JP6233561B2 - Flux transfer tape - Google Patents

Description

  The present invention relates to a technique for mounting an electronic component on a substrate, and more particularly, to a mounting technology for mounting an electronic component on a substrate after transferring a flux to a plurality of bumps provided on the electronic component.

  As a mounting technique, a surface mounting technology (SMT: Surface Mount Technology) for mounting electronic components on the surface of a substrate has been widely used. As one of the surface mounting techniques, there is a technique for soldering an electronic component to a land electrode provided on a surface of a substrate by melting a plurality of bumps provided on the electronic component.

  In such mounting technology, the mounting of electronic components on a board after transferring paste-like flux to the bumps so that an excellent electrical connection between the bump and the land electrode can be obtained. Technology (for example, see Patent Document 1 or 2) is used.

  As an example, first, a flux coating film is formed on the surface of the transfer stage by stretching a paste-like flux using a squeegee. At this time, the thickness of the coating film is adjusted by adjusting the size of the gap provided between the transfer stage and the squeegee according to the viscosity of the paste. Next, the flux is transferred to the bumps by landing a plurality of bumps provided on the electronic component on the flux coating film. After the transfer, the flux on the transfer stage is scraped by sliding the squeegee with the squeegee in contact with the surface of the transfer stage. Then, a flux coating film is formed again. As described above, in the conventional transfer technology, a paste-like flux is repeatedly used.

JP 2011-139085 A JP 2007-305726 A

  However, the conventional transfer technology using paste-like flux tends to increase the viscosity of the paste. One possible cause is that the solvent in the paste volatilizes. Further, when the paste is a solder paste containing solder powder, the progress of the solidification reaction of the flux due to tin (Sn) in the solder is considered as one of the causes of increasing the viscosity. Furthermore, when the flux is a thermosetting flux, the progress of curing of the flux is considered as one of the causes of the increase in viscosity. Such an increase in viscosity makes it difficult to adjust the film thickness when forming the flux coating film.

  Further, when the viscosity of the paste becomes excessively high, it becomes difficult to form a flux coating film. In this case, it is necessary to temporarily stop the mounting line, and to clean the transfer stage and replace the paste-like flux, which hinders continuous operation of the mounting line. In addition, when the flux is solidified, it becomes very difficult to remove it by washing or the like.

  Accordingly, an object of the present invention is to provide a flux transfer tape that facilitates handling of the flux used for transfer.

The tape for flux transfer according to the present invention includes a tape substrate and a flux film formed on the surface of the tape substrate. The flux film is a film including a solid flux layer formed from a flux, and spreads in a strip shape in the longitudinal direction of the tape base material. And the width | variety of a tape base material is larger than the width | variety of a flux film. Specifically, on the surface of the tape base material, two regions each including both side edges of the tape base material where the flux film is not formed are provided, and the formation region of the flux film is sandwiched between the two regions. ing. A plurality of through holes for engaging the sprocket pins are formed in at least one of the two regions.

  The flux transfer tape according to the present invention facilitates handling of the flux used for transfer.

It is a perspective view of the tape for flux transfer concerning the embodiment of the present invention. It is sectional drawing of the tape for flux transfer. It is a top view of the electronic component mounting apparatus in which the tape for flux transfer concerning this invention is used. It is explanatory drawing of the flux supply part with which an electronic component mounting apparatus is provided. FIG. 5 is a detailed view of a V region shown in FIG. 4. FIG. 5 is a detailed view of a VI area shown in FIG. 4. It is explanatory drawing of the transcription | transfer process performed with the electronic component mounting method.

First, the flux transfer tape according to the present invention will be described.
The tape for flux transfer according to the present invention includes a tape substrate and a flux film formed on the surface of the tape substrate. The flux film is a film including a solid flux layer formed from a flux, and spreads in a strip shape in the longitudinal direction of the tape base material. And the width | variety of a tape base material is larger than the width | variety of a flux film. The solid flux layer is solidified at room temperature, and includes components such as a film forming material.

  According to the flux transfer tape of the present invention, even when the solid flux layer is softened and has fluidity, the flux does not easily fall off from the surface of the tape substrate. Accordingly, it is possible to reduce the frequency of cleaning the flux supply device and the electronic component mounting device in which the flux transfer tape is used, and as a result, the mounting line can be continuously operated over a long period of time, and the running cost is reduced. Will be. Therefore, the flux transfer tape of the present invention facilitates handling of the flux used for transfer.

  In a preferred specific configuration of the above-described flux transfer tape, the surface of the tape base material is provided with two regions each including both side edges of the tape base material on which the flux film is not formed. The film formation area is sandwiched. According to such a flux transfer tape, it is easy to prevent the softened flux from falling from the surface of the tape substrate.

  For example, a sprocket is used as means for feeding the flux transfer tape to a transfer position where flux transfer is performed. In this case, a plurality of through holes for engaging the sprocket pins are formed in at least one of the two regions, and the plurality of through holes are connected to the sprocket pins as the sprocket rotates. It is preferable that they are arranged at an equal pitch in the longitudinal direction of the tape base so as to be sequentially engaged.

  More preferably, on the surface of the tape base material, the through-hole formation region is separated from the flux film formation region. According to such a flux transfer tape, it is easy to prevent the softened flux from falling from the through hole.

  The flux transfer tape may further include a belt-like cover film that covers the solid flux layer. In this case, it is preferable that the side edge of the cover film is partially or entirely attached to at least one of the two regions. According to such a flux transfer tape, the adhesion of foreign matter to the solid flux layer is prevented.

  It is preferable that the flux transfer tape further includes a belt-shaped resin film, a solid flux layer is formed on the surface of the resin film, and the back surface of the resin film is adhered to the surface of the tape substrate. According to such a flux transfer tape, it is possible to use, as a tape base material, a tape made of a material that is difficult to directly form a solid flux layer on the surface.

Next, the flux transfer tape according to the embodiment of the present invention will be specifically described with reference to the drawings.
[1] Flux Transfer Tape FIG. 1 is a perspective view of a flux transfer tape. FIG. 2 is a cross-sectional view of the flux transfer tape. As shown in FIGS. 1 and 2, the flux transfer tape 8 includes a tape substrate 81, a flux film 82 formed on the surface 81 a of the tape substrate 81, and a strip-shaped cover film 83 that covers the flux film 82. It has. The flux transfer tape 8 is wound around, for example, a reel 85 (see FIG. 4).

  In the flux transfer tape 8, the flux film 82 extends in a band shape in the longitudinal direction of the tape base material 81. And as shown in FIG. 1, the width W1 of the tape base material 81 is larger than the width W2 of the flux film 82. Specifically, as shown in FIG. 2, two regions R <b> 1 and R <b> 2 in which the surface 81 a of the tape substrate 81 includes both side edges 81 b and 81 c of the tape substrate 81 and the flux film 82 is not formed. The flux film 82 forming region Rf is sandwiched between the two regions R1 and R2. The width W2 of the flux film 82 is, for example, 3 to 20 mm, although it depends on the size of the electronic component to which the flux is transferred. Further, the width W1 of the tape substrate 81 is, for example, 130 to 333% of the width W2.

  As shown in FIG. 2, the flux film 82 includes a strip-shaped resin film 821 and a solid flux layer 822 formed on the surface of the resin film 821. For the resin film 821, for example, a PET (polyethylene terephthalate) film or the like is used. The thickness of the resin film 821 is, for example, 50 to 100 μm. Further, the surface of the resin film 821 may be subjected to a mold release process. The solid flux layer 822 is formed from a flux. Examples of the flux include film forming materials such as phenoxy resin and urethane resin, active ingredients such as rosins and reducing agents, thixotropic agents and viscosity modifiers. And additives such as epoxy resins and thermosetting components such as epoxy resins. The thickness of the solid flux layer 822 is, for example, 10 to 300 μm, although it depends on the size of the bump to be transferred with the flux. The solid flux layer 822 may contain conductive powder such as solder powder or powder obtained by coating tin (Sn) particles with silver (Ag). The conductive powder may be spherical or scaly.

  When forming the flux film 82, first, a solution is prepared by dissolving the various components in a solvent. Next, a coating film of a solution having a predetermined thickness is formed on the surface of a large resin film 821 using a coating machine. Thereafter, the coating film is dried in a drying furnace to volatilize the solvent from the coating film to form the solid flux layer 822. In this way, a large-size flux film 82 is produced. Then, the large-sized flux film 82 is cut into a strip shape.

  The flux film 82 formed in this manner is attached to the surface 81 a of the tape base material 81. Specifically, the back surface of the resin film 821 (the surface on which the solid flux layer 822 is not formed) is attached to the surface 81 a of the tape substrate 81. At this time, the longitudinal direction of the tape base material 81 and the longitudinal direction of the flux film 82 are matched. By obtaining such a process, the flux transfer tape 8 is obtained. According to such a flux transfer tape 8, it is possible to use, as the tape base material 81, a tape made of a material in which it is difficult to directly form the solid flux layer 822 on the surface 81 a. For example, a paper tape can be used as the tape base material 81. A resin film such as a PET film may be used as the tape substrate 81. In this case, the solid flux layer 822 may be formed as the flux film 82 directly on the surface 81 a of the tape substrate 81.

  The cover film 83 covers the solid flux layer 822, and both side edges of the cover film 83 are partially or entirely attached to the two regions R1 and R2. For the cover film 83, for example, a film formed of polyester or polyethylene is used. In addition, any one side edge part of the cover film 83 may be affixed to the area | region R1 or R2 corresponding to the side edge part partially or entirely. According to the cover film 83, adhesion of foreign matters to the solid flux layer 822 is prevented.

  Further, in the present embodiment, a plurality of through holes 84 for feeding the flux transfer tape 8 are formed in the region R1 by engaging pins of a sprocket 421 described later. These through holes 84 are arranged at an equal pitch in the longitudinal direction of the tape base material 81 so that the pins of the sprocket 421 are sequentially engaged with the rotation of the sprocket 421. Further, on the surface 81 a of the tape substrate 81, the formation region of the through hole 84 is separated from the formation region Rf of the flux film 82. The through hole 84 may be formed in the region R2 instead of the region R1, or may be formed in both the two regions R1 and R2.

  According to the flux transfer tape 8 according to the present embodiment, even when the solid flux layer 822 is softened and has fluidity, the flux hardly falls from the surface 81a of the tape substrate 81. Further, it is difficult for the flux to adhere to the pins of the sprocket 421.

  In addition, since flux contains components such as film forming materials that solidify at room temperature, even if flux residue is generated on the surface of the substrate during the mounting process of electronic components, the residue remains in a solidified state. Will be maintained. For this reason, the electrical insulation characteristic is maintained in the component mounting board manufactured through the mounting process.

  Next, a flux supply device, an electronic component mounting device, and an electronic component mounting method in which the flux transfer tape according to the present invention is used will be described. In the present embodiment, the flux supply unit included in the electronic component mounting apparatus is configured by the flux supply apparatus. Below, an electronic component mounting apparatus is demonstrated concretely along drawing. Thereby, embodiment of the flux supply apparatus was also demonstrated.

[2] Electronic Component Mounting Device FIG. 3 is a plan view of the electronic component mounting device. As shown in FIG. 3, the electronic component mounting apparatus is held by the substrate transport unit 1, the component mounting unit 2, the first component supply unit 3 </ b> A, the plurality of second component supply units 3 </ b> B held by the cart 71, and the cart 72. Two flux supply sections 4 are provided.

  The substrate transport unit 1 is a conveyor having a pair of guide rails 11 and transports the substrate 6 in the X-axis direction along a transport path 12 defined by the pair of guide rails 11. In addition to the function of transporting the substrate 6, the substrate transport unit 1 functions as a substrate holding unit that transports the substrate 6 to a work position where electronic components are mounted and positions the substrate 6 at the work position. Also have.

  The component mounting unit 2 mounts the electronic component supplied from the first component supply unit 3A or the second component supply unit 3B on the substrate 6 positioned at the work position. Specifically, the component mounting unit 2 includes a Y-axis table 21, a Y-axis slider 22, an X-axis table 23, an X-axis slider 24, and a mounting head 25 that holds electronic components. The Y-axis table 21 is provided on the base 20 at a position downstream of the transport path 12 and has a shape that extends long in the Y-axis direction. The Y-axis slider 22 is provided on the Y-axis table 21 and can slide in the Y-axis direction along the Y-axis table 21. The X-axis table 23 has a shape extending in the X-axis direction and is fixed to the Y-axis slider 22. The X-axis slider 24 is provided on the X-axis table 23 and can slide along the X-axis table 23 in the X-axis direction. The mounting head 25 is attached to the X-axis slider 24. The mounting head 25 is provided with a suction nozzle 26 (see FIG. 7A) capable of sucking an electronic component at the tip. A plurality of Y-axis sliders 22 may be provided on the Y-axis table 21, and an X-axis table 23, an X-axis slider 24, and a mounting head 25 may be provided for each Y-axis slider 22.

  According to the component mounting unit 2, the mounting head 25 can be freely moved in the XY plane by moving the Y-axis slider 22 and the X-axis slider 24 in the Y-axis and X-axis directions, respectively. Further, the mounting head 25 can move the suction nozzle 26 in the Z-axis direction (direction perpendicular to the XY plane). Therefore, the component mounting unit 2 can freely move the electronic component sucked at the tip of the suction nozzle 26 in the space on the base 20. The movement of the Y-axis slider 22 in the Y-axis direction, the movement of the X-axis slider 24 in the X-axis direction, and the movement of the suction nozzle 26 in the Z-axis direction are controlled by a control unit (not shown), for example. The

  The first component supply unit 3 </ b> A is a tray feeder that conveys an electronic component 31 that is mainly provided with a plurality of bumps while being stored in the tray 30. Each of the second component supply units 3 </ b> B is a tape feeder that mainly supplies a chip-type electronic component to the component extraction port 33. Examples of the chip-type electronic component include a resistance element and a capacitor element. In the present embodiment, only the second component supply unit 3 </ b> B is held by the carriage 71, but some of them may be replaced by the flux supply unit 4.

  FIG. 4 is an explanatory diagram of each of the flux supply units 4. 5 and 6 are detailed views of the V region and the VI region shown in FIG. 4, respectively. In addition, illustration of the resin film 821 is abbreviate | omitted in FIG. The flux supply unit 4 is provided with a transfer position Pt at which the transfer of the flux to the bumps is performed. The flux supply unit 4 supplies the flux to the transfer position Pt. Specifically, the flux supply unit 4 includes a transfer window 4a (see FIG. 6) that exposes the transfer position Pt to the outside, a transfer stage 41 disposed at the transfer position Pt, a tape feeding mechanism 42, and a flux heating unit. 43 and a peeling mechanism 44. The transfer stage 41 is arranged so that the transfer position Pt is provided on the surface 41a.

  The tape feeding mechanism 42 is a mechanism for feeding the flux transfer tape 8 to the transfer position Pt. Specifically, the tape feeding mechanism 42 includes a sprocket 421 having a plurality of pins and a drive unit 422 that rotates the sprocket 421. Further, the flux transfer tape 8 is pulled out from the reel 85, and as shown in FIG. 5, the pin of the sprocket 421 is engaged with the feed through hole 84 existing in the pulled out portion. The tape feed mechanism 42 rotates the sprocket 421 to sequentially engage the pins of the sprocket 421 with the feed through hole 84. As a result, when the flux transfer tape 8 is unwound from the reel 85, an unused area of the flux transfer tape 8 is sent to the transfer position Pt (see FIG. 6). The rotation amount of the sprocket 421 that determines the feed amount of the flux transfer tape 8 is adjusted by the control unit (not shown) controlling the drive unit 422.

  The flux heating unit 43 softens the solid flux layer 822 by heating the flux transfer tape 8 at the transfer position Pt. Specifically, the flux heating unit 43 heats and softens the solid flux layer 822 by heat transfer such as heat conduction or heat radiation (radiation) from the surface by heating the surface 41a of the transfer stage 41. .

  The peeling mechanism 44 peels the cover film 83 covering the unused area from the flux transfer tape 8 before the unused area of the flux transfer tape 8 is sent to the transfer position Pt. Specifically, as shown in FIG. 6, a portion of the cover film 83 that is peeled off from the flux transfer tape 8 is drawn out from the transfer window 4a. The peeling mechanism 44 has two rollers 441 (see FIG. 4) provided on the upstream side of the transfer window 4a, and the peeled portion of the flux transfer tape 8 is sandwiched between the two rollers 441. Pull to the opposite side of the direction of travel. As a result, the cover film 83 is pulled by the two rollers 441 in a state of being hooked on the edge 4b of the transfer window 4a. According to such a peeling mechanism 44, immediately before the unused area of the flux transfer tape 8 is sent to the transfer position Pt, the cover film 83 covering the unused area is peeled off from the flux transfer tape 8. . Therefore, the mixing of foreign matters into the flux is prevented.

  The electronic component mounting apparatus of the present embodiment is provided with two flux supply units 4 as shown in FIG. 1. However, the electronic component mounting apparatus is not limited to this, and only one flux supply unit 4 is provided. It may be provided, and three or more flux supply units 4 may be provided. In addition, when the electronic component mounting apparatus is provided with a plurality of flux supply units 4, the width and thickness of the solid flux layer 822 of the flux transfer tape 8 used may be different for each flux supply unit 4. .

  In the electronic component mounting apparatus, the following transfer operation and mounting operation are performed. First, the suction nozzle 26 is moved onto the tray 30 of the first component supply unit 3A, so that the electronic component 31 stored in the tray 30 is sucked to the tip of the suction nozzle 26. Next, when the suction nozzle 26 is moved to a position facing the transfer window 4a of the flux supply unit 4, the electronic component 31 is moved to the transfer position Pt by moving the suction nozzle 26 in the Z-axis direction. Thereby, the plurality of bumps 32 provided on the electronic component 31 are landed on the softened flux (see FIG. 7A). In this way, the flux is transferred to the bumps 32 (see FIG. 7B). Thereafter, the suction nozzle 26 is moved onto the substrate 6 and the suction nozzle 26 is moved in the Z-axis direction so that the electronic component 31 onto which the flux has been transferred is mounted on the substrate 6. That is, before mounting the electronic component 31 on the substrate 6, the component mounting unit 2 causes the bump 32 to land on the softened solid flux layer 822 at the transfer position Pt of the flux supply unit 4, thereby providing flux to the bump 32. Transcript.

[3] Electronic Component Mounting Method Next, an electronic component mounting method corresponding to the transfer operation and the mounting operation described above will be specifically described. In the electronic component mounting method, a tape feeding process, a flux heating process, a transfer process, and a mounting process are executed.

  In the tape feeding process, as shown in FIG. 5, the sprocket 421 is rotated and the pins of the sprocket 421 are sequentially engaged with the feed through holes 84. Thereby, the flux transfer tape 8 is sent to the transfer position Pt. Specifically, as shown in FIG. 6, the used area of the flux transfer tape 8 is sent from the transfer position Pt, and the unused area of the flux transfer tape 8 is sent to the transfer position Pt. Further, immediately before the unused area of the flux transfer tape 8 is sent to the transfer position Pt, the cover film 83 covering the unused area is peeled off from the flux transfer tape 8 by the peeling mechanism 44. Thereby, the surface of the solid flux layer 822 is exposed.

  In the flux heating step, the solid flux layer 822 is softened by heating the flux transfer tape 8 at the transfer position Pt. Specifically, the back surface of the tape base material 81 is brought into contact with the surface 41a of the transfer stage 41 at the transfer position Pt, and the surface 41a of the transfer stage 41 is heated using the flux heating unit 43. Thereby, the solid flux layer 822 is heated and softened by heat transfer (heat conduction or heat radiation (radiation)) from the surface 41a. At this time, the surface 41a of the transfer stage 41 is heated to 40 to 150 ° C., for example.

  7A and 7B are explanatory diagrams of the transfer process. In addition, illustration of the resin film 821 is abbreviate | omitted in Fig.7 (a) and (b). In the transfer step, first, as shown in FIG. 7A, the electronic component 31 is moved using the component mounting portion 2, whereby a plurality of bumps 32 provided on the electronic component 31 are converted into a softened flux 823. Land. Thereafter, as shown in FIG. 7B, the bump 32 is separated from the flux 823 by pulling up the electronic component 31. In this way, the flux is transferred to the bumps 32.

  After the transfer process, the electronic component 31 to which the flux has been transferred is mounted on the substrate 6 by moving the electronic component 31 using the component mounting portion 2 in the mounting process. Thereafter, by performing the tape feeding process again, as shown in FIG. 6, the used area of the flux transfer tape 8 is sent from the transfer position Pt, and the unused area of the flux transfer tape 8 is sent to the transfer position Pt. . For example, when the dimension of the electronic component 31 is smaller than the width W2 (see FIG. 1) of the solid flux layer 822, the transfer process is performed before the tape feeding process so that the amount of discarded flux is reduced. It may be executed repeatedly. When the transfer process is repeated in this manner, it is preferable to change the position where the bumps 32 are landed on the flux little by little.

  According to the electronic component mounting apparatus and electronic component mounting method of the present embodiment, the solid flux layer 822 is supplied as the transfer flux to the transfer position Pt, and the solid flux layer 822 is heated and softened at the transfer position Pt. To do. Accordingly, the flux is always supplied to the transfer position Pt with a desired viscosity. Therefore, in the conventional transfer technique, since the paste-like flux is repeatedly used for forming the flux coating film at the transfer position, there arises a problem that the viscosity of the paste is increased. There is no problem. As described above, in the present embodiment, a flux having a desired viscosity is transferred to the bump 32, and therefore, an appropriate amount of flux is transferred to the bump 32.

  Furthermore, according to the electronic component mounting apparatus and the electronic component mounting method of the present embodiment, film formation in the apparatus, which is necessary in the conventional transfer technology, becomes unnecessary, so that the flux hardly adheres to the transfer stage 41 and the like. Become. Further, since the flux that is no longer needed is sent from the transfer position Pt together with the tape base material 81 by executing the tape feeding process, the flux is difficult to adhere to the transfer stage 41 and the like. Therefore, it is possible to reduce the frequency of performing maintenance such as cleaning on the electronic component mounting apparatus. As a result, it is possible to continuously operate the mounting line over a long period of time, thereby reducing the running cost.

  As described above, according to the flux transfer tape 8 of the present embodiment, it is difficult for the flux to spill from the surface 81 a of the tape base material 81, and it is difficult for the flux to adhere to the pins of the sprocket 421. Therefore, it is possible to reduce the frequency of cleaning the electronic component mounting apparatus, and as a result, it is possible to continuously operate the mounting line over a long period of time, thereby reducing the running cost. Therefore, the flux transfer tape 8 of this embodiment facilitates handling of the flux used for transfer.

  In addition, each part structure of this invention is not restricted to the said embodiment, A various deformation | transformation is possible within the technical scope as described in a claim.

  The tape for flux transfer according to the present invention can be applied to the production of a component mounting board provided in an electronic device such as a liquid crystal display module.

DESCRIPTION OF SYMBOLS 1 Board | substrate conveyance part 11 Guide rail 12 Conveyance path 2 Component mounting part 20 Base 21 Y-axis table 22 Y-axis slider 23 X-axis table 24 X-axis slider 25 Mounting head 26 Adsorption nozzle 3A 1st component supply part 3B 2nd component supply Section 30 Tray 31 Electronic component 32 Bump 33 Component outlet 4 Flux supply section 4a Transfer window 4b Edge 41 Transfer stage 41a Surface 42 Tape feed mechanism 421 Sprocket 422 Drive section 43 Flux heating section 44 Peeling mechanism 441 Roller 6 Substrate 71, 72 Carriage 8 Flux Transfer Tape 81 Tape Base 81a Surface 81b, 81c Both Sides Edge 82 Flux Film 821 Resin Film 822 Solid Flux Layer 823 Flux 83 Cover Film 84 Through Hole 85 Reel Pt Transfer Position R1, R2 Region Rf Formation Region W1, W Width

Claims (5)

A tape substrate;
A film including a solid flux layer formed from a flux, and formed on the surface of the tape base material, and further including a flux film spreading in a strip shape in the longitudinal direction of the tape base material, and the tape the width of the substrate is rather larger than the width of the flux film,
On the surface of the tape base material, two regions each including both side edges of the tape base material where the flux film is not formed are provided, and the flux film forming region is sandwiched between the two regions. ,
A flux transfer tape , wherein a plurality of through holes for engaging a sprocket pin are formed in at least one of the two regions . Before SL plurality of through holes, as the pin of the sprocket with the rotation of the sprocket is sequentially engaged, are arranged at a constant pitch in the longitudinal direction of the tape base material, according to claim 1 The tape for flux transfer described in 1. 3. The flux transfer tape according to claim 1, wherein a region where the through hole is formed is separated from a region where the flux film is formed on the surface of the tape base material. A belt-like cover film covering the solid flux layer is further provided, and a side edge of the cover film is partially or entirely attached to at least one of the two regions. flux transfer tape according to any one of claims 1 to 3. The said flux film further contains a strip | belt-shaped resin film, the said solid flux layer is formed in the surface of the said resin film, and the back surface of the said resin film is stuck on the said surface of the said tape base material. The tape for flux transfer according to any one of claims 4 to 4 .

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