheral wall step part. In the main welding step, the tip-side pin F3 that rotates is inserted into a start position SP1 set closer to inside than the set movement route L1, and then the tip-side pin F3 is gradually pressed-in to a predetermined depth, while moving a rotation center shaft of the rotary tool F to a position where the shaft overlaps with the set movement route L1.SELECTED DRAWING: Figure 9

Description

The present invention relates to a method for manufacturing a liquid-cooled jacket.

Liquid-cooled jackets are manufactured using friction stir welding. For example, Patent Document 1 discloses a method for manufacturing a liquid-cooled jacket. FIG. 19 is a cross-sectional view showing a conventional method for manufacturing a liquid-cooled jacket. In the conventional method for manufacturing a liquid-cooled jacket, the butt portion J10 formed by abutting the step side surface 101c provided on the step portion of the aluminum alloy jacket body 101 and the side surface 102c of the aluminum alloy sealing body 102. This is to perform friction stir welding. Further, in the conventional method for manufacturing a liquid-cooled jacket, only the stirring pin F42 of the rotating tool F40 is inserted into the butt portion J10 to perform friction stir welding. Further, in the conventional method for manufacturing a liquid-cooled jacket, the rotation center axis Z of the rotation tool F40 is overlapped with the butt portion J10 and relatively moved.

Japanese Unexamined Patent Publication No. 2015-131321

Here, the jacket body 101 tends to have a complicated shape. For example, a jacket body 101 formed of a cast material of 4000 series aluminum alloy and a relatively simple shape such as a sealing body 102 is a wrought material of 1000 series aluminum alloy. In some cases, it is formed by. In this way, a liquid-cooled jacket may be manufactured by joining members of different grades of aluminum alloy. In such a case, the jacket body 101 generally has a higher hardness than the sealing body 102. Therefore, when friction stir welding is performed as shown in FIG. 19, the stirring pin F42 becomes the sealing body 102. The material resistance received from the jacket body 101 side is larger than the material resistance received from the side. Therefore, it becomes difficult to stir different grades in a well-balanced manner by the stirring pin F42 of the rotating tool F40, and there is a problem that cavity defects occur in the plasticized region after joining and the joining strength decreases.

Further, as shown in FIG. 19, when the stirring pin F42 is inserted into the butt portion J10, the stirring pin F42 is pushed in in the vertical direction until it reaches a predetermined depth, so that the frictional heat at the start position of frictional stirring becomes excessive. .. As a result, at the start position, the metal on the jacket body 101 side is likely to be mixed into the sealing body 102 side, which causes a problem of contributing to poor joining.

From such a viewpoint, it is an object of the present invention to provide a method for producing a liquid-cooled jacket capable of suitably joining aluminum alloys of different grades.

In order to solve the above problems, the present invention is composed of a jacket body having a bottom portion and a peripheral wall portion rising from the peripheral edge of the bottom portion, and a sealing body for sealing the opening of the jacket body. A method for manufacturing a liquid-cooled jacket in which the sealing body is joined by friction stir welding. The jacket body is made of a first aluminum alloy, and the sealing body is made of a second aluminum alloy. The first aluminum alloy is a grade having a higher hardness than the second aluminum alloy, and the rotary tool used for friction stir welding includes a base end side pin and a tip end side pin, and the taper angle of the base end side pin is It is larger than the taper angle of the tip end side pin, and a stepped step portion is formed on the outer peripheral surface of the base end side pin, and the step bottom surface and the step bottom surface are formed on the inner peripheral edge of the peripheral wall portion. A first inclined step side surface that rises so as to spread toward the opening, and a second inclined step side surface that rises so as to further spread toward the opening from the upper end of the first inclined step side surface. The preparatory step of forming the peripheral wall stepped portion having, and forming the plate thickness of the sealing body so as to be larger than the height dimension of the first inclined step side surface of the peripheral wall stepped portion, and the jacket main body. By placing the sealing body on the surrounding wall step portion, the first inclined step side surface of the peripheral wall step portion and the outer peripheral side surface of the sealing body are abutted to form the first abutting portion, and the step bottom surface of the peripheral wall step portion is formed. And the back surface of the sealing body are overlapped to form a second butt portion, and the tip side pin of the rotating tool is inserted into the sealing body to form an outer peripheral surface of the tip side pin. In a state where the outer peripheral surface of the base end side pin is in contact with the surface of the sealing body while slightly contacting the first inclined step side surface of the peripheral wall step portion, the outer peripheral surface of the sealing body is more than the outer peripheral side surface of the sealing body. In the main joining step, the main joining step of circling around the sealing body at a predetermined depth along a set movement route set inside and frictionally agitating the first butt portion is included, and rotation is performed in the main joining step. After inserting the tip side pin to the start position set further inside the set movement route, the rotation center axis of the rotation tool is moved to a position overlapping the set movement route to reach the predetermined depth. It is characterized in that the tip side pin is gradually pushed in until.

According to such a manufacturing method, the second aluminum alloy mainly on the sealing body side of the first butt portion is agitated and plastically fluidized by the frictional heat between the sealing body and the base end side pin and the tip end side pin, and the first butt portion is formed. The first inclined step side surface and the outer peripheral side surface of the sealing body can be joined in the above. Further, since the outer peripheral surface of the tip side pin is kept slightly in contact with the side surface of the first inclined step of the jacket body, it is possible to minimize the mixing of the first aluminum alloy from the jacket body to the sealing body. As a result, in the first butt portion, the second aluminum alloy on the sealing body side is mainly frictionally agitated, so that a decrease in joint strength can be suppressed. Further, by moving the rotation tool to a position overlapping the set movement route and gradually pushing the tip side pin until it reaches a predetermined depth, it is possible to prevent the frictional heat from becoming excessive on the set movement route. ..

In the method for manufacturing a liquid-cooled jacket of the present invention, in the main joining step, the rotation tool is rotated while the outer peripheral surface of the base end side pin is slightly brought into contact with the second inclined step side surface of the peripheral wall step portion. The inclination angle of the central axis with respect to the vertical surface is γ, the inclination angle of the first inclined step side surface with respect to the vertical surface is β, the inclination angle of the second inclined step side surface with respect to the vertical surface is β', and the tip side pin Assuming that the inclination angle of the outer peripheral surface with respect to the rotation center axis is α and the inclination angle of the outer peripheral surface of the proximal end side pin with respect to the rotation center axis is α', γ = α-β and γ = α'-β'. It is preferable to perform friction-stirring joining in this state.

According to such a manufacturing method, the inclination angle γ of the rotation center axis of the rotation tool with respect to the vertical surface is set, and the inclination angle α of the outer peripheral surface of the tip side pin with respect to the rotation center axis is set to the inclination angle β of the first inclined step side surface with respect to the vertical surface. By matching the subtracted values, the optimum values can be selected as the inclination angles α and β. Further, the inclination angle γ of the rotation center axis of the rotation tool with respect to the vertical surface was subtracted from the inclination angle α'with respect to the rotation center axis of the outer peripheral surface of the base end side pin by the inclination angle β'with respect to the vertical surface of the second inclined step side surface. By matching the values, the optimum values can be selected as the inclination angles α'and β'. Further, the outer peripheral surface of the tip side pin and the side surface of the first inclined step are made parallel, and the outer peripheral surface of the base end side pin and the side surface of the second inclined step are made parallel, and the outer peripheral surface of the tip side pin and the side surface of the first inclined step are made parallel. It is possible to avoid contact with the peripheral surface of the base end side pin and contact with the side surface of the second inclined step. At the same time, the outer peripheral surface of the tip end side pin and the side surface of the first inclined step can be brought close to each other as much as possible in the height direction, and the outer peripheral surface of the base end side pin and the side surface of the second inclined step can be brought close to each other in the height direction. It can be made as close as possible.

Further, it is preferable that the predetermined depth of the main joining step is set at a position where the tip end side pin slightly contacts the step bottom surface of the peripheral wall step portion.

According to such a manufacturing method, it is possible to increase the joint strength of the second butt portion while preventing the first aluminum alloy from being mixed into the sealed body as much as possible.

Further, in the main joining step, the tip side pin is rotated at a predetermined rotation speed to perform frictional stirring, and when the tip side pin is inserted in the main joining step, the tip side pin is inserted at a speed higher than the predetermined rotation speed. It is preferable that the tip side pin is inserted in a rotated state and moved to the set movement route while gradually reducing the rotation speed.

According to such a manufacturing method, friction stir welding can be performed more preferably.

In order to solve the above problems, the second invention is composed of a jacket body having a bottom portion and a peripheral wall portion rising from the peripheral edge of the bottom portion, and a sealing body for sealing the opening of the jacket body. A method for manufacturing a liquid-cooled jacket in which a jacket body and the sealing body are joined by frictional stirring. The jacket body is made of a first aluminum alloy, and the sealing body is made of a second aluminum alloy. The first aluminum alloy is a grade having a higher hardness than the second aluminum alloy, and the rotary tool used for friction stirring includes a proximal end side pin and a distal end side pin, and the proximal end side pin is tapered. The angle is larger than the taper angle of the tip end side pin, a stepped step portion is formed on the outer peripheral surface of the base end side pin, and a step bottom surface and a step bottom surface are formed on the inner peripheral edge of the peripheral wall portion. A first inclined step side surface that inclines and rises from the bottom surface of the step toward the opening, and a second incline that inclines and rises from the upper end of the first inclined step side surface toward the opening. A preparatory step of forming a peripheral wall stepped portion having a stepped side surface and forming the plate thickness of the sealing body so as to be larger than the height dimension of the first inclined stepped side surface of the peripheral wall stepped portion. By placing the sealing body on the jacket body, the first inclined step side surface of the peripheral wall step portion and the outer peripheral side surface of the sealing body are abutted to form the first abutting portion, and the peripheral wall step portion is formed. The step bottom surface and the back surface of the sealing body are overlapped to form a second butt portion, and the tip side pin of the rotating tool is inserted into the sealing body to form the tip side pin. The outer peripheral surface of the sealing body is in contact with the surface of the sealing body while the outer peripheral surface of the base end side pin is in contact with the surface of the sealing body while slightly contacting the outer peripheral surface of the peripheral wall step portion with the side surface of the first inclined step. The main joining step includes a main joining step of circling around the sealing body at a predetermined depth along a set movement route set inside the side surface and rubbing and stirring the first butt portion. The tip-side pin is inserted from the start position set on the set movement route, and the tip-side pin is gradually pushed in until the predetermined depth is reached while moving in the traveling direction.

According to such a manufacturing method, the second aluminum alloy mainly on the sealing body side of the first butt portion is agitated and plastically fluidized by the frictional heat between the sealing body and the base end side pin and the tip end side pin, and the first butt portion is formed. The step side surface and the outer peripheral side surface of the sealing body can be joined in the above. Further, since the outer peripheral surface of the tip side pin is kept slightly in contact with the side surface of the first inclined step of the jacket body, it is possible to minimize the mixing of the first aluminum alloy from the jacket body to the sealing body. As a result, in the first butt portion, the second aluminum alloy on the sealing body side is mainly frictionally agitated, so that a decrease in joint strength can be suppressed. Further, by gradually pushing the tip side pin until it reaches a predetermined depth while moving the rotation tool on the set movement route, it is possible to prevent the frictional heat from becoming excessive at one point on the set movement route.

Also in the second method for manufacturing a liquid-cooled jacket of the present invention, in the present joining step, the rotation while slightly contacting the outer peripheral surface of the base end side pin with the second inclined step side surface of the peripheral wall step portion. The inclination angle of the rotation center axis of the tool with respect to the vertical surface is γ, the inclination angle of the first inclined step side surface with respect to the vertical surface is β, the inclination angle of the second inclined step side surface with respect to the vertical surface is β', and the tip thereof is defined as β'. Assuming that the inclination angle of the outer peripheral surface of the side pin with respect to the rotation center axis is α and the inclination angle of the outer peripheral surface of the proximal end side pin with respect to the rotation center axis is α', γ = α−β and γ = α ′ −. It is preferable to perform friction stirring joining in a state of β'.

According to such a manufacturing method, the inclination angle γ of the rotation center axis of the rotation tool with respect to the vertical surface is subtracted from the inclination angle α of the outer peripheral surface of the tip side pin with respect to the rotation center axis by subtracting the inclination angle β with respect to the vertical surface of the step side surface. By matching with, the optimum values can be selected as the inclination angles α and β. Further, the inclination angle γ of the rotation center axis of the rotation tool with respect to the vertical surface was subtracted from the inclination angle α'with respect to the rotation center axis of the outer peripheral surface of the base end side pin by the inclination angle β'with respect to the vertical surface of the second inclined step side surface. By matching the values, the optimum values can be selected as the inclination angles α'and β'. Further, the outer peripheral surface of the tip side pin and the side surface of the first inclined step are made parallel, and the outer peripheral surface of the base end side pin and the side surface of the second inclined step are made parallel, and the outer peripheral surface of the tip side pin and the side surface of the first inclined step are made parallel. It is possible to avoid contact with the peripheral surface of the base end side pin and contact with the side surface of the second inclined step. At the same time, the outer peripheral surface of the tip end side pin and the side surface of the first inclined step can be brought close to each other as much as possible in the height direction, and the outer peripheral surface of the base end side pin and the side surface of the second inclined step can be brought close to each other in the height direction. It can be made as close as possible.

Further, it is preferable that the predetermined depth of the main joining step is set at a position where the tip end side pin slightly contacts the step bottom surface of the peripheral wall step portion.

According to such a manufacturing method, it is possible to increase the joint strength of the second butt portion while preventing the first aluminum alloy from being mixed into the sealed body as much as possible.

Further, in the main joining step, in the main joining step, the tip side pin is rotated at a predetermined rotation speed to perform frictional stirring, and in the insertion step of the main joining step, a speed higher than the predetermined rotation speed is performed. It is preferable to insert the pin on the tip side in a rotated state and push in the rotation tool while gradually reducing the rotation speed.

According to such a manufacturing method, friction stir welding can be performed more preferably.

Further, in the preparatory step, it is preferable that the jacket body is die-cast and at least the sealed body is formed so as to be convex toward the surface side.

According to such a manufacturing method, the liquid-cooled jacket can be flattened by utilizing the heat shrinkage caused by the frictional heat by making the sealed body convex in advance.

Further, it is preferable to further include a temporary joining step of temporarily joining the first butt portion prior to the main joining step.

According to such a manufacturing method, it is possible to prevent the opening of the first butt portion in the main joining step.

According to the method for producing a liquid-cooled jacket according to the present invention, aluminum alloys of different grades can be suitably joined.

It is a side view which shows the rotation tool which concerns on embodiment of this invention. It is an enlarged sectional view of the rotation tool. It is sectional drawing which shows the 1st modification of a rotation tool. It is sectional drawing which shows the 2nd modification of the rotation tool. It is sectional drawing which shows the 3rd modification of the rotation tool. It is an exploded perspective view which shows the liquid-cooled jacket which concerns on 1st Embodiment of this invention. It is sectional drawing which shows the mounting process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is a top view which shows the mounting process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is a top view which shows the main joining process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is sectional drawing which shows the state near the start point of the rotation tool of this joining process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is sectional drawing which shows the main joining process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is a top view which shows the main joining process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is sectional drawing which shows the state near the end point of the rotary tool of this joining process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is sectional drawing which shows the plasticized region formed by the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is a top view which shows the main joining process of the manufacturing method of the liquid-cooled jacket which concerns on 2nd Embodiment. It is a top view which shows after the main joining process of the manufacturing method of the liquid-cooled jacket which concerns on 2nd Embodiment. It is sectional drawing which shows the preparation process and the butt process of the manufacturing method of the liquid-cooled jacket which concerns on 3rd Embodiment. It is sectional drawing which shows the joining process of the manufacturing method of the liquid-cooled jacket which concerns on 1st Embodiment. It is sectional drawing which shows the manufacturing method of the conventional liquid-cooled jacket.

Embodiments of the present invention will be described with reference to the drawings as appropriate. First, the rotation tool used in the joining method according to the present embodiment will be described. The rotary tool is a tool used for friction stir welding. As shown in FIG. 1, the rotary tool F is made of, for example, tool steel, and is mainly composed of a base shaft portion F1, a base end side pin F2, and a tip end side pin F3. The base shaft portion F1 has a columnar shape and is a portion connected to the main shaft of the friction stir welder.

The base end side pin F2 is continuous with the base shaft portion F1 and is tapered toward the tip end. The proximal end side pin F2 has a truncated cone shape. The taper angle A of the base end side pin F2 may be appropriately set, and is, for example, 135 to 160 °. If the taper angle A is less than 135 ° or exceeds 160 °, the joint surface roughness after friction stir welding becomes large. The taper angle A is larger than the taper angle B of the tip side pin F3, which will be described later. As shown in FIG.
On the outer peripheral surface of the base end side pin F2, a stepped pin step portion F21 is formed over the entire height direction. The pin step portion F21 is formed in a clockwise or counterclockwise spiral shape. That is, the pin step portion F21 has a spiral shape when viewed in a plane and a step shape when viewed from a side surface. In the first embodiment, in order to rotate the rotation tool F clockwise, the pin step portion F21 is set counterclockwise from the base end side to the tip end side.

When rotating the rotation tool F counterclockwise, it is preferable to set the pin step portion F21 clockwise from the base end side to the tip end side. As a result, the plastic fluid material is guided to the tip side by the pin step portion F21, so that the metal overflowing to the outside of the metal member to be joined can be reduced. The pin step portion F21 is composed of a step bottom surface F21a and a step side surface F21b. The distance X1 (horizontal distance) between the vertices F21c and F21c of the adjacent pin step portions F21 is appropriately set according to the step angle C and the height Y1 of the step side surface F21b described later.

The height Y1 of the step side surface F21b may be appropriately set, and is set to, for example, 0.1 to 0.4 mm. If the height Y1 is less than 0.1 mm, the joint surface roughness becomes large. On the other hand, when the height Y1 exceeds 0.4 mm, the joint surface roughness tends to increase, and the number of effective step portions (the number of pin step portions F21 in contact with the metal member to be joined) also decreases.

The step angle C formed by the step bottom surface F21a and the step side surface F21b may be appropriately set, but is set to, for example, 85 to 120 °. The step bottom surface F21a is parallel to the horizontal plane in this embodiment. The step bottom surface F21a may be inclined in the range of -5 ° to 15 ° with respect to the horizontal plane from the rotation center axis of the tool toward the outer peripheral direction (minus is downward with respect to the horizontal plane, plus is with respect to the horizontal plane). Above). The distance X1, the height Y1 of the step side surface F21b, the step angle C, and the angle of the step bottom surface F21a with respect to the horizontal plane are such that the plastic fluid does not stay inside the pin step portion F21 and adhere to the outside during friction stir welding. The surface roughness of the joint is appropriately set so that the plastic fluid material can be pressed by the step bottom surface F21a to reduce the roughness of the joint surface.

As shown in FIG. 1, the distal end side pin F3 is continuously formed on the proximal end side pin F2. The tip side pin F3 has a truncated cone shape. The tip of the tip side pin F3 is a flat surface F4 perpendicular to the rotation center axis. The taper angle B of the tip end side pin F3 is smaller than the taper angle A of the base end side pin F2. As shown in FIG. 2, a spiral groove F31 is engraved on the outer peripheral surface of the tip end side pin F3. The spiral groove F31 may be clockwise or counterclockwise, but in the first embodiment, the spiral groove F31 is carved counterclockwise from the base end side to the tip end side in order to rotate the rotation tool F clockwise.

When rotating the rotation tool F counterclockwise, it is preferable to set the spiral groove F31 clockwise from the base end side to the tip end side. As a result, the plastic fluid material is guided to the tip side by the spiral groove F31, so that the metal overflowing to the outside of the metal member to be joined can be reduced. The spiral groove F31 is composed of a spiral bottom surface F31a and a spiral side surface F31b. The distance (horizontal distance) between the vertices F31c and F31c of the adjacent spiral grooves F31 is defined as the length X2. The height of the spiral side surface F31b is defined as the height Y2. The spiral angle D composed of the spiral bottom surface F31a and the spiral side surface F31b is formed at, for example, 45 to 90 °. The spiral groove F31 has a role of increasing frictional heat by coming into contact with the metal member to be joined and guiding the plastic fluid material to the tip side.

The design of the rotation tool F can be changed as appropriate. FIG. 3 is a side view showing a first modification of the rotation tool of the present invention. As shown in FIG. 3, in the rotation tool FA according to the first modification, the step angle C formed by the step bottom surface F21a of the pin step portion F21 and the step side surface F21b is 85 °. The step bottom surface F21a is parallel to the horizontal plane. As described above, the step bottom surface F21a is parallel to the horizontal plane, and the step angle C may be an acute angle within a range in which the plastic fluid material stays in the pin step portion F21 during friction stir welding and escapes to the outside without adhering. ..

FIG. 4 is a side view showing a second modification of the rotation tool of the present invention. As shown in FIG. 4, in the rotation tool FB according to the second modification, the step angle C of the pin step portion F21 is 115 °. The step bottom surface F21a is parallel to the horizontal plane. As described above, the step bottom surface F21a may be parallel to the horizontal plane, and the step angle C may be obtuse within the range in which the step bottom surface F21a functions as the pin step portion F21.

FIG. 5 is a side view showing a third modification of the rotation tool of the present invention. As shown in FIG. 5, in the rotation tool FC according to the third modification, the step bottom surface F21a is inclined 10 ° upward with respect to the horizontal plane from the rotation center axis of the tool toward the outer peripheral direction. The step side surface F21b is parallel to the vertical surface. As described above, the step bottom surface F21a may be formed so as to be inclined upward from the horizontal plane from the rotation center axis of the tool toward the outer peripheral direction within a range in which the plastic fluid material can be pressed during friction stir welding. The same effect as that of the following embodiment can be obtained by the first to third modifications of the rotation tool described above.

[First Embodiment]
Embodiments of the present invention will be described with reference to the drawings as appropriate. As shown in FIG. 6, the liquid-cooled jacket 1 according to the first embodiment is composed of a jacket body 2 and a sealing body 3. The liquid-cooled jacket 1 is a device that circulates a fluid inside to cool an arranged heating element. The jacket body 2 and the sealing body 3 are integrated by friction stir welding. In the following description, the "front surface" means the surface opposite to the "back surface".

The jacket body 2 is mainly composed of a bottom portion 10 and a peripheral wall portion 11. The jacket body 2 is not particularly limited as long as it is a metal capable of friction stir welding, but in the present embodiment, it is formed mainly containing a first aluminum alloy. As the first aluminum alloy, for example, an aluminum alloy casting material such as JISH5302 ADC12 (Al—Si—Cu system) is used.

The bottom portion 10 is a plate-shaped member having a rectangular shape. The peripheral wall portion 11 is a wall portion that rises in a rectangular frame shape from the peripheral edge portion of the bottom portion 10. A recess 13 is formed in the bottom portion 10 and the peripheral wall portion 11. A peripheral wall step portion 12 is formed on the inner peripheral edge of the peripheral wall portion 11. The peripheral wall step portion 12 is composed of a step bottom surface 12a, a first inclined step side surface 12b that rises diagonally from the step bottom surface 12a, and a second inclined step side surface 12c that rises further inclined from the upper end of the first inclined step side surface 12b. ing. The first inclined step side surface 12b is inclined so as to spread toward the opening of the jacket body 2 (as it goes upward). The second inclined step side surface 12c is inclined toward the opening so as to be further widened than the first inclined step side surface 12b. As shown in FIG. 7, the inclination angle β of the first inclined step side surface 12b and the inclination angle β'of the second inclined step side surface 12c may be appropriately set, but the inclination angle β of the first inclined step side surface 12b Is smaller than the inclination angle β'of the second inclined step side surface 12c. Further, in the present embodiment, the inclination angle β of the first inclined step side surface 12b is the same as the inclination angle α (half of the taper angle B) of the tip side pin F3 of the rotation tool F shown in FIG. 11, and the second inclined step The inclination angle β'of the side surface 12c is the same as the inclination angle α'(half of the taper angle A) of the base end side pin F2 of the rotation tool F.

Although the jacket body 2 of the present embodiment is integrally formed, for example, the peripheral wall portion 11 may be divided and joined by a seal member to be integrated.

The sealing body 3 is a member that seals the opening of the jacket body 2. The sealing body 3 is not particularly limited as long as it is a metal capable of friction stir welding, but in the present embodiment, it is formed mainly containing a second aluminum alloy. The second aluminum alloy is a material having a lower hardness than the first aluminum alloy. The second aluminum alloy is formed of, for example, an aluminum alloy wrought material such as JIS A1050, A1100, A6063. In the present specification, the hardness refers to Brinell hardness and can be measured by a method according to JIS Z 2243.

Next, a method for manufacturing the liquid-cooled jacket according to the present embodiment will be described. In the method for manufacturing a liquid-cooled jacket according to the present embodiment, a preparation step, a mounting step, and a main joining step are performed.

The preparation step is a step of preparing the jacket body 2 and the sealing body 3. Jacket body 2
The manufacturing method of the sealing body 3 and the sealing body 3 is not particularly limited, but the jacket body 2 is molded by die casting, for example. The sealing body 3 is formed by, for example, extrusion molding.

As shown in FIG. 7, the mounting step is a step of mounting the sealing body 3 on the jacket body 2. By the mounting step, the outer peripheral side surface 3c of the sealing body 3 and the first inclined step side surface 12b of the peripheral wall step portion 12 are abutted to form the first abutting portion J1. Since the first inclined step side surface 12b is inclined outward, a gap having a V-shaped cross section is formed in the first butt portion J1. Since the second inclined step side surface 12c is inclined further outward than the first inclined step side surface 12b, it does not come into contact with the outer peripheral side surface 3c of the sealing body 3. The first butt portion J1 is formed in a rectangular shape in a plan view along the periphery of the sealing body 3. Further, the step bottom surface 12a of the peripheral wall step portion 12 and the back surface 3b of the sealing body 3 are butted to form the second butted portion J2. The plate thickness of the sealing body 3 may be appropriately set, but in the present embodiment, it is larger than the sum of the height dimension of the first inclined step side surface 12b and the height dimension of the second inclined step side surface 12c. .. The surface 3a of the sealing body 3 is located above the surface 11a of the peripheral wall portion 11 of the jacket body 2.

As shown in FIG. 8, the “set movement route L1” (dashed line) is set inside the first butt portion J1. The set movement route L1 is a movement route of the rotation tool F necessary for joining the first butt portion J1 in the main joining step described later. As will be described later, in the present embodiment, the tip end side pin F3 is slightly brought into contact with the first inclined step side surface 12b, and the base end side pin F2 is slightly brought into contact with the second inclined step side surface 12c. Is set to have a rectangular shape in a plan view inside the outer peripheral side surface 3c.

As shown in FIGS. 9, 11 and 12, this joining step is a step of friction stir welding the first butt portion J1 using the rotary tool F. As shown in FIGS. 9 and 12, in this joining step, the intrusion section from the start position SP1 to the intermediate point S1 and the intermediate point S2 (see FIG. 12) that goes around from the intermediate point S1 on the set movement route L1. This section and the three sections of the detachment section from the intermediate point S2 to the end position EP1 (see FIG. 12) are continuously frictionally agitated. The intermediate points S1 and S2 are set on the set movement route L1. The start position SP1 is set at a position inside the set movement route L1 on the surface 3a of the sealing body 3. In the present embodiment, the angle formed by the line segment connecting the start position SP1 and the intermediate point S1 and the set movement route L1 is set to an obtuse angle.

In the closet section of the main joining step, as shown in FIG. 9, friction stir welding is performed from the start position SP1 to the intermediate point S1. In the closet section, the tip side pin F3 rotated clockwise is inserted into the start position SP1 and moved to the intermediate point S1. At this time, as shown in FIG. 10, the tip side pin F3 is gradually pushed in so as to reach a preset "predetermined depth" by at least reaching the intermediate point S1. That is, instead of keeping the rotation tool F in one place, the rotation tool F is gradually lowered while being moved to the set movement route L1.

When the intermediate point S1 is reached, the process proceeds to friction stir welding in this section as it is. As shown in FIGS. 9 and 11, in this section, the rotation tool F is moved so that the rotation center axis Z of the tip side pin F3 and the set movement route L1 overlap. At this time, since the jacket body 2 is provided with the second inclined step side surface 12c, it is possible to prevent the base end side pin F2 from making large contact with the jacket body 2, and slightly contact the second inclined step side surface 12c. Can be done. In this section, the "predetermined depth" of the tip-side pin F3 is set so that the flat surface F4 at the tip of the tip-side pin F3 slightly contacts the step bottom surface 12a. The "predetermined depth" of the tip-side pin F3 may be appropriately set, and may be set at a position where the tip-side pin F3 does not reach the step bottom surface 12a, for example.

In this section of the main joining step, as shown in FIG. 11, the outer peripheral surface of the tip side pin F3 slightly contacts the first inclined step side surface 12b, and the outer peripheral surface of the proximal end side pin F2 is slightly in contact with the second inclined step side surface 12c. The set movement route L1 is set so that the surfaces slightly touch each other. Further, in this section of the first main joining step, the insertion depth is set so that the outer peripheral surface of the base end side pin F2 of the rotation tool F comes into contact with the surface 3a of the sealing body 3. Here, the contact allowance of the outer peripheral surface of the tip side pin F3 with respect to the first inclined step side surface 12b is defined as the offset amount N. This offset amount N is equivalent to the contact allowance of the outer peripheral surface of the base end side pin F2 with respect to the second inclined step side surface 12c. As in the present embodiment, the flat surface F4 of the tip side pin F3 is inserted deeper than the step bottom surface 12a of the peripheral wall step portion 12, and the outer peripheral surface of the tip side pin F3 is brought into contact with the first inclined step side surface 12b. When the outer peripheral surface of the base end side pin F2 is brought into contact with the second inclined step side surface 12c, the offset amount N is set between 0 <N ≦ 1.0 mm, preferably 0 <N ≦ 0.85 mm. It is set between 0 <N ≦ 0.65 mm, more preferably 0 <N ≦ 0.65 mm.

When the outer peripheral surface of the tip end side pin F3 and the first inclined step side surface 12b are not in contact with each other and the outer peripheral surface of the base end side pin F2 and the second inclined step side surface 12c are not in contact with each other, the first butt portion J1 The joint strength is low. Further, when the offset amount N between the outer peripheral surface of the tip end side pin F3 and the first inclined step side surface 12b and the offset amount N between the outer peripheral surface of the proximal end side pin F2 and the second inclined step side surface 12c exceed 1.0 mm, the jacket A large amount of the first aluminum alloy of the main body 2 may be mixed into the sealing body 3 side, resulting in poor bonding.

As shown in FIG. 12, when the rotation tool F is made to go around the sealing body 3, the start end and the end end of the plasticized region W are overlapped, and when the tip end side pin F3 reaches the intermediate point S2, the detachment section is as it is. Move to. In the detachment section, as shown in FIG. 13, the tip side pin F3 is gradually moved upward from the intermediate point S2 to the end position EP1, and the tip side pin F3 is gradually moved upward from the sealing body 3 at the end position EP1. To leave. That is, the rotation tool F is gradually pulled out (raised) while being moved to the end position EP1 without staying in one place. The end position EP1 is set at a position where the angle formed by the line segment connecting the end position EP1 and the intermediate point S2 and the set movement route L1 is an obtuse angle. A plasticized region W is formed in the movement locus of the rotation tool F.

As shown in FIG. 14, the plasticized region W is formed so as to extend beyond the first butt portion J1 and the second butt portion J2 and reach the jacket body 2. The sealing body 3 side is high and the jacket body 2 side is low, and an inclined surface is formed on the surface of the plasticized region W.

According to the method for manufacturing a liquid-cooled jacket in the present embodiment described above, the second aluminum alloy mainly on the sealing body 3 side of the first butt portion J1 is agitated by the frictional heat between the sealing body 3 and the tip side pin F3. Then, it is plastically fluidized, and the first inclined step side surface 12b and the outer peripheral side surface 3c of the sealing body 3 can be joined at the first butt portion J1. Further, the outer peripheral surface of the tip end side pin F3 is slightly brought into contact with the first inclined step side surface 12b of the jacket body 2, and the outer peripheral surface of the base end side pin F2 is slightly brought into contact with the second inclined step side surface 12c of the jacket body 2. It is possible to minimize the mixing of the first aluminum alloy from the jacket body 2 to the sealing body 3 in order to keep the jacket body 3 from being mixed. As a result, in the first butt portion J1, the second aluminum alloy on the sealing body 3 side is mainly frictionally agitated, so that a decrease in joint strength can be suppressed. That is, in this joining step, the imbalance of the material resistance received by the tip side pin F3 on one side and the other side with respect to the rotation center axis Z of the tip side pin F3 can be minimized. As a result, the plastic fluid material is frictionally agitated in a well-balanced manner, so that a decrease in joint strength can be suppressed. Further, by increasing the plate thickness of the sealing body 3, it is possible to prevent a metal shortage at the joint portion.

Further, in the conventional method for manufacturing a liquid-cooled jacket, since the hardness of the jacket body and the sealing body are different, the material resistance received by the tip end side pin and the base end side pin on one side and the other side of the rotation center axis. Was also very different. Therefore, the plastic fluid material is not agitated in a well-balanced manner, which causes a decrease in joint strength. However, according to the present embodiment, since the contact allowance between the outer peripheral surface of the tip end side pin F3 and the proximal end side pin F2 and the jacket body 2 is made as small as possible, the distal end side pin F3 and the proximal end side pin F2 are jacketed. The material resistance received from the main body 2 can be minimized.

Further, in the present embodiment, in the main joining step, the outer peripheral surface of the base end side pin F2 is brought into contact with the sealing body 3, and friction stirring is performed while pressing the plastic fluid material, so that the generation of burrs can be suppressed. it can. Further, since the plastic fluid material can be pressed on the outer peripheral surface of the base end side pin F2, the stepped concave groove formed on the joint surface (surface 3a of the sealing body 3) can be reduced, and the stepped concave groove can be reduced. The bulge formed on the side of the can be eliminated or reduced. Further, since the stepped pin step portion F21 of the base end side pin F2 is shallow and the outlet is wide, the plastic fluid material can be easily pulled out to the outside of the pin step portion F21 while pressing the plastic fluid material with the step bottom surface F21a. There is. Therefore, even if the plastic fluid material is pressed by the base end side pin F2, the plastic fluid material is unlikely to adhere to the outer peripheral surface of the base end side pin F2. Therefore, the roughness of the joint surface can be reduced, and the joint quality can be suitably stabilized.

Further, in the closet section of the main joining process, the rotary tool F is moved from the start position SP1 to a position overlapping the set movement route L1 and the tip side pin F3 is gradually pushed in until it reaches a predetermined depth to move the set movement. It is possible to prevent the rotation tool F from stopping on the route L1 and causing the frictional heat to become excessive.
Similarly, in the detachment section of the main joining step, the set movement route is separated by gradually raising the tip side pin F3 from a predetermined depth while moving the rotation tool F from the set movement route L1 to the end position EP1. It is possible to prevent the rotation tool F from stopping on L1 and excessive frictional heat.
As a result, it is possible to prevent the frictional heat from becoming excessive on the set movement route L1 and the first aluminum alloy from being excessively mixed from the jacket body 2 to the sealing body 3 to cause poor bonding.

Further, friction stir welding is performed with the tip end side pin F3 slightly in contact with both the first inclined step side surface 12b and the step bottom surface 12a, and the base end side pin F2 slightly in contact with the second inclined step side surface 12c. By doing so, the first butt portion J1 and the second butt portion J2 can be reliably joined. Further, the second inclined step side surface 12c and the base end side pin F2 are slightly brought into contact with each other, the first inclined step side surface 12b and the tip end side pin F3 are slightly brought into contact with each other, and the step bottom surface 12a and the tip end side pin F3 are brought into contact with each other. Since the contact is kept only slightly, it is possible to prevent the first aluminum alloy from being mixed into the sealing body 3 from the jacket body 2 as much as possible.

Further, in the main joining step, the position of the start position SP1 may be appropriately set, but by setting the angle formed by the start position SP1 and the set movement route L1 to be an obtuse angle, the rotation tool F at the intermediate point S1 Smoothly transitions to this section without slowing down the movement speed of. As a result, it is possible to prevent the frictional heat from becoming excessive due to the rotation tool F stopping or the moving speed decreasing on the set movement route L1. Further, also at the end position EP1, by setting in the same manner as at the start position SP1, the rotation tool F can be smoothly moved from this section to the departure section.

Further, in the main joining step of the present embodiment, the rotation direction and the traveling direction of the rotation tool F may be appropriately set, but the jacket body 2 side of the plasticized region W formed in the movement locus of the rotation tool F is sheared. The rotation direction and the traveling direction of the rotation tool F were set so as to be on the side and the sealing body 3 side was on the flow side. By setting the jacket body 2 side to be the shear side, the stirring action by the tip side pin F3 around the first butt portion J1 is enhanced, and the temperature rise in the first butt portion J1 can be expected, and the first butt portion J1 In, the first inclined step side surface 12b and the outer peripheral side surface 3c of the sealing body 3 can be more reliably joined.

The shear side (Advancing side) means the side where the relative speed of the outer circumference of the rotating tool with respect to the jointed portion is the value obtained by adding the magnitude of the moving speed to the magnitude of the tangential velocity on the outer circumference of the rotating tool. .. On the other hand, the Retreating side refers to the side where the relative speed of the rotating tool with respect to the jointed portion becomes low due to the rotation of the rotating tool in the direction opposite to the moving direction of the rotating tool.

Further, the first aluminum alloy of the jacket body 2 is a material having a higher hardness than the second aluminum alloy of the sealing body 3. Thereby, the durability of the liquid-cooled jacket 1 can be enhanced. Further, it is preferable that the first aluminum alloy of the jacket body 2 is an aluminum alloy casting material and the second aluminum alloy of the sealing body 3 is an aluminum alloy wrought material. By using an Al—Si—Cu based aluminum alloy casting material such as JIS H5302 ADC12 as the first aluminum alloy, the castability, strength, machinability, etc. of the jacket body 2 can be improved. Further, by using, for example, JIS A1000 series or A6000 series as the second aluminum alloy, processability and thermal conductivity can be improved.

Further, in the main joining step, since the entire circumference of the first butt portion J1 can be friction-stir welded in the main joining step, the airtightness and watertightness of the liquid-cooled jacket can be improved. Further, by overlapping the ends on the start point side and the end point side of the plasticized region W, the airtightness and watertightness can be further improved.

Further, by setting the inclination angle α of the tip side pin F3 and the inclination angle β of the first inclined step side surface 12b to be the same (parallel), the inclination angle β of the first inclined step side surface 12b is made uniform over the entire height direction. The tip side pin F3 can be brought into contact with the pin F3. Further, by setting the inclination angle α'of the base end side pin F2 and the inclination angle β'of the second inclined step side surface 12c to be the same (parallel), the entire area of the second inclined step side surface 12c in the height direction is set. The base end side pins F2 can be brought into contact with each other uniformly. As a result, friction stir welding can be performed in a well-balanced manner.

In this joining step, the rotation speed of the rotation tool F may be constant, but may be variable. In the indentation section of this joining process, assuming that the rotation speed of the rotation tool F at the start position SP1 is V1 and the rotation speed of the rotation tool F between the intermediate points S1 to S2 is V2, V1
> V2 may be set. The rotation speed V2 is a preset constant rotation speed in the set movement route L1. That is, at the start position SP1, the rotation speed may be set high, and the rotation speed may be gradually reduced in the closet section to shift to the main section.

Further, assuming that the rotation speed of the rotation tool F between the intermediate points S1 and S2 is V2 and the rotation speed of the rotation tool F at the end position EP1 is V3 in the separation section of the first main joining process, V3> V2. May be. That is, after shifting to the detachment section, the rotation tool F may be detached from the sealing body 3 while gradually increasing the rotation speed toward the end position EP1. By setting as described above when the rotary tool F is pushed into or detached from the sealing body 3, the small pressing force in the indentation section or the detaching section can be compensated by the rotational speed. Therefore, friction stir welding can be preferably performed.

[Second Embodiment]
Next, a method for manufacturing a liquid-cooled jacket according to the second embodiment of the present invention will be described. In the second embodiment, as shown in FIG. 15, the positions of the start position SP2 and the end position EP2 in the main joining step are different from those in the first embodiment. In the second embodiment, the parts different from the first embodiment will be mainly described.

In the production of the liquid-cooled jacket according to the second embodiment, a preparation step, a mounting step, and a main joining step are performed. The preparation step and the placement step are the same as those in the first embodiment.

As shown in FIG. 15, in the main joining process of the present embodiment, the start position SP2 is set on the set movement route L1 and the end position EP2 is set on the set movement route L1.

In this joining process, the intrusion section from the start position SP2 to the intermediate point S1, the main section from the intermediate point S1 on the set movement route L1 to the intermediate point S2 that goes around, and the departure from the intermediate point S2 to the end position EP2. Friction stir welding is performed continuously for three sections. The intermediate points S1 and S2 are set on the set movement route L1.

In the closet section of the main joining step, as shown in FIG. 15, friction stir welding is performed from the start position SP2 to the intermediate point S1. In the closet section, the tip side pin F3 rotated clockwise is inserted into the start position SP2 and moved to the intermediate point S1. At this time, the tip side pin F3 is gradually pushed in so as to reach a preset "predetermined depth" by at least reaching the intermediate point S1.

When the intermediate point S1 is reached, the process proceeds to friction stir welding in this section as it is. As shown in FIGS. 15 and 16, in this section, the rotation tool F is moved so that the rotation center axis Z of the tip side pin F3 and the set movement route L1 overlap. The offset amount between the tip end side pin F3 and the first inclined step side surface 12b, the offset amount between the base end side pin F2 and the second inclined step side surface 12c, and the insertion depth of the tip end side pin F3 are the same as those in the first embodiment. ..

When the tip side pin F3 reaches the intermediate point S2, the process shifts to the detachment section as it is. In the detachment section, the tip side pin F3 is gradually pulled out (raised) from the sealing body 3 between the intermediate point S2 and the end position EP2, and at the end position EP2 set on the set movement route L1. The tip side pin F3 is separated from the sealing body 3.

The method for manufacturing the liquid-cooled jacket according to the second embodiment described above can also achieve substantially the same effect as that of the first embodiment. Further, in the closet section of the main joining step according to the second embodiment, the rotary tool F is moved on the set movement route L1 and the tip side pin is gradually pushed in until the depth reaches a predetermined depth, so that the set movement route L1 It is possible to prevent the rotation tool F from stopping at the above point and causing the frictional heat to become excessive.

[Third Embodiment]
Next, a method for manufacturing a liquid-cooled jacket according to the third embodiment of the present invention will be described. The third embodiment is different from the above-described embodiment in that, as shown in FIGS. 16 and 17, the rotary tool F is tilted to perform friction stir welding. In this embodiment, the points different from those in the first embodiment will be mainly described.

In the present embodiment, the first inclined step side surface 12b1 and the second inclined step side surface 12c1 of the jacket body 2 are inclined outward more than in the first embodiment. That is, the inclination angle β1 of the first inclined step side surface 12b1 is larger than the inclination angle β of the first inclined step side surface 12b of the first embodiment, and the inclination angle β'1 of the second inclined step side surface 12c1 is the first embodiment. It is larger than the inclination angle β'of the second inclined step side surface 12c. The intersection angle between the first inclined step side surface 12b1 and the second inclined step side surface 12c1 is the same as that of the first embodiment, and the outer peripheral surface of the tip side pin F3 of the rotation tool F and the outer peripheral surface of the base end side pin F2 It is equivalent to the intersection angle.

As shown in FIG. 18, in this joining step, the rotation center axis j of the rotation tool F is tilted toward the outer peripheral portion side of the jacket body 2 by an inclination angle γ with respect to the vertical plane, and the tip side pin F3 is sealed. Friction stir welding is performed in contact with 3. The tilt angle γ for tilting the rotation center axis j of the rotation tool F with respect to the vertical plane is the first tilt of the jacket body 2 from the tilt angle α formed by the outer peripheral surface of the tip side pin F3 and the rotation center axis j. It is the same as the value obtained by subtracting the inclination angle β1 (see FIG. 17) of the step side surface 12b1 (γ = α-β1), and the inclination angle formed by the outer peripheral surface of the proximal end side pin F2 and the rotation center axis j. It is the same as the value obtained by subtracting the inclination angle β'1 (see FIG. 17) of the second inclined step side surface 12c1 of the jacket body 2 from α'(γ = α'-β'1). Since the value of γ in this case is a negative value, the rotation center axis j is tilted toward the outer peripheral portion of the jacket body 2. The outer peripheral surfaces of the tip side pin F3 facing the first inclined step side surface 12b1 and the first inclined step side surface 12b1 are parallel. Further, the outer peripheral surfaces of the base end side pin F2 facing the second inclined step side surface 12c1 and the second inclined step side surface 12c1 are parallel.

That is, the direction in which the rotation center axis j of the rotation tool F is tilted is determined by the relationship between the tilt angles α, β1, α', and β'1. For example, in the case of "α> β1, α'>β'1", the tilt angle γ becomes a positive value, and the rotation center axis j of the rotation tool F is tilted toward the sealing body 3. Further, when "α <β1, α'<β'1", the tilt angle γ becomes a negative value, and the rotation center axis j of the rotation tool F is tilted toward the outer peripheral portion side of the jacket body 2. Further, in the case of "α = β1, α'= β'1", the inclination angle γ becomes "0 (zero)", and the rotation center axis j of the rotation tool F is not tilted and is parallel to the vertical plane.
Since the other steps are the same as those in the first embodiment, the description thereof will be omitted.

The method for manufacturing the liquid-cooled jacket according to the third embodiment described above can also achieve substantially the same effect as that of the first embodiment. Further, in the present embodiment, the inclination angle γ of the rotation center axis j of the rotation tool F with respect to the vertical surface is changed from the inclination angle α with respect to the rotation center axis j of the outer peripheral surface of the tip side pin F3 to the vertical surface of the first inclined step side surface 12b1. The inclination angle β1 with respect to the vertical surface of the second inclined step side surface 12c1 was subtracted from the inclination angle α'with respect to the rotation center axis j of the outer peripheral surface of the proximal end side pin F2. By matching the values, the following effects can be obtained. That is, the optimum values can be selected as the inclination angles α, β1, α', and β'1. Further, the outer peripheral surface of the tip side pin F3 and the first inclined step side surface 12b1 are made parallel to each other, and the outer peripheral surface of the tip side pin F3 is avoided while avoiding contact between the outer peripheral surface of the tip side pin F3 and the first inclined step side surface 12b1. And the first inclined step side surface 12b1 can be brought close to each other as much as possible in the height direction. Further, the outer peripheral surface of the base end side pin F2 and the second inclined step side surface 12c1 are made parallel to each other, and the base end side pin F2 is avoided while avoiding contact between the outer peripheral surface of the base end side pin F2 and the second inclined step side surface 12c1. The outer peripheral surface and the second inclined step side surface 12c1 can be brought close to each other as much as possible in the height direction. Further, the contact allowance between the outer peripheral surface of the tip end side pin F3 and the first inclined step side surface 12b1 can be made uniform over the height direction, and the contact between the outer peripheral surface of the proximal end side pin F2 and the second inclined step side surface 12c1 can be made uniform. The allowance can be made uniform over the height direction. As a result, in the present embodiment, the plastic fluid material is agitated in a well-balanced manner, so that a decrease in the strength of the joint can be suppressed.

Further, the inclination angles α and α'are determined by the design concept of the rotation tool according to the technical field of friction stir welding (FSW), and the inclination angles β1 and β'1 are determined by the casting field (for example, die casting). Determined by the design concept of the mold. That is, since the inclination angles α, α', β1, β'1 all have optimum values depending on the design concept, it may be difficult to set "α = β1, α'= β'1". However, according to the present embodiment, since the tilt angles α, α', β1, β'1 can be freely selected, the optimum values can be selected as the tilt angles α, β.

Although the embodiments of the present invention have been described above, the design can be appropriately changed within a range not contrary to the gist of the present invention. In the above embodiment, the tip end side pin F3 is slightly brought into contact with both the first inclined step side surface 12b and the step bottom surface 12a, and the base end side pin F2 is slightly brought into contact with the second inclined step side surface 12c. Friction stir welding is performed, but the present invention is not limited to this. The base end side pin F2 does not necessarily have to be in contact with the second inclined step side surface 12c.

In the above embodiment, the surface 3a of the sealing body 3 is located above the surface 11a of the peripheral wall portion 11 of the jacket body 2, but the present invention is not limited to this. The surface 3a of the sealing body 3 and the surface 11a of the peripheral wall portion 11 of the jacket body 2 may have the same height.

By the way, when frictional heat is generated by friction stir welding, the sealing body 3 may warp in a concave shape due to heat shrinkage. Therefore, the sealing body 3 may be formed in advance so as to be convex toward the surface 3a. With this configuration, the liquid-cooled jacket can be flattened by utilizing heat shrinkage.

Further, before performing the main joining step, a temporary joining step of temporarily joining the jacket body 2 and the sealing body 3 may be performed. As a result, it is possible to prevent the jacket body 2 and the sealing body 3 from opening in the main joining process. In the temporary joining step, a rotary tool for temporary joining may be used for friction stir welding, or welding may be performed.

Further, in the closet section and the detachment section, the movement route may be set so that the movement locus of the rotation tool F draws a curve (for example, an arc) in a plan view. As a result, the transition from the closet section to the main section or from the main section to the departure section can be smoothly performed.

1 Liquid-cooled jacket 2 Jacket body 3 Encapsulant 11 Peripheral wall part 12 Peripheral wall stepped part 12a Stepped bottom surface 12b First inclined stepped side surface 12c Second inclined stepped side surface 12b1 First inclined stepped side surface 12c1 Second inclined stepped side surface F Rotating tool F2 End side pin F3 Tip side pin J1 First butt part J2 Second butt part L1 Setting movement route S1 Midpoint S2 Midpoint SP1 Start position SP2 Start position EP1 End position EP2 End position W Plasticization area

Claims (10)

A liquid that is composed of a jacket body having a bottom portion and a peripheral wall portion rising from the peripheral edge of the bottom portion and a sealing body that seals an opening of the jacket body, and joins the jacket body and the sealing body by friction stir welding. It ’s a method of manufacturing cold jackets.
The jacket body is made of a first aluminum alloy, the sealant is made of a second aluminum alloy, and the first aluminum alloy is a grade having a higher hardness than the second aluminum alloy.
The rotary tool used for friction stir welding has a base end side pin and a tip end side pin.
The taper angle of the base end side pin is larger than the taper angle of the tip end side pin, and a stepped step portion is formed on the outer peripheral surface of the base end side pin.
On the inner peripheral edge of the peripheral wall portion, the bottom surface of the step, the side surface of the first inclined step rising so as to spread from the bottom surface of the step toward the opening, and the upper end of the side surface of the first inclined step toward the opening. A peripheral wall step portion having a second inclined step side surface that is inclined and rises so as to further expand is formed, and the plate thickness of the sealing body is set to the height dimension of the first inclined step side surface of the peripheral wall step portion. And the preparatory process to form it to be larger than
By placing the sealing body on the jacket body, the first inclined step side surface of the peripheral wall step portion and the outer peripheral side surface of the sealing body are abutted to form the first abutting portion, and the peripheral wall step portion is formed. The mounting step of forming the second butt portion by superimposing the bottom surface of the step and the back surface of the sealing body,
The tip end side pin of the rotating tool is inserted into the sealing body, and the base end side pin is slightly brought into contact with the first inclined step side surface of the peripheral wall step portion. In a state where the outer peripheral surface of the seal is in contact with the surface of the seal, it goes around the seal at a predetermined depth along a set movement route set inside the outer peripheral side surface of the seal. Including the main joining step of rubbing and stirring the first butt portion.
In the main joining step, after inserting the rotating tip side pin into the start position set further inside the set movement route, the rotation center axis of the rotation tool is moved to a position overlapping the set movement route. A method for manufacturing a liquid-cooled jacket, which comprises gradually pushing in the tip-side pin until the depth reaches a predetermined depth. In the main joining step, the inclination angle of the rotation center axis of the rotation tool with respect to the vertical surface is set to γ while slightly contacting the outer peripheral surface of the base end side pin with the side surface of the second inclined step portion of the peripheral wall step portion. The inclination angle of the first inclined step side surface with respect to the vertical surface is β, the inclination angle of the second inclined step side surface with respect to the vertical surface is β ′, and the inclination angle of the outer peripheral surface of the tip end side pin with respect to the rotation center axis is α. Assuming that the inclination angle of the outer peripheral surface of the base end side pin with respect to the rotation center axis is α', the friction stirring joint is performed in a state where γ = α-β and γ = α'-β'. The method for manufacturing a liquid-cooled jacket according to claim 1. The liquid according to claim 1 or 2, wherein the predetermined depth of the main joining step is set at a position where the tip end side pin slightly contacts the step bottom surface of the peripheral wall step portion. How to make a cold jacket. In the main joining step, the tip side pin is rotated at a predetermined rotation speed to perform friction stir welding.
When the tip side pin is inserted in the main joining step, the tip side pin is inserted in a state of being rotated at a speed higher than the predetermined rotation speed, and the tip side pin is moved to the set movement route while gradually reducing the rotation speed. The method for manufacturing a liquid-cooled jacket according to any one of claims 1 to 3, wherein the liquid-cooled jacket is made to rotate. A liquid that is composed of a jacket body having a bottom portion and a peripheral wall portion rising from the peripheral edge of the bottom portion and a sealing body that seals an opening of the jacket body, and joins the jacket body and the sealing body by friction stir welding. It ’s a method of manufacturing cold jackets.
The jacket body is made of a first aluminum alloy, the sealant is made of a second aluminum alloy, and the first aluminum alloy is a grade having a higher hardness than the second aluminum alloy.
The rotary tool used for friction stir welding has a base end side pin and a tip end side pin.
The taper angle of the base end side pin is larger than the taper angle of the tip end side pin, and a stepped step portion is formed on the outer peripheral surface of the base end side pin.
On the inner peripheral edge of the peripheral wall portion, the bottom surface of the step, the side surface of the first inclined step rising so as to spread from the bottom surface of the step toward the opening, and the upper end of the side surface of the first inclined step toward the opening. A peripheral wall step portion having a second inclined step side surface that is inclined and rises so as to further expand is formed, and the plate thickness of the sealing body is set to the height dimension of the first inclined step side surface of the peripheral wall step portion. And the preparatory process to form it to be larger than
By placing the sealing body on the jacket body, the first inclined step side surface of the peripheral wall step portion and the outer peripheral side surface of the sealing body are abutted to form the first abutting portion, and the peripheral wall step portion is formed. The mounting step of forming the second butt portion by superimposing the bottom surface of the step and the back surface of the sealing body,
The tip end side pin of the rotating tool is inserted into the sealing body, and the base end side pin is slightly brought into contact with the first inclined step side surface of the peripheral wall step portion. In a state where the outer peripheral surface of the seal is in contact with the surface of the seal, it goes around the seal at a predetermined depth along a set movement route set inside the outer peripheral side surface of the seal. Including the main joining step of rubbing and stirring the first butt portion.
In the main joining step, the tip side pin is inserted from a start position set on the set movement route, and the tip side pin is gradually pushed in until the predetermined depth is reached while moving in the traveling direction. How to manufacture a liquid-cooled jacket. In the main joining step, the inclination angle of the rotation center axis of the rotation tool with respect to the vertical surface is set to γ while slightly contacting the outer peripheral surface of the base end side pin with the side surface of the second inclined step portion of the peripheral wall step portion. The inclination angle of the first inclined step side surface with respect to the vertical surface is β, the inclination angle of the second inclined step side surface with respect to the vertical surface is β ′, and the inclination angle of the outer peripheral surface of the tip end side pin with respect to the rotation center axis is α. Assuming that the inclination angle of the outer peripheral surface of the base end side pin with respect to the rotation center axis is α', the friction stirring joint is performed in a state where γ = α-β and γ = α'-β'. The method for manufacturing a liquid-cooled jacket according to claim 5. The liquid according to claim 5 or 6, wherein the predetermined depth of the main joining step is set at a position where the tip end side pin slightly contacts the step bottom surface of the peripheral wall step portion. How to make a cold jacket. In the main joining step, the tip side pin is rotated at a predetermined rotation speed to perform friction stir welding.
The insertion step of the main joining step is characterized in that the tip side pin is inserted in a state of being rotated at a speed higher than the predetermined rotation speed, and the rotation tool is pushed in while gradually reducing the rotation speed. The method for manufacturing a liquid-cooled jacket according to any one of claims 5 to 7. The method according to any one of claims 1 to 8, wherein in the preparatory step, the jacket body is die-cast and at least the sealed body is formed so as to be convex toward the surface side. How to make a liquid-cooled jacket. The method for manufacturing a liquid-cooled jacket according to any one of claims 1 to 9, further comprising a temporary joining step of temporarily joining the first butt portion prior to the main joining step.

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