JP2006239720A - Method for joining different kind of metallic member - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for joining different kinds of metallic members, which can effectively enhance soundness of a weld zone without considering any fear for galvanic corrosion. <P>SOLUTION: When an Al plate 2 and a steel plate 4 are superposed on each other, a probe 16 coaxially positioned at the tip end of the shoulder member 14 of a rotary tool 10 is rotatably inserted from the Al plate 2 side in a manner that the tip end reaches directly above the steel plate 4, and is then friction-stirred to join the Al plate 2 and the steel plate 4 together, as the rotary tool 10, the probe 16 is constituted as a separate body from the shoulder member 14 and, using a double-acting rotary tool made separately movable in the axial direction, the probe 16 is inserted into the Al plate 2 to perform the friction stir welding of the Al plate and the steel plate 4. Thereafter, the probe 16 is withdrawn from the friction stirring section 18 formed in the Al plate 2, while a probe hole caused by such withdrawing is buried through the flow of the material from other parts of the friction stirring section 18. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for joining dissimilar metal members, and in particular, when plate-like portions of two metal members having different materials and different hardnesses are overlapped and the overlapped portions are joined, It relates to a technology that can improve the performance.

  In recent years, from the viewpoint of protecting the global environment and saving energy, there has been a demand for suppression of generation of harmful gases and carbon dioxide emitted from automobiles, improvement of fuel consumption, and the like. And in order to meet such a demand, since the weight reduction of an automobile is the most effective, in the body member and various parts, the conversion of the material from a steel material to an aluminum material is actively studied. However, it is difficult in terms of cost to make all the materials of the body members and various parts constituting the automobile into an aluminum material. For this reason, when using an aluminum material, the dissimilar metal between steel and aluminum is used. This so-called hybrid joining is inevitable, and this dissimilar metal joining is an important issue.

  In addition, the joining between different kinds of metal members such as aluminum and steel is requested not only in the field of transport equipment represented by automobiles as described above, but also in various fields such as home appliances and structures such as building materials. There, there is a demand for strong bonding. Furthermore, not only aluminum materials but also strong metal bonding is required in the dissimilar metal bonding between a material made of a soft metal such as a copper material and a material made of a hard metal such as steel.

By the way, when an aluminum material and an iron material such as steel are joined by a fusion welding method generally used in joining metal materials, each metal is melted at the time of joining, and the joining interface is formed. There is a problem that brittle and hard intermetallic compounds (Fe ₂ Al ₅ , FeAl _3, etc.) are generated, and this reduces the bonding strength. For this reason, in dissimilar metal joining, various joining methods such as mechanical joining such as caulking, rivet joining, and bolt joining, explosive bonding, adhesion, and rotary friction welding have been studied in order to ensure sufficient joining strength. However, any of these methods has some or more problems inherently in practical use in terms of workability of joining, reliability of joints, design properties, joining costs, etc. .

  Therefore, the applicant of the present application previously disclosed in Patent Document 1 a friction stir welding method (Friction Stir Welding) in which solid heat joining is performed in a state where the heat input at the time of joining is small and the material to be joined is plastically fluidized without melting. ) Proposed a method of joining a soft aluminum material and a hard steel member. More specifically, on a hard backing member, a soft aluminum material and a steel material to be joined are superimposed and restrained so that the aluminum material is on top, Insert a pin-shaped hard probe that protrudes from the shoulder surface of a rod-shaped rotary tool rotated at high speed around the axis until the shoulder surface touches the surface of the aluminum material and the tip of the probe does not touch the hard steel material. Then, a method of joining the aluminum material and the steel material by agitating the aluminum material plastically fluidized by the frictional heat with a hard probe and generating an intermetallic compound was proposed. Advantageously suppresses or prevents the occurrence of steel, and ensures a secure joint between aluminum and steel, and advantageously improves the joint strength by tensile shear (joint strength). It was revealed Rukoto.

  However, in the joining material (joint) to be joined by such a friction stir welding method, the tool body and the probe that give the shoulder surface of the rotary tool have an integral structure. When the rotary tool is pulled out from the joint after the friction stir welding operation is completed, a hole corresponding to the probe of the rotary tool remains in the joint (friction stirrer) and opens on the surface, and In addition, the presence of such a hole indicating a probe mark inherently causes a problem of corrosion at the bottom of the hole in addition to causing a problem of liquid accumulation in coating of the obtained bonding material. . That is, in the friction stir welding between the aluminum material and the steel material, the probe of the rotary tool inserted from the aluminum material side causes the friction stir action so that the tip reaches a position close to the surface of the steel material. The friction stir zone is formed so that the steel material and the steel material can be joined with a sufficient joint strength. In this case, the interface between the aluminum material and the steel material, in particular the oxide present on the steel material surface, Fe metal components, Zn plating, etc. may be exposed to the surface of the bottom of the probe hole without being caught in the friction stirrer. In that case, if water enters the probe hole, aluminum and aluminum of them There was a risk of contact corrosion between different metals, so-called galvanic corrosion (electrical corrosion). .

  Also in Patent Document 2, a method of friction stir welding of dissimilar metal materials is proposed, in which the probe of the friction stir jig is penetrated from the low melting point material side to the high melting point material side. Although the method of inserting the tip has been clarified, since the probe is usually made of steel, when this method is applied to the joining of aluminum and steel, the probe is made of steel. There is a problem that the life of the jig is extremely shortened.

  On the other hand, the applicant of the present application in Patent Document 3, press-fitting a press-fit probe separate from the rotary tool main body into a plurality of stacked aluminum materials while rotating and friction-stirring the press-fit probe. Clarified the point joining method of aluminum material by pulling out the probe and embedding the press-fitting hole (probe) with the material from other places so that the press-fitting hole of the press-fitted probe does not remain in the joint part. However, only a method for spot-joining a plurality of aluminum materials by a friction stir welding method has been clarified.

JP 2003-275876 A JP 2003-170280 A JP 2001-259863 A

  Here, the present invention has been made in the background of such circumstances, and the problem to be solved is to superimpose plate-like portions of a plurality of metal materials having different materials and different hardnesses. It is an object of the present invention to provide a method for joining dissimilar metal members that can effectively improve the soundness of a joined portion without considering any concern about galvanic corrosion when the overlapped portions are friction stir joined.

  In the present invention, in order to solve the above-described problem, the first member made of a soft metal and the second member made of a hard metal are overlapped, and the first member side is rotated around the axis. The probe, which is coaxially positioned at the tip of the shoulder member of the rotary tool that is rotated to the right, is inserted while being rotated so that the tip reaches directly above the second member, and is agitated by friction. When the second member is joined, a double-acting rotary tool in which the probe is configured separately from the shoulder member and separately movable in the axial direction is used as the rotary tool. After inserting into the first member and performing friction stir welding of the first and second members, the probe is pulled out from the friction stirrer formed on the first member, and is generated by such pulling out. The lobe hole, by the flow of material from other parts of the friction stir portion, the joining method of dissimilar metal members, characterized in that so as to fill, it is an gist thereof.

  According to such a joining method of dissimilar metal members according to the present invention, the double-acting rotary tool is used as the rotary tool, and the probe is movable in the axial direction separately from the shoulder member. After performing solid phase bonding by friction stir action between the member and the second member, the probe is pulled out, and the resulting probe hole is embedded by the flow of material from the other part of the formed friction stirrer. Therefore, when the probe hole is embedded, at the bottom of such a probe hole, the interface between the first member and the second member, particularly the surface of the second member Even if the metal component of the oxide and the metal component of the second member, and the surface processing component, etc. are present, they are embedded by the material flowing from the other part of the friction stirrer and Even if the first member side may come into contact with water from the point where it is not exposed, a battery is formed between the first member and the metal component, and galvanic corrosion occurs. There is no such concern.

  Therefore, in the present invention, the problem of galvanic corrosion is effectively eliminated in addition to avoiding problems such as coating liquid pooling in the obtained dissimilar metal joining material from where the probe hole does not remain. As a result, the quality of the friction stir welded portion can be improved, and the soundness can be advantageously increased.

Aspects of the Invention

  By the way, the present invention can be suitably implemented in various aspects as listed below, but can also be realized in various aspects that can be conceived by those skilled in the art based on the following description. Is possible.

(1) A first member made of a soft metal and a second member made of a hard metal are superposed on each other, and coaxially formed from the first member side to the tip of a shoulder member of a rotary tool rotated around an axis. When the probe positioned is rotated and inserted so that the tip of the probe reaches just above the second member, the first member is frictionally stirred, and when the first and second members are joined, As the rotary tool, a double-acting rotary tool in which the probe is configured separately from the shoulder member and separately movable in the axial direction, the probe is inserted into the first member, After performing the friction stir welding of the first and second members, the probe is pulled out of the friction stirrer formed on the first member, while the probe hole generated by the pulling is removed from the friction stirrer. other By the flow of material from the position, the joining method of dissimilar metal members, characterized in that so as to fill.

(2) The burr suppression cylinder is extrapolated to the outer peripheral surface of the shoulder member and brought into contact with the surface of the first member, thereby suppressing or preventing the generation of burrs around the shoulder member. The joining method of the dissimilar-metal member as described in aspect (1) which has come to be obtained.
According to such an embodiment, the presence of the burr suppression cylinder can effectively suppress or prevent the burr generated by being pushed out of the friction stirrer around the shoulder member when the probe is inserted. In addition, since the material to be pushed out can be pushed into the friction stirrer by the contact of the burr suppressing cylinder, the oxide and its metal component present on the surface of the second member can be removed. From the point where the plastic flow along the interface of the friction stirrer to the surface of the first member is effectively prevented and can be stopped in the friction stirrer. The concern that galvanic corrosion is caused based on the metal component on the surface of the second member that has been moved through can be effectively eliminated.

(3) In the aspect (1) or the aspect (2), the distance between the second member and the tip of the probe is a value from 10 μm to 20% of the thickness of the first member. The joining method of the dissimilar metal member of description.
According to such an aspect, by regulating the distance between the surface of the second member and the tip of the probe protruding from the rotary tool, the tip of the probe is positioned immediately above the surface of the second member. , Only the first member can be agitated to effectively provide a new surface at the interface between the first member and the second member, thereby advantageously increasing the bonding strength of the members and The variation in the quality of the parts can be effectively eliminated.

(4) While the shoulder member is moved in the axial direction by position control with respect to the first member, the insertion depth of the probe is controlled based on the insertion load (1) ) To the dissimilar metal member joining method according to any one of aspects (3).
According to such an aspect, the axial movement of the shoulder member is performed by position control, while the insertion depth of the probe is controlled based on the insertion load, thereby controlling the axial movement of the shoulder member and the probe. Therefore, even when the thickness of the first member is changed, it can be advantageously coped with.

(5) The method for joining dissimilar metal members according to any one of aspects (1) to (4), wherein the first member is made of aluminum, and the second member is made of iron.

(6) A dissimilar metal bonding material formed by bonding a first member made of a soft metal and a second member made of a hard metal, and is described in any one of modes (1) to (5) A dissimilar metal bonding material characterized by being bonded by the above method.

  Hereinafter, in order to clarify the present invention more specifically, representative embodiments of the present invention will be described in detail with reference to the drawings.

  First, in FIG. 1, two metal plates 2 and 4 having different materials and different hardness, which are point-bonded according to the present invention, are arranged in a state of being overlapped in the vertical direction. And these two metal plates 2 and 4 are clamped to a fixed position in the same manner as in the past for the purpose of friction stir spot joining, and on the back surface of the lower metal plate 4 Although not shown, a backing jig is arranged to support the two metal plates 2 and 4.

  The metal plate 2 positioned on the upper side of the two metal plates 2 and 4 is a first member, and is made of various metal materials such as aluminum, aluminum alloy, copper, and copper alloy. Among these, a metal plate made of a relatively soft material, while the lower metal plate 4 is a second member, for example, a hard metal such as steel or iron made of iron or an alloy thereof. A metal plate made of Among them, the upper metal plate 2 is preferably made of an aluminum material, and the lower metal plate 4 is preferably made of an iron material. Thus, the technique of the present invention is advantageously applied.

  On the other hand, a steel double-acting rotary tool 10 similar to the conventional one is placed on the upper side of the two metal plates 2 and 4, in other words, on the metal plate 2 side. It has been. The rotary tool 10 includes a shoulder member 14 which is a cylindrical tool body having a shoulder surface 12 on the bottom surface, and a rod (column) probe 16 which is inserted and positioned in the center hole thereof. The member 14 and the probe 16 can be rotated at high speed around their axes, and can be moved independently in their axial directions. In the double-action structure, the shoulder member 14 and the probe 16 can be actuated. Note that at least portions of the probe 16 and the shoulder member 14 that are in contact with or pressed against the upper metal plate 2 and are inserted are formed of a material harder than the metal plate 2, and wear and tear thereof are reduced. It is to be prevented.

  When joining the two metal plates 2 and 4 by the friction stir welding method according to the present invention, first, the probe 16 is made of a soft metal while rotating the rotary tool 10 at a high speed. Is inserted from the upper metal plate 2 side. At that time, the shoulder member 14 and the probe 16 constituting the rotary tool 10 can be rotated independently, or can be rotated independently of each other. Further, in the state where the tip of the probe 16 is drawn into the shoulder member 14 so that the tip of the probe 16 is substantially flush with the shoulder surface 12, the shoulder surface 12 on the lower surface of the rotary tool 10, specifically the shoulder member 14, is a metal plate. 2 is lightly pressed against the surface and caused to generate frictional heat, while the probe 16 is protruded from the shoulder member 14 and inserted into the metal plate 2, and the tip thereof is a second member made of hard metal. It reaches right above the lower metal plate 4. FIG. 2 shows a state in which such a probe 16 has reached directly above the metal plate 4.

  In this way, in a state where the probe 16 is flush with the shoulder member 14, the friction stir welding is started by abutting against the surface of the upper metal plate 2 to effectively generate the initial burrs. It is possible to enjoy the advantages that can be suppressed or prevented, but, of course, the operation method is not limited to such an operation method, and various known double-acting rotary tool operation methods are appropriately employed. For example, the probe 16 can be inserted into the upper metal plate 2 in a state where the probe 16 protrudes from the shoulder member 14.

  Further, as shown in FIG. 2, the probe 16 is moved below the shoulder surface 12 by the friction stir action caused by the contact of the shoulder surface 12 and the insertion of the probe 16 under the high-speed rotation of the rotary tool 10 as shown in FIG. The friction stirrer 18 formed by stirring only the material of the upper metal plate 2 is formed around this, and the friction stirrer 18 comes into contact with the new surface of the lower metal plate 4 to thereby form two sheets. Thus, the friction stir welding of the metal plates 2 and 4 is realized.

  In such a friction stir welding operation, if the rotary tool 10 (specifically, the probe 16) is inserted too much into the overlapping portion of the two metal plates 2 and 4, the tip of the probe 16. May come into contact with the lower metal plate 4, which is the second member made of hard metal, and wear, while if the insertion depth is too shallow, the interface between the two metal plates 2, 4 The distance d between the tip of the probe 16 and the lower metal plate 4 is generally 10 μm or more because stirring is insufficient and it is difficult to ensure sufficient bonding strength (joint strength). It is desirable that the rotary tool 10 is inserted so that the thickness of the upper metal plate 2 is 20% or less.

  Next, the rotary tool 10 is detached from the state where the friction stir welding shown in FIG. 2 is completed. At this time, simply pulling the rotary tool 10 away from the friction stirrer 18 causes the probe 16 to move away. Since the hole (probe hole) that has been left remains in the friction stirrer 18 as it is, and the problems such as the concern of galvanic corrosion as described above become inherent in the present invention, in the present invention, for example, FIG. 3, the probe 16 constituting the rotary tool 10 is moved upward in the axial direction to be pulled out from the friction stirrer 18, while the shoulder member 14 is moved downward in the axial direction so that the shoulder surface 12, the upper surface of the friction stirrer 18 is pressed and pushed in, so that holes generated by pulling out the probe 16 are By the flow of material from the site, it is to be embedded.

  In addition, as a specific embedding operation of the hole generated by pulling out the probe 16, the shoulder member 14 is lowered (pushed) simultaneously with the raising (pulling) of the probe 16, and a little delayed from the start of the former raising. An operation such as starting the lowering of the latter or starting the lowering of the latter after completion of the former can be appropriately adopted, and the rotary tool 10 is detached from the friction stirrer 18. It is also possible to apply a pressing operation with an appropriate pressing member to cause the material to flow from other parts of the friction stirrer 18 so that the probe hole is embedded.

  Then, when the rotary tool 10 is detached from the joint portion (friction stirrer 18) of the two metal plates 2 and 4 and the probe hole is embedded, as shown in FIG. In other words, the hole formed by the probe 16 is substantially lost. However, such a probe hole need not be completely erased to the extent that a trace remains or cannot be confirmed, so that the bottom at the maximum depth at which the probe 16 is inserted is sufficiently covered. As long as it is embedded with a material that can be caused to flow from other parts of the friction stirrer 18, there is no problem even if it exists as a hole having a certain depth.

  In this way, the hole generated by pulling out the probe 16 from the friction stirrer 18 is embedded at the bottom of the probe hole by being buried by the flow of material from other parts of the friction stirrer 18, particularly the peripheral part. The oxide on the surface of the lower metal plate 4 and the metal components thereof are covered with the material of the friction stirrer 18 and are held in the interior, so that they are exposed on the surface. Therefore, even in the case where water is present on the surface of the friction stirrer 18, the galvanic battery is formed by the battery configured between the material of the upper metal plate 2 constituting the friction stirrer 18. The concern that the corrosion phenomenon is caused can be avoided at all, and therefore the soundness of the friction stir welded portion (18), and hence the reliability, can be advantageously improved.

  Further, the probe hole which is the extraction hole of the probe 16 is embedded, and as shown in FIG. 4, the probe hole is not substantially present on the surface of the friction stirrer 18. The problem of the liquid pool was also effectively solved, thereby contributing to the improvement of the soundness of the joint portion, and the design property of the surface of the joint portion could be advantageously improved.

  By the way, the present invention can be advantageously implemented in the above-described embodiment and also in the embodiment shown in FIG.

  In the joining step by the friction stir method shown in FIG. 5, a cylindrical burr suppression cylinder 20 is extrapolated and arranged on the outer peripheral surface of the shoulder member 14 of the rotary tool 10, and this burr suppression cylinder is arranged. When the body 20 is lowered, the two metal plates 2 and 4 that are superposed and supported by the backing jig 22 can be pressed from above.

  In the friction stir welding operation, the burr suppression cylinder 20 is lowered simultaneously with or before the lowering of the shoulder member 14 and the probe 16 of the rotary tool 10, and the surface of the upper metal plate 2. To be pressed. Next, the rotary tool 10 is lowered and the same friction stir welding operation as in the previous example is performed. At that time, the friction surface is formed by the friction stir action of the shoulder surface 12 of the shoulder member 14 and the probe 16. The burr overflowing from the friction stirrer 18 is prevented by the presence of the burr suppressing cylinder 12. However, the shoulder member 14 is prevented during the friction agitation operation so that the overflow of the burr is prevented and the increase in the volume of the friction agitation unit 18 due to being blocked by the friction agitation unit 18 can be absorbed. It is designed to be slightly retracted (raised). The burr suppressing cylinder 20 is pressed by a spring or the like without being rotated and having a pressing force such that the burr does not enter between the upper metal plate 2.

  When the friction stir operation by the rotary tool 10 is finished, the probe 16 is pulled out (ascended) and pushed down by the shoulder member 14 being lowered, so that the pull-out hole of the probe 16 is removed from other parts of the friction stirrer 18. Then, it is made to be embedded by the flow of the material, and thereafter, the pressure against the metal plate 2 of the burr suppressing cylinder 20 is released, and the friction stir welding of the target metal plates 2 and 4 is performed. It is realized.

  In this manner, the burr suppressing cylinder 20 is disposed around the shoulder member 14 of the rotary tool 10 to suppress burrs generated around the outer peripheral portion of the shoulder member 14, in other words, the outer peripheral portion of the shoulder surface 12. As a result, the oxide existing on the surface of the lower metal plate 4 moving along the interface between the friction stirrer 18 and the upper metal plate 2 on which it is formed and the metal components of the metal plate 4 itself are present. Since the plastic flow is prevented from reaching the surface of the upper metal plate 2 and is prevented from being pushed into the friction stirrer 18, the metal component of the metal plate 4 existing at the interface is the metal plate. Concerns that cause galvanic corrosion with 2 can also be effectively eliminated.

  Further, when the dissimilar metal member joining method according to the present invention is carried out, for example, as shown in FIG. 6, the operation of the probe driving device 32 and the shoulder member driving device 34 is controlled by the control device 30, and the probe 16 or By controlling the rotation of the shoulder member 14 and the amount of movement in the axial direction of the shoulder member 14, the shoulder member 14 is inserted into the overlapping portion of the metal plates 2, 4 so that an effective friction stirring portion 18 in the upper metal plate 2 can be formed. It is. Here, any of the probe driving device 32 and the shoulder member driving device 34 may independently have a rotation function and an axial movement function, and either one of them, For example, only the shoulder member driving device 34 may have a rotation function and an axial movement function, and the probe driving device 32 may have only an axial movement function. The operation of the probe driving device 32 and the shoulder member driving device 34 is based on the load acting on the probe 16 and the shoulder member 14 (shoulder surface 12), and the metal plates 2, 4 of the probe 16 and the shoulder member 14 are also used. Based on the positional relationship with respect to, the control device 30 can perform load control or position control.

  Specifically, the load control by the control device 30 is performed based on the load (pressure) from the upper metal plate 2 or the friction stirrer 18 acting on the shoulder surface 12 of the shoulder member 14, and to the metal plate 2. Based on the load (pressure) that rises as the tip of the inserted probe 16 approaches the surface of the lower metal plate 4, the tip positions of the shoulder member 14 and the probe 16 are controlled by the control device 30. In the position control, the thicknesses of the two metal plates 2 and 4 are input to the control device 30 by an input device (not shown), and the two metal plates 2 and 4 are controlled. While the tip positions of the shoulder member 14 and the probe 16 are controlled by the control device 30, the shoulder surface 12 of the shoulder member 14 is pressed against the surface of the upper metal plate 2. End of the probe 16, protrude is actuated so as to be positioned directly above the lower side of the metal plate 4, in the metal plate 2 is valid friction stir portion 18 is formed.

  Such a control device 30 controls the amount of axial movement of the probe 16 and the shoulder member 14, respectively, so that the quality can be stabilized even when the thickness of the metal plates 2 and 4 to be joined changes. Thus, it is possible to ensure the joined state. In particular, since the distance (d) between the tip of the probe 16 and the lower metal plate 4 can be accurately maintained, the problem of contact with the lower metal plate 4 due to excessive insertion of the probe 16, and thus The problem of wear of the probe tip, the problem of a decrease in the joint strength due to insufficient stirring of the interface between the two metal plates 2 and 4 due to insufficient insertion, etc., can be solved. .

  In addition, the control of the axial movement amount of the probe 16 and the shoulder member 14 by the control device 30 as described above is not limited to the case where either of them is performed by either position control or load control. It is possible to set one side as position control and the other as load control. Further, it is possible to control the amount of axial movement of the shoulder member 14 or the probe 16 by combining position control and load control. It is. Among them, the shoulder member 14 is moved in the axial direction by position control based on the position of the upper metal plate 2, while the insertion depth of the probe 16 is controlled based on the insertion load. This is desirable, and even when the thickness of the upper metal plate 2 changes, it is possible to cope with it advantageously. It is also desirable that the axial movement of the shoulder member 14 is position control in the initial stage of friction stirring, while load control is performed in the second half of the friction stirring operation.

  The exemplary embodiments of the present invention have been described in detail above. However, the embodiments are merely examples, and the present invention is limited in any way by specific descriptions according to such embodiments. It should be understood that it is not interpreted.

  For example, in the above-described embodiment, the point joining method to which the present invention is advantageously applied is adopted as the friction stir welding method. However, the rotary tool 10 is moved relative to the metal plates 2 and 4 to some extent. Thus, the present invention can also be applied to a method in which friction stir welding is performed.

  Moreover, although the example of using the metal plates 2 and 4 which are plate materials is demonstrated as the 1st and 2nd members (to-be-joined material) which should be joined, although this invention is made | formed, The shape of the material to be joined is not limited to the plate material, as long as the overlapping portions subjected to the friction stir welding operation such as friction stir spot welding are respectively plate-shaped or face plate-shaped, Any member can be employed.

  Furthermore, as the rotary tool 10, various known double-acting rotary tools can be used as appropriate. Even if the probe 16 has the shape or structure, it is not only a straight cylindrical shape but also toward the tip. Any of various known shapes such as a tapered cone shape and a truncated cone shape can be adopted, and even if the surface is provided with protrusions, ridges, grooves, etc. There is no problem. Moreover, even if it is in the shape of the shoulder surface 12 of the end surface of the shoulder member 14, it is not specifically limited, Even if it is a flat surface, it may be the concave surface shape curved toward the center, and it is well-known conventionally. The shape is appropriately adopted.

  In addition, although not enumerated one by one, the present invention is carried out in a mode to which various changes, modifications, improvements, etc. are added based on the knowledge of those skilled in the art. It goes without saying that any one of them falls within the scope of the present invention without departing from the spirit of the present invention.

  First, as a first member (2) made of a soft metal, a 6000 series aluminum plate material (6016-T4) having a thickness of 1 mm is prepared, while as a second member (4) made of a hard metal, the thickness: A 1 mm steel plate (SPCC) was prepared.

  Next, the aluminum plate (2) and the steel plate (4) are overlapped, and a ring-shaped steel clamp as a burr suppressing cylinder (20) as shown in FIG. 5 is extrapolated from the aluminum plate side. Using the rotary tool 10, a friction stir welding operation according to the present invention was performed.

  Specifically, in a state in which the backing jig (22) is in contact with and supported by the back surface of the steel plate (4) on the lower plate side of the stacked aluminum plate (2) and steel plate (4). Using a double-acting rotary tool (10), first, a ring-shaped steel clamp (outer diameter: 16 mm, inner diameter: 10 mm) is brought into contact with the upper surface of the aluminum plate (2) on the upper plate side, and then In the state where the shoulder member (14) having an outer diameter of 10 mm and the probe (16) having an outer diameter of 4 mm are flush with each other and rotated at high speed in the same direction, the aluminum plate (2) After that, the probe (16) was inserted to a position of 100 μm immediately above the steel plate (4), and stirred by friction to form a friction stirring part (18) as shown in FIG.

  Next, after the friction stir welding operation, the probe (16) is pulled out from the friction stirrer 18, and at the same time, the shoulder member 14 is lowered to push in the friction stirrer 18, and the probe (16) An aluminum plate-steel plate joining material having a flat joint surface in which a probe withdrawal hole does not substantially remain on the surface of the friction stir joint (18) by embedding holes generated by the drawing by the flow of the material. I was able to get.

  In the friction stir welding operation described above, the axial movement of the shoulder member (14) is controlled based on the position information of the surface of the aluminum plate (2) on the backing jig (22), The insertion depth of the probe (16) was controlled based on the insertion load.

  In such a friction stir welding operation, the ring-shaped steel clamp as the burr suppressing cylinder (20) suppresses the generation of burrs on the outer periphery of the shoulder member (14). A friction stir spot bonding material in which no minute was exposed on the surface could be obtained. Further, it was recognized that the joint had a surface roughness of 0.05 mm or less and the back surface was a substantially flat and healthy one. Further, when the joint was subjected to a shear tensile test, it was confirmed that the joint had a breaking strength of 2.5 KN and had excellent joint strength.

It is sectional explanatory drawing which shows one state before joining operation of the joining method of the dissimilar metal member according to this invention. It is sectional explanatory drawing which shows 1 process of the friction stirring process in the joining method of the dissimilar metal member according to this invention, and its partial enlarged view. It is a section explanatory view showing the state after moving a shoulder member and a probe after friction stir welding in a joining method of dissimilar metal members according to the present invention. In the joining method of the dissimilar metal member according to the present invention, it is a section explanatory view showing the state where the rotary tool was detached from the joined first and second members. It is sectional explanatory drawing equivalent to FIG. 2 using the different thing of the rotary tool used in the joining method of the dissimilar metal member according to this invention. It is explanatory drawing which shows an example of the operation control of the probe and shoulder member of a rotary tool.

Explanation of symbols

2 Metal plate (first member) 4 Metal plate (second member)
DESCRIPTION OF SYMBOLS 10 Rotating tool 12 Shoulder surface 14 Shoulder member 16 Probe 18 Friction stirring part 20 Burr suppression cylinder 22 Backing jig 30 Control device 32 Probe drive device 34 Shoulder member drive device

Claims (6)

The first member made of a soft metal and the second member made of a hard metal were overlapped and positioned coaxially from the first member side to the tip of the shoulder member of the rotary tool that can be rotated around the axis. While rotating the probe, the tip of the probe reaches just above the second member, and friction stir to join the first and second members,
As the rotary tool, a double-acting rotary tool in which the probe is configured separately from the shoulder member and separately movable in the axial direction, the probe is inserted into the first member, After performing the friction stir welding of the first and second members, the probe is pulled out of the friction stirrer formed on the first member, while the probe hole generated by the pulling is removed from the friction stirrer. A method for joining dissimilar metal members, wherein the material is embedded by the flow of a material from another part.   As a burr suppression cylinder is extrapolated to the outer peripheral surface of the shoulder member and brought into contact with the surface of the first member, the generation of burrs around the shoulder member can be suppressed or prevented. The joining method for dissimilar metal members according to claim 1.   3. The dissimilar metal member according to claim 1, wherein a distance between the second member and the tip of the probe is a value from 10 μm to 20% of a thickness of the first member. Joining method.   The said shoulder member is moved to an axial direction by position control with respect to said 1st member, On the other hand, the insertion depth of the said probe is controlled based on an insertion load. 4. The method for joining dissimilar metal members according to any one of 3 above.   5. The method for joining dissimilar metal members according to claim 1, wherein the first member is made of aluminum, and the second member is made of iron. 6. A dissimilar metal bonding material formed by bonding a first member made of a soft metal and a second member made of a hard metal, which is bonded by the method according to any one of claims 1 to 5. Dissimilar metal bonding material characterized by comprising.

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