JP2010195029A - Coating film transferring tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem of low accuracy of a product caused by difficult calculation of engaging accuracy due to presence of a plurality of gears and sawtooth, and a large number of components, a complex configuration because of much processing for each component, increasing a price, a complex mold even when each component is manufactured as a molded article, time and labor necessitated by the complexity. <P>SOLUTION: The coating film transferring tool includes a transfer head disposed to project/retract from/into a transferring tool case, a delivery core having a transfer tape wound thereon, and a take-up core for taking up the transfer tape delivered from the delivery core. A tape traveling path changing member operated cooperatively with the projecting/retracting operation of the transferring head is disposed in the transferring head. At least when the transfer head retracts, the transfer tape is wound by the tape traveling path changing member. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention provides a transfer core in which a transfer tape provided with a transfer coating film is wound around a transfer tool case, and a transfer tape supplied from the supply core is pressed against the transfer surface from the back side of the substrate. The present invention also relates to a coating film transfer tool comprising: a transfer head that transfers the transfer coating film to a transfer surface; and a winding core that is drawn from the feeding core and winds up the substrate that has passed through the tip of the transfer head.

2. Description of the Related Art Conventionally, a coating film transfer tool is known in which a transfer head protrudes from a case at the time of transfer and can be accommodated in the case at the time of non-transfer. For example, it is described in JP 2007-136959 A.
The coating film transfer tool described in Japanese Patent Application Laid-Open No. 2007-136959 slides the transfer head, abuts against the transfer tape to perform the transfer, protrudes from the case, and further enters the transfer tool case. When the slide mechanism is interposed between the slide mechanism to be housed, the supply bobbin, and the supply reel and the transfer head is protruded by the slide mechanism, the linkage between the supply bobbin and the supply reel is released, When the supply bobbin rotates in the direction of winding up the transfer tape as the transfer tape travels, the slide mechanism includes a slip mechanism that rotates the supply reel and the supply bobbin in conjunction with the rotation direction. When the sliding operation is performed to store the storage reel, the supply reel is engaged with the supply reel and rotated reversely.

JP 2007-136959 A.

  However, in the prior art described in Japanese Patent Application Laid-Open No. 2007-136959, when the slide mechanism is slid with respect to the transfer head protruding from the transfer tool case to perform the storing operation in the transfer tool case, the gear of the slide mechanism is used. Is engaged with the supply reel so that the tape is interlocked and stored in the transfer tool case. However, in order to link the slide mechanism and the tape storage mechanism, the transfer head 5, the connecting portion 102, the case 10, the supply bobbin 21, the transfer tape T, the take-up bobbin 31, the supply reel 2, the take-up reel 3, the slip 14 parts (16 parts when the case and tape unit are divided into upper and lower parts) are required, including the clutch with mechanism 22, the reel interlocking gear 6, the gear 103, the spring part 104, the operating part 101, and the tape unit 4. ing. Further, in order to perform an interlocking operation in which the transfer head and the transfer tape are projected and retracted with respect to the transfer tool case, for example, the connecting portion 102 has a through hole 102a, a sawtooth-shaped transmission portion 102b, and the tape unit 4 has a stretch A gear 41a and a gear 2b are formed on the member 41 and the supply reel 2, and a shaft portion 10d, a shaft portion 10e, a shaft portion 10f, a recess 10g, a sliding groove 10h, and a locking groove 10i are formed on the case lower portion 10b. That is, in the above configuration, the number of parts is large, and since many processes are performed on each of the parts, the configuration becomes complicated and expensive. Also, even when each part is manufactured as a molded product, it takes time to make a mold, and since there are multiple gears and saw teeth, it is difficult to calculate the meshing accuracy and the product accuracy is also poor. It has become.

  In the present invention, the transfer head is disposed so as to be able to appear and retract with respect to the transfer tool case, and a feeding core around which the transfer tape is wound and a winding core that winds up the transfer tape fed out from the feeding core are arranged. The tape travel path changing member that operates in conjunction with the movement operation of the transfer head is disposed on the transfer head, and the tape travel path change member is at least during the immersion operation of the transfer head. The gist is that the transfer tape is wound around.

  In the present invention, the transfer head is disposed so as to be able to appear and retract with respect to the transfer tool case, and a feeding core around which the transfer tape is wound and a winding core that winds up the transfer tape fed out from the feeding core are arranged. The tape travel path changing member that operates in conjunction with the movement operation of the transfer head is disposed on the transfer head, and the tape travel path change member is at least during the immersion operation of the transfer head. Since the transfer tape is wound around, the coating film transfer tool can be provided at a low cost with a simple configuration.

The disassembled perspective view which shows the structure of 1st Example of this invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external perspective view showing a slide button, a transfer tool case upper part, a winding core, and a feeding core according to a first embodiment of the present invention. FIG. 3 is an external perspective view of the transfer tool showing a transfer head protruding state according to the first embodiment of the present invention. FIG. 3 is a configuration diagram showing the position of a transfer coating film in a state where the transfer head according to the first embodiment of the present invention protrudes from the inside of the transfer tool case. FIG. 3 is a configuration diagram showing the position of a transfer coating film in a state where the transfer head according to the first embodiment of the present invention is housed in a transfer tool case. The disassembled perspective view which shows the structure of 2nd Example of this invention. The external appearance perspective view which shows the slide button, transfer tool case upper part, winding core, and feeding core of 2nd Example of this invention. The external appearance perspective view of the transfer tool which shows the transfer head protrusion state of 2nd Example of this invention. The block diagram which shows the position of the transfer coating film in the state which the transfer head in connection with 2nd Example of this invention protruded from the inside of the transfer tool case. The block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 2nd Example of this invention was accommodated in the transfer tool case. The disassembled perspective view which shows the structure of 3rd Example of this invention. The external appearance perspective view which shows the slide member and transfer tool case upper part of 3rd Example of this invention. The external appearance perspective view of the transfer tool which shows the transfer head protrusion state of 3rd Example of this invention. The block diagram which shows the position of the transfer coating film in the state which the transfer head in connection with 3rd Example of this invention protruded from the inside of the transfer tool case. The block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 3rd Example of this invention was accommodated in the transfer tool case. The disassembled perspective view which shows the structure of 4th Example of this invention. The external appearance perspective view which shows the transfer tool case upper part of the 4th Example of this invention, and a slide mechanism. The external appearance perspective view of the transfer tool which shows the transfer head protrusion state of 4th Example of this invention. The block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 4th Example of this invention was accommodated in the transfer tool case. The block diagram which shows the position of the transfer coating film in the state which the transfer head concerning 4th Example of this invention protruded from the inside of a transfer tool case. The disassembled perspective view which shows the structure of 5th Example of this invention. FIG. 10 is a perspective view of a transfer head according to a fifth embodiment of the invention. The block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 5th Example of this invention was accommodated in the transfer tool case. The block diagram which shows the position of the transfer coating film in the state which the transfer head concerning 5th Example of this invention protruded from the inside of a transfer tool case. FIG. 10 is an external perspective view showing a transfer head state when the transfer head protrudes according to a fifth embodiment of the present invention. FIG. 10 is an external perspective view showing a state of a transfer head when the transfer head is housed in a fifth embodiment of the present invention. The disassembled perspective view which shows the structure of 6th Example of this invention. The external appearance perspective view which shows the slide button of 6th Example of this invention, the transcription | transfer tool case upper part, a winding core, and a feeding core. The external appearance perspective view of the transfer tool which shows the transfer head protrusion state of 6th Example of this invention. The block diagram which shows the position of the transfer coating film in the state which the transfer head in connection with 6th Example of this invention protruded from the inside of the transfer tool case. The block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 6th Example of this invention was accommodated in the transfer tool case. The disassembled perspective view which shows the structure of 7th Example of this invention. The external appearance perspective view which shows the slide button, transfer tool case upper part, winding core, and feeding core of 7th Example of this invention. The external appearance perspective view of the transfer tool which shows the transfer head protrusion state of 7th Example of this invention. The block diagram which shows the position of the transfer coating film in the state which the transfer head in connection with 7th Example of this invention protruded from the inside of the transfer tool case. The block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 7th Example of this invention was accommodated in the transfer tool case. The disassembled perspective view which shows the structure of 8th Example of this invention. The external appearance perspective view which shows the slide member of 8th Example of this invention, and a transfer tool case upper part. The external appearance perspective view of the transfer tool which shows the transfer head protrusion state of 8th Example of this invention. The cross-sectional block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 8th Example of this invention was accommodated in the transfer tool case. The cross-sectional block diagram which shows the position of the transfer coating film in the state which the transfer head concerning 8th Example of this invention protruded from the inside of a transfer tool case. The block diagram which shows the position of the transfer coating film in the state which the transfer head concerning 8th Example of this invention protruded from the inside of a transfer tool case. The block diagram which shows the position of the transfer coating film in the state in which the transfer head concerning 8th Example of this invention was accommodated in the transfer tool case.

Example 1
The configuration of the coating film transfer tool of the first embodiment will be described based on the drawings of FIGS. 1, 2, and 3. The transfer tool case 1 includes a transfer tool case lower part 10 and a transfer tool case upper part 20. The transfer tool case lower part 10 has a bottomed box shape having a front wall 10a, a rear wall 10b, a right wall 10c, a left wall 10d and a bottom wall 10e. A protruding rotary shaft 10f is provided upright at the center of the transfer tool case lower part 10, and the winding core 30 is pivotally supported by the rotary shaft 10f. The winding core 30 has a cylindrical shape, and a slip portion 30a, which is a half-moon-shaped cylindrical member, radiates along the side surface on the side surface of the cylindrical portion near the bottom wall 10e of the transfer tool case lower part 10. Is formed. Further, a winding portion 30 b for winding the transfer tape T fed from the feeding core 40 is formed in a cylindrical shape on the winding core 30. Further, a cylindrical member 30c larger than the outer diameter of the winding part 30b is formed between the lower part of the winding part 30b and the upper part of the slip part 30a.
Further, an engaging portion 30d that can be elastically deformed is formed on the upper surface of the cylindrical member 30c and below the winding portion 30b, and a radial groove formed on the bottom wall 20e of the transfer tool case upper portion 20 is formed. 20k is detachably engaged. The engaging portion 30d is formed as an arcuate engaging portion 30d by forming a "U" -shaped groove 30e in an arc shape in the cylindrical member 30c, and the engaging portion 30d is engaged at the tip of the engaging portion 30d. A claw 30f is formed. The engaging claws 30f are formed so as to protrude from the upper surface of the cylindrical member 30c, and are engaged with the radial grooves 20k in a detachable manner.
On the other hand, the feeding core 40 has a cylindrical shape, and the height thereof is designed to be larger than the width of the transfer tape T. Further, the inside of the feeding core 40 is fitted in a state where it is pressed against the side surface of the slip portion 30a. As a result, the feeding core 40 is rotatably supported in a state in which a frictional resistance is applied, and a frictional resistance in the rotational direction with respect to the slip portion 30a of the feeding core 40 is given, and each other is assembled and disassembled. Is prevented. A transfer tape T is wound around the feeding core 40. Further, winding grooves 40b, which are circular grooves, are radially formed on the bottom surface 40a of the feeding core 40 near the lower part 10 of the transfer tool case.

Assembly parts 10g, 10h, and 10i are formed in a cylindrical shape at the other three corners on the bottom wall 10e of the transfer tool case lower part 10 but not on the corners of the front wall 10a and the right wall 10c. Further, in the front wall 10a, in the vicinity of the right wall 10c, a case lower opening 10j is open as a through hole in a rectangular shape. Further, on the side surface opposite to the side surface near the right wall 10c of the case lower opening 10j, a parallel wall and a wall are formed to the vicinity of the center along the right wall 10c of the transfer tool case lower portion 10, and the guide rail 10k and the guide rail 10 l. In the vicinity of the upper portions of the opposing walls of the guide rails 10k and 10l, guide grooves 10m and 10n are vacant as through holes, respectively. Further, a tape travel path fixing change member 10o is erected in a columnar shape near the outer side of the guide rail 10l on the bottom wall 10e of the lower part 10 of the transfer tool case 10 in the direction of the right wall 10c from the rotation shaft 10f. Yes.
Further, the roller 50 has a cylindrical shape, the inner diameter thereof is larger than the outer shape of the tape travel path fixing / changing member 10o, and is pivotally supported by the tape travel path fixing / changing member 10o so as to be rotatable. A semicircular hole 10p is formed around the rotation shaft 10f.

The transfer tool case upper part 20 has a bottomed box shape having a front wall 20a, a rear wall 20b, a right wall 20c, a left wall 20d and a bottom wall 20e, and has a bottom surface having the same shape as the lower part of the transfer tool case 10. Have. Further, assembly parts 20g, 20h, 20i are formed in a cylindrical shape on the bottom wall 20e of the transfer tool case upper part 20, and can be fitted to the assembly parts 10g, 10h, 10i of the transfer tool case lower part 10. Similarly, the assembling portion 20f and the assembling portion 20o also have a cylindrical shape, and are an assembling portion 20f that can be fitted to the rotating shaft 10f and an assembling portion 20o that can be fitted to the tape travel path fixing changing member 10o. . Further, an anti-reverse member 20l having an inner diameter larger than the outer shape of the assembly portion 20f is formed in a cylindrical shape around the rotation shaft 10f, and the radial groove 20k is formed on the upper portion thereof. Is formed. In the transfer tool case upper part 20, a case upper opening 20 j is formed at the same location as the transfer tool case lower part 10. A hole formed by the case upper opening 20j and the case lower opening 10j is referred to as a case opening 2.
A guide groove 20m is formed as a rectangular groove on the top surface of the transfer tool case upper portion 20 in the vicinity of the case opening 20j and in the vicinity of the right wall 20c. Further, a transfer head guide hole 20n is formed in the guide groove 20m in a rectangular shape from the vicinity of the front wall 20a. Within the guide groove 20m, behind the transfer head guide hole 20n, a button guide hole 20p is formed in a rectangular shape toward the rear end of the guide groove 20m, and further at the four corners of the button guide hole 20p. The square hole 20q is vacant toward the side surface.

The transfer head 60 has a rectangular plate shape and is made of a material that can be elastically deformed. Further, a pressing portion 60a having a substantially triangular cross section is formed at the front end portion of the transfer head 60, and a tape protruding in a columnar shape near the end opposite to the pressing portion 60a. A travel path movement changing member 60b is provided. Further, a rectangular parallelepiped is located on the opposite side of the surface on which the tape travel path movement changing member 60 b is disposed, which is the substantially central portion of the transfer head 60, and at substantially the end portions on both sides of the transfer head 60. Shaped slide protrusions 60c and 60d are erected. Locking protrusions 60e and 60f having a substantially triangular shape are formed inside the upper ends of the slide protrusions 60c and 60d. Also, tape guides 60g having a substantially triangular shape are formed on both sides in the width direction of the front portion of the transfer head 60.
Similar to the transfer head 60, the slide button 70 has a rectangular plate shape and is made of a material that can be elastically deformed. Further, a button slide portion 70a which is a rectangular parallelepiped protrusion is formed at the front end portion of the slide button 70, and the button slide portion 70a has a transfer head fitting hole 70b. The transfer head fitting hole 70b has a rectangular shape and can be locked with the locking protrusion 60d. In addition, a rectangular-shaped case slide portion 70c protrudes from the center of the slide button 70 on the side where the button slide portion 70a is formed, and above the case slide portion 70c. A slide locking portion 70d, which is a rectangular projection having a size larger than the upper surface of the case slide portion 70c and including the button guide hole 20p and the square hole 20q, is formed. Further, an elastic repulsion portion 70e is formed on the rear end portion of the slide button 70 as a substantially triangular projection. Further, on the surface of the slide button 70 opposite to the case slide portion 70c, a button slip preventing portion 70f is formed as a plurality of substantially triangular projections, and is formed from the center portion to the end portion.
In this embodiment, the transfer tool case lower part 10, the transfer tool case upper part 20, the winding core 30, the feeding core 40, the roller 50, the transfer head 60, the slide button 70, and the transfer tape T are configured. Yes.

Next, the operation of this embodiment will be described with reference to FIGS. Since the locking protrusion 60d formed integrally with the transfer head 60 and the transfer head fitting hole 70b of the slide button 70 are locked, for example, the slide button 70 is moved back and forth with respect to the case opening 2. Then, the transfer head 60 appears and disappears from the case opening 2 of the transfer tool case 1.
At the time of transfer of the correction tape, the transfer tape T fed from the feed core 40 is fed toward the tape travel path fixing / changing member 10o, folded back on the side surface on the front wall 10a side of the roller 50, and the tape travel of the transfer head 60. It goes to the route movement changing member 60b. At this time, the transfer coating film S side of the transfer tape T contacts the side surface of the roller 50. Since the roller 50 is rotatably supported by the tape travel path fixing / changing member 10o, the transfer tape T is smoothly fed out. Damage to the surface is prevented. Then, the transfer tape T side is folded back while making contact with the side surface on the rear wall 10b side of the tape travel path movement changing member 60b, passes through the lower surface of the transfer head 60, and the transfer tape T side contacts with the transfer head pressing portion 60a. Wrapped while. The folded transfer tape T passes from the transfer head pressing portion 60a to the assembling portion 10i while passing through the upper surface of the transfer head 60 and passing between the slide protrusions 60c and 60d. The transfer tape T folded back on the side surface on the right wall 10 c side of the assembly portion 10 i and on the rear wall 10 b side is wound up by the winding portion 30 b of the winding core 30. Further, the surface of the tape that is folded back and brought into contact with the side surface on the rear wall 10b side may be on the transfer tape T side or on the transfer coating film S side, but there is no damage to the coating film. The tape T side is desirable.
Here, when the transfer head 60 is stored in the transfer tool case 1, the slide button 70 is moved to the rear of the transfer tool case 1 along the guide groove 20m. At this time, the tape travel path movement changing member 60b formed on the transfer head 60 also moves backward in conjunction with the slide button 70. At the same time, the transfer tape T via the tape travel path movement changing member 60b is transferred to the transfer tool case 1. Stored inside. Further, at this time, the transfer tape T between the tape travel path movement changing member 60b and the tape travel path movement changing member 10o is also separated by the retreat of the tape travel path movement changing member 60b. It is stored in the tool case 1. At this time, even when the transfer tape T is stored, the engaging portion 30d of the winding core 30 is engaged with the radial groove 20k, so that it is prevented from rotating in the direction opposite to the winding direction. The transfer tape T is not wound up.
Therefore, when the transfer head 60 is housed in the transfer tool case 1, the tape travel path movement changing member 60b moves backward, and the transfer tape T that has passed through the tape travel path change member 60b is pulled by the tape travel path movement changing member 60b. The transfer tape T is accommodated by being pulled by the distance and the separation distance between the tape travel path movement changing member 60b and the tape travel path fixing / changing member 10o. That is, the transfer tape T moves approximately twice as much as the movement distance of the tape travel path changing member 60b and is stored.
By this pulling operation, the transfer coating film S applied to the transfer tape T located under the transfer head 60 is stored behind the transfer head 60. Because of the above configuration, the tape is fed from the feeding core 40 and is folded back by the pressing portion 60a of the transfer head 60 via the roller 50 having the tape running path fixing / changing member 10o as an axis and the tape running path movement changing member 60b. The length of the transfer tape T that passes between the slide protrusions 60c and 60d and is taken up by the take-up portion 30b of the take-up core 30 through the assembling portion 10i is constant without being loosened even when the transfer head 60 is immersed. It is. The transfer tape T is in a state that does not always slack during the retracting operation, and is attached to the transfer tape T located under the transfer head 60 when the transfer head 60 described above is stored. Since the transfer coating film S is stored behind the transfer head 60, the transfer coating film S is prevented from being damaged. At the same time, since the transfer tape T to which the transfer coating film S adheres at the pressing portion 60a does not interfere, the peeling of the transfer coating film S from the transfer tape T is also prevented. Further, since the transfer tape T does not always slack when the transfer head 60 moves in and out, the transfer head 60 can be stored at the end of the case opening 2 when the transfer head 60 is stored in the transfer tool case 1. . That is, even when the transfer head 60 is at the end of the case opening 2, the transfer tape T is protected because the transfer tape T is stored in the transfer tool case 1. In addition, because of the above configuration, there is no need to house the transfer head 60 in the transfer tool case 1, and there is an advantage that the transfer tool case 1 can be slimmed.

When the transfer head 60 is protruded from the case opening 2, the transfer coating film S located at the lower rear of the transfer head 60 is stored in the transfer tool case 1 by the protrusion operation of the pressing portion 60 a of the transfer head 60. The transfer tape T is pulled out to the front end portion (pressing portion 60a) of the transfer head 60 together with the transfer tape T that has been applied. This is because when the transfer head 60 described above is housed in the transfer tool case 1, the tape travel path movement changing member 60b moves backward, and the transfer tape T that has passed through the tape travel path change member 60b moves the tape travel path. This is because the transfer tape T is accommodated by the distance pulled by the change member 60b and the separation distance between the tape travel path movement change member 60b and the tape travel path fixing change member 10o. This is because only the transfer tape T located at the lower part is accommodated in the transfer tool case 1. Furthermore, since only the transfer tape T accommodated in the transfer tool case 1 is protruded by the pressing portion 60a of the transfer head 60 during the protrusion operation of the transfer head 60, the transfer head 60 is in the protruded state. The transfer coating film S is configured such that the position of the coating film is always at the tip of the transfer head 60.
Here, when the transfer tape T is loosened, a thin rod-shaped member (for example, a toothpick or a pen tip of a ballpoint pen) is inserted through the semicircular arc-shaped hole 10p and engaged with the take-up groove 40b. The slack is eliminated by rotating the core 40 counterclockwise. At this time, the winding core 30 also tries to rotate in conjunction with the feeding core 40, but the reverse rotation of the winding core 30 is prevented by the engagement between the engaging claws 30f and the radial grooves 20k. The take-up core 30 is prevented from rotating. That is, since the reverse rotation of the winding core 30 is prevented, even if the winding groove 40b is rotated, only the feeding core 40 is rotated, thereby eliminating the slack of the tape. Furthermore, since only the transfer coating film S is wound around the feeding core 40 again, the transfer coating film S is not wasted.
Further, since the winding diameter of the transfer tape T with respect to the feeding core 40 is smaller than the winding core 30, the tape winding speed by the winding core 3 is higher than the tape drawing speed from the feeding core 40, and the winding core 30 is always provided. However, it works to wind up the transfer tape T more than the feeding core 40. As a result, the used transfer tape T can be reliably wound around the winding core 30.
As described above, in the present embodiment, the feeding core 40 and the take-up core 30 are provided on the same axis, but an independent shaft may be provided and interlocked using a gear, a timing bell, or the like.

The above configuration is a basic configuration, which will be described more specifically. The transfer tool case 1 is a resin molded product such as acrylonitrile / styrene copolymer resin, acrylonitrile / buditaene / styrene copolymer, reinforced polyethylene terephthalate, polycarbonate resin, polystyrene, or methacrylic resin. Moreover, as thickness of the transfer tool case 1, the range of 0.5 mm-2.0 mm is preferable. Incidentally, if it exceeds 2.0 mm, it becomes difficult to cool the molded product after molding, and if the thickness is less than 0.5 mm, there is a risk that the strength is impaired.
The transfer tape T is a transfer film S having adhesive properties such as a character correction coating film, a decorative colored coating film, an adhesive pressure-sensitive adhesive film, and a fluorescent coating film on the surface of a synthetic resin transfer tape T as a base material. It has.
The transfer tape T is wound around the feeding core 40, and the transfer tape T fed from the feeding core 40 is pressed against the transfer surface such as paper from the back side of the transfer tape T by the transfer head 60. The transfer coating film S is transferred to the transfer surface. The used transfer tape T (transfer tape as a base material) after passing through the transfer head 60 is wound up by the winding core 30. The transfer head 60 is preferably made of a material such as polyacetal resin, polypropylene resin, metal (stainless steel, brass, piano wire, etc.) in consideration of slidability, durability, and flexibility.
The material of the feeding core 40 and the winding core 30 is slidable and durable polyacetal resin, polypropylene resin, polybutylene terephthalate, acrylonitrile / styrene copolymer resin, acrylonitrile / buditaene / styrene copolymer, reinforced It is preferable to use a resin material such as polyethylene terephthalate, polycarbonate resin, polystyrene, or methacrylic resin.

(Example 2)
Next, the structure of the coating film transfer tool of 2nd Embodiment is demonstrated based on drawing of FIG.6, FIG.7, FIG.8. The description of the same configuration as in the first embodiment is omitted. In addition, in the figure, the same code | symbol is attached | subjected about the structure similar to Example 1. FIG.
The transfer tool case 3 includes a transfer tool case lower part 100 and a transfer tool case upper part 110. The transfer tool case lower part 100 has a rectangular plate shape with three corners in an arc shape, and a rotary shaft 100a is provided in a columnar shape at a substantially central part thereof.
The winding core 30 is pivotally supported by the rotating shaft 100a. The engaging claw 30f of the winding core 30 is detachably engaged with a radial groove 110d formed on the bottom surface of the transfer tool case upper portion 110.
A rectangular guide rail 100b is erected on the side of the bottom surface of the transfer tool case lower part 100 at the corner, and the transfer head 120 is spaced apart by about the same width. A guide rail 100c is erected.
In addition, guide grooves 100d and 100e are formed as through holes in the vicinity of the upper portion of the opposing walls of the guide rail 100b and the guide rail 100c.
Also, a tape travel path fixing / changing member 100f is erected in a columnar shape near the side surface of the guide rail 100c above the rotation shaft 100a in the lower part 100 of the transfer tool case.
Further, between the guide rails 100b and 100c and behind the transfer tool case, a tape travel path 100g is formed as a cylindrical protrusion.
A semicircular hole 100h is formed around the rotation shaft 100a.

The transfer tool case upper part 110 has a bottomed box shape and has a bottom surface having the same shape as the transfer tool case lower part 100. Further, the transfer tool case upper part 110 is formed with assembly parts 110a and 110b in a cylindrical shape. The transfer tool case lower part 100 can be fitted with the rotary shaft 100a, the assembly part 110a, and the tape travel path fixing change member 100g. The assembly portion 110b can be fitted.
Further, an anti-reverse member 110c, which is an upper part 110 of the transfer tool case and has an inner diameter larger than the outer shape of the assembling part 110a, is formed in a cylindrical shape centering on the rotation shaft 100a. 110d is formed.
In addition, guide rails 100b and 100c are disposed in the lower part 100 of the transfer tool case so that the transfer head 120 slides. A case opening 4 is formed in the tool case upper part 110.
Further, on the top surface of the transfer tool case upper portion 100, a slide groove 110e is formed as a rectangular hole from the vicinity of the case opening 4 to the rear of the transfer tool case 3.
The transfer head 120 has a rectangular plate shape and is made of a material that can be elastically deformed. In addition, a pressing portion 120a having a substantially triangular cross section is formed at the front end portion of the transfer head 120, and a tape protruding in a columnar shape near the end opposite to the pressing portion 120a. A travel route movement changing member 120b is provided. In addition, tape guides 120 c having a substantially triangular shape are formed on both sides in the width direction of the front portion of the transfer head 120.
The slide button 130 has a cylindrical shape. In addition, a circular transfer head fitting portion 130a is vacant at the lower portion of the slide button 130 and can be fitted to the upper portion of the tape travel path movement changing member 120b.
In this embodiment, the transfer tool case lower part 100, the transfer tool case upper part 110, the winding core 30, the feeding core 40, the transfer head 120, the slide button 130, and the transfer tape T are configured.

Next, the operation of this embodiment will be described with reference to FIGS. Since the tape travel path movement changing member 120b formed integrally with the transfer head 120 and the transfer head fitting hole 130a located below the slide member 130 are connected, for example, the slide member 130 is connected to the case opening. When slid back and forth with respect to 4, the transfer head 120 appears and disappears from the case opening 4 of the transfer tool case 3.
During transfer of the correction tape, the transfer tape T fed from the feeding core 40 is sent out toward the tape travel path 100g, folded back on the side surface behind the tape travel path 100g, passed through the lower surface of the transfer head 120, and transferred. Heading toward the head pressing portion 120a. At this time, the transfer tape T side contacts the side surface of the tape running path 100g. Then, the transfer tape T folded back at the pressing portion 120a of the transfer head 120 passes through the upper surface of the transfer head 120 from the transfer head pressing portion 120a and is transferred onto the rear side surface of the tape travel path movement changing member 120b. The film S side is folded while contacting, and heads toward the tape travel path fixing / changing member 100f. The transfer tape T is folded while the transfer tape T side is in contact with the front side surface of the tape travel path fixing / changing member 100f and wound by the winding portion 30b of the winding core 30.

Here, when the transfer head 120 is housed in the transfer tool case 3, the slide member 130 is moved to the rear of the transfer tool case 5 along the slide groove 110e. At this time, the tape travel path movement changing member 120b formed on the transfer head 120 also moves backward in conjunction with the slide member 130. At the same time, the transfer tape T via the tape travel path movement changing member 120b is also transferred to the transfer tool case 3. Stored inside.
Further, at that time, the transfer tape T between the tape travel path movement changing member 120b and the tape travel path movement changing member 100g is also separated by the retreat of the tape travel path movement changing member 120b. It is stored in the tool case 3.
At this time, since the engaging claws 30f of the winding core 30 are engaged with the radial grooves 110d even when the transfer tape T is stored, it is prevented from rotating in the direction opposite to the winding direction. Does not wind up. Therefore, when the transfer head 120 is housed in the transfer tool case 3, the tape travel path movement changing member 120b moves backward, and the transfer tape T that has passed through the tape travel path movement changing member 120b is moved by the tape travel path movement changing member 120b. The transfer tape T is accommodated by the pulled distance and the separation distance between the tape travel path movement changing member 120b and the tape travel path fixing / changing member 100g. By this pulling operation, the transfer coating film S attached to the transfer tape T located at the lower part of the transfer head 120 goes around the upper part of the transfer head 120 via the pressing part 120a.
With this configuration, when the transfer head 120 appears and disappears, the transfer tape T and the transfer coating film S are handled by the pressing portion 120a of the transfer head 120, so that the transfer tape T is slightly loosened in the transfer tool case 3. Need to be stored. Due to this configuration, the transfer coating film S adhering to the transfer tape T is not handled by the pressing portion of the transfer head 60a and the coating film is not peeled off. Further, at the time of coating film transfer, the transfer tape T that has already been transferred does not interfere with the tape travel path fixing / changing member 100f and does not receive frictional resistance, so that the transfer operation can be performed more smoothly. Therefore, by providing the tape travel path fixing / changing member 100g behind the transfer tool case 3 relative to the tape travel path moving / changing member 120b when the transfer head 120 is stored, The separation distance of the tape travel path fixing / changing member 100g is shorter than that in the first embodiment.

Because of the above-described configuration, it is fed from the feeding core 40, via the travel path member 100f, via the pressing portion 120a of the transfer head 120, and further via the tape travel path movement change member 120b and the tape travel path fixing change member 100g. The length of the transfer tape T taken up by the take-up core 30 is constant without being loosened during the protruding operation of the transfer head 120.
Further, when the transfer head 120 is protruded from the case opening 4, the transfer coating film S located on the upper part of the transfer head 120 is accommodated in the transfer tool case 3 by the pressing portion 120 a of the transfer head 120. The transfer tape T is pulled to return to the pressing portion 120a of the transfer head 120, and the transfer operation can be resumed.
Here, when the transfer tape T is loosened, a thin rod-like member (for example, a toothpick or a pen tip of a ballpoint pen) is inserted from the transfer tool case groove 100h and engaged with the take-up groove 40b, and the feeding core The slack is eliminated by rotating 40 counterclockwise. At that time, the winding core 30 also tries to rotate in conjunction with the feeding core 40, but the reverse rotation of the winding core 30 is prevented by the engagement between the engaging claws 30f and the radial grooves 110d. The take-up core 30 is prevented from rotating. That is, since the reverse rotation of the winding core 30 is prevented, even if the winding groove 40b is rotated, only the feeding core 40 is rotated, thereby eliminating the slack of the tape. Furthermore, since only the transfer coating film S is wound around the feeding core 40 again, the transfer coating film S is not wasted.
Further, since the winding diameter of the transfer tape T with respect to the feeding core 40 is smaller than the winding core 30, the tape winding speed by the winding core 3 is higher than the tape drawing speed from the feeding core 40, and the winding core 30 is always provided. However, it works to wind up the transfer tape T more than the feeding core 40. As a result, the used transfer tape T can be reliably wound around the winding core 30.
As described above, in the present embodiment, the feeding core 40 and the winding core 30 are provided on the same axis, but an independent shaft may be provided and interlocked using a gear, a timing bell, or the like.
In the present embodiment, the number of rollers 50 in the first embodiment can be reduced, and the number of parts can be reduced. As a result, the transfer coating film S can be prevented from being scratched as well as being inexpensively produced. The reason is that the transfer coating film S of the tape fed from the transfer tape T does not come into contact with other parts until it is transferred from the pressing portion 60a of the transfer head 60.

(Example 3)
The configuration of the coating film transfer tool of the third embodiment will be described based on the drawings of FIGS. 11, 12, and 13. The transfer tool case 5 includes a transfer tool case upper part 210 and a transfer tool case lower part 200. The transfer tool case lower part 200 has a bottomed box shape having a front wall 200a, a rear wall 200b, a right wall 200c, a left wall 200d and a bottom wall 200e. Similarly, the transfer tool case upper part 210 has a bottomed box shape having a front wall 210a, a rear wall 210b, a right wall 210c, a left wall 210d and a bottom wall 210e.
A projecting rotary shaft 200f is erected on the rear wall 200b side from the center in the lower part 200 of the transfer tool case, and the feeding core 220 is pivotally supported by the rotary shaft 200f. The feeding core 220 has a gear 220a in a portion near the bottom wall 200e of the transfer tool case lower part 200, and a cylindrical part 220b is formed on the upper part of the gear 220a. Further, a groove 220c is engraved on the upper portion of the cylindrical portion 220b of the feeding core 220. Further, in the transfer tool case lower part 200, a columnar travel path member 200g is erected on the right wall 220c side and in the vicinity of the rear wall 220b side from the rotating shaft 200f.
A slip member 230 is rotatably supported on the cylindrical portion 220b of the feeding core 220 in a state where a frictional resistance is applied. The slip member 230 includes two cylindrical portions having different outer diameters (a large diameter cylindrical portion 230a and a small diameter cylindrical portion 230b). Protrusions 230c are formed on the circumference of the inner diameter portion of the small diameter cylindrical portion 230b, while radial winding grooves 230d are formed radially above the large diameter cylindrical portion 230a.
The protrusion 230c formed on the inner surface of the small-diameter cylindrical portion 230b is fitted in a state of being pressed against the groove 220c formed in the cylindrical portion 220b of the feeding core 220. By this pressure contact action, a frictional resistance in the rotational direction of the slip member 230 with respect to the feeding core 220 is given, and they are assembled to each other and disassembly is prevented. A transfer tape T is wound around the slip member 230.

Further, a protruding rotating shaft 200h is erected on the front wall 200a side of the rotating shaft 200f of the transfer tool case lower part 200, and the winding shaft 240 having a smaller diameter than the feeding core 220 is provided on the rotating shaft 200h. Is supported. The take-up core 240 has a gear 240a at a portion close to the bottom surface of the transfer tool case lower portion 200, like the feeding core 220, and a cylindrical portion 240b is formed on the upper portion of the gear 240a. Further, the flat plate portion 240c of the gear 240a of the winding core 240 is formed with an engaging portion 240d that can be elastically deformed, and can be engaged with and disengaged from the radial groove 200i formed on the bottom surface of the lower part 200 of the transfer tool case. Is engaged.
The engaging portion 240d is formed as an arcuate engaging portion 240d by forming a "U" -shaped groove 240e in an arc shape in the flat plate portion 240c of the gear 240a, and the tip of the engaging portion 240d is formed. An engaging claw 240f is formed on the. The engaging claws 240f are formed so as to protrude from the lower surface of the flat slope 240c of the gear 240a, and are engaged with the radial grooves 200i in a detachable manner.
Further, a transfer head 250 is disposed in front of the winding core 240, and when the transfer tool case lower part 200 and the transfer tool case upper part 210 are fitted together, the case lower part in the vicinity where the transfer head 250 is disposed. Projection is possible from the opening 6 comprising the opening 200j and the case upper opening 210j. The transfer head 250 has a rectangular plate shape and is made of a material that can be elastically deformed.
Further, a pressing portion 250a having a substantially triangular cross section is formed at the front end portion of the transfer head 250. The pressing portion 250a is near the end opposite to the pressing portion 250a and close to the winding core 240. On the side, a tape travel path movement changing member 250b protruding in a columnar shape is disposed. Further, tape guides 250 c having a substantially triangular shape are formed on both sides in the width direction of the front portion of the transfer head 250.

An upper end portion of the tape travel path movement changing member 250b passes through a slide groove 210g formed in the transfer tool case upper part 210 and fits into a circular groove 260a of a slide member 260 provided outside the transfer tool case upper part 210. It is fixed. The groove 210g of the transfer tool case upper part 210 is formed from the opening 6 composed of the case lower opening part 200j and the case upper opening part 210j to the middle of the transfer tool case upper part 210, and is a rectangular long groove. Yes. Note that at least the length of the slide groove 210g is set in a range where the transfer head 250 can be accommodated from the state in which the transfer head 250 protrudes from the case opening 6.
The slide member 260 has a rectangular shape and is rounded so that the side of the upper surface has no corners, and the upper end of the tape travel path movement changing member 250b is fitted in the center of the bottom surface. A mating circular groove 260a is provided. Further, in the upper part of the transfer tool case 210, a transfer tool case groove 210i is formed along the shape of the take-up groove 230d above the winding groove 230d to form an arcuate groove.
Further, the transfer tool case lower part 200 is assembled with a transfer head 250 with respect to the transfer tool case 5, and in the vicinity of the tape travel path movement changing member 250b when the transfer head 250 is in the protruding state, the left wall 200d. On the side of the rear wall 200b, a protruding columnar tape travel path fixing / changing member 200o is erected.
Moreover, the transfer tool case lower part 200 and the transfer tool case upper part 210 have a rectangular shape, and the four corners are rounded. Furthermore, since the transfer tool case lower part 200 and the upper part 210 need to be fitted and fixed for use as a transfer tool, the interior of the transfer tool case lower part 200 other than the part where the case lower opening 200j is disposed. In the three corners, case connecting portions 200k, 200l, and 200m are arranged in a cylindrical shape.

On the other hand, case connection receiving portions 210k, 210l, and 210m are provided in three corners inside the transfer tool case upper portion 210 other than the place where the case upper opening portion 210j is provided. When the receiving parts 200k, 200l, and 200m are connected to the case connecting parts 210k, 210l, and 210m, the case upper part 210 and the case lower part 200 are fitted and fixed. Similarly, a bearing part 210n is formed in a cylindrical shape on the transfer tool case upper part 210, and is fitted to the rotary shaft 200h.
A plate-like movement restricting member 200h is disposed on the right wall 200c side near the case side surface of the slide groove 210e in the inner portion of the transfer tool case lower part 200. Similarly, a plate-like movement restricting member 210h is also disposed on the right wall 210c side near the case side surface of the slide groove 210e with respect to the transfer tool case upper part 210.
In this embodiment, the transfer tool case lower part 200, the transfer tool case upper part 210, the winding core 240, the feeding core 220, the slip member 230, the transfer head 250, the slide mechanism 260, and the transfer tape T are configured. ing.

Next, the operation of the present embodiment will be described with reference to FIGS. Since the tape travel path movement changing member 250b formed integrally with the transfer head 250 and the concave portion 260a positioned below the slide member 260 are connected, for example, the slide member 260 is connected to the case opening 6. When slid back and forth, the transfer head 250 appears and disappears from the case opening 6 of the transfer tool case 5.
During transfer of the correction tape, the transfer tape T fed from the feeding core 220 is fed toward the travel path member 200g, is folded back on the side surface on the rear wall 200e side of the travel path member 200g, and passes through the lower surface of the transfer head 250. Then, it goes to the transfer head pressing portion 250a. Then, the transfer tape T folded back at the pressing portion 250a of the transfer head 250 passes through the upper surface of the transfer head 250 from the transfer head pressing portion 250a and is folded back at the side surface on the rear wall 200b side of the tape travel path movement changing member 250b. Then, the tape travels to the tape travel path fixing change member 200o. The transfer tape T is folded at the side surface on the front wall 200a side of the tape travel path fixing / changing member 200o and wound around the side surface of the cylindrical portion 240b of the winding core 240.
Here, when the transfer head 250 is housed in the transfer tool case 5, the slide member 260 is moved to the rear of the transfer tool case 5 along the slide groove 210g. At this time, the tape travel path movement changing member 250b formed in the transfer head 250 also moves backward in conjunction with the slide member 260, and at the same time, the transfer tape T via the tape travel path movement changing member 250b is also transferred to the transfer tool case 5. Stored inside. Further, at that time, the transfer tape T between the tape travel path movement changing member 250b and the tape travel path movement changing member 200o is also separated by the backward movement of the tape travel path movement changing member 250b. It is stored in the tool case 1.
At this time, even when the transfer tape T is stored, the engaging claws 240f of the winding core 240 are engaged with the radial grooves 200i, so that it is prevented from rotating in the direction opposite to the winding direction. Does not wind up. Therefore, when the transfer head 250 is housed in the transfer tool case 5, the tape travel path movement changing member 250b moves backward, and the transfer tape T that has passed through the tape travel path movement changing member 250b is moved by the tape travel path movement changing member 250b. The transfer tape T is accommodated by the pulled distance and the separation distance between the tape travel path movement changing member 250b and the tape travel path fixing / changing member 200o.
By this pulling operation, the transfer coating film S attached to the transfer tape T located at the lower part of the transfer head 250 wraps around the pressing part 250 a above the transfer head 250. With this configuration, when the transfer head 250 appears and disappears, the transfer tape T and the transfer coating film S are handled by the pressing portion 250a of the transfer head 250, so that the transfer tape S is slightly loosened in the transfer tool case 5. Need to be stored. Therefore, when the transfer head 250 protrudes, the position of the tape travel path fixing / changing member 200o is formed behind the transfer tool case 5 relative to the tape travel path moving / changing member 250b.

Because of the above-described configuration, it is fed from the feeding core 220, via the travel path member 200g, via the pressing portion 250a of the transfer head 250, and further via the tape travel path movement change member 250b and the tape travel path fixing change member 200o. The length of the transfer tape T taken up by the take-up core 240 is constant without being loosened during the protruding operation of the transfer head 250.
Further, when the transfer head 250 is protruded from the case opening 6, the transfer coating film S located on the upper portion of the transfer head 250 is accommodated in the transfer tool case 5 by the pressing portion 250 a of the transfer head 250. The transfer tape T is pulled to return to the pressing portion 250a of the transfer head 250, and the transfer operation can be resumed.
Here, when the transfer tape T is loosened, a thin rod-like member (for example, a toothpick or a pen tip of a ballpoint pen) is inserted from the transfer tool case groove 210i and engaged with the take-up groove 230d. By rotating 230 clockwise, the slack is eliminated. At that time, the feeding core 220 and the winding core 240 that meshes with the feeding core 220 also try to rotate, but the reverse rotation of the winding core 240 is prevented by the engagement between the locking claws 240f and the radial grooves 200i. Therefore, the winding core 240 and the feeding core 220 are prevented from rotating. That is, since the reverse rotation of the winding core 240 is prevented, even if the winding groove 230d is rotated, only the slip member 230 is rotated, thereby eliminating the slack of the tape and transferring the transfer coating. Since only the film S is wound around the feeding core 220 again, the transfer coating film S is not wasted.
Further, even when the winding diameter of the transfer tape T with respect to the feeding core 220 is larger than the winding core 240, the feeding core so that the tape winding speed by the winding core 240 is higher than the tape drawing speed from the feeding core 220. Since the outer diameter of the gear 220 is larger than the winding diameter of the transfer tape T around the feeding core 220, the winding core 240 always functions to wind up the transfer tape T more than the feeding core 220. As a result, the used transfer tape T can be reliably wound around the winding core 240.
As described above, in this embodiment, the feeding core and the winding core are linked by the gear, but they may be linked by using a timing belt or the like.
In this embodiment, unlike the first and second embodiments, the winding core and the feeding core are not arranged on the same axis, so the width in the thickness direction of the transfer tool case Can be reduced, and slimming can be achieved.

Example 4
The configuration of the coating film transfer tool of the fourth embodiment will be described with reference to the drawings of FIGS. The transfer tool case 610 includes a transfer tool case upper part 602 and a transfer tool case lower part 601. A protruding rotating shaft 601d is erected from the center in the lower part of the transfer tool case 601. A feeding core 604 is pivotally supported by the rotating shaft 601d. The feeding core 604 has a gear 604b at a lower portion, that is, a portion near the bottom surface of the transfer tool case lower portion 601, and a cylindrical portion 604c is formed on the upper portion of the gear 604b. Further, a groove 604a is engraved in the upper part of the cylindrical portion 604c of the feeding core 604. Further, in the transfer tool case lower part 601, a columnar travel path member 601i is erected at a position near the inner wall of the transfer tool case lower part 601 above the rotation shaft 601d.
A slip member 605 is rotatably supported on the cylindrical portion 604c of the feeding core 604 while being provided with a frictional resistance. The slip member 605 includes two cylindrical portions (a large diameter cylindrical portion 605c and a small diameter cylindrical portion 605d) having different outer diameters. A projection 605b is formed on the circumference of the inner diameter portion of the small diameter cylindrical portion 605d, and on the other hand, a radially circular winding groove 605a is formed on the upper portion of the large diameter cylindrical portion 605c. The protrusion 605b formed on the inner surface of the small diameter cylindrical portion 605d is fitted in a state of being pressed into a groove 604a formed in the cylindrical portion 604c of the feeding core 604. By this pressure contact action, a frictional resistance in the rotational direction of the slip member 605 with respect to the feeding core 604 is given, and they are assembled with each other and disassembly is prevented. A transfer tape T is wound around the slip member 605.
In addition, a protruding rotating shaft 601e is erected in front of the rotating shaft 601d of the transfer tool case lower portion 601, and a winding core 603 having a smaller diameter than the feeding core 604 is pivotally supported on the rotating shaft 601e. Has been. Similar to the feeding core 604, the winding core 603 has a gear 603b near the bottom surface of the transfer tool case lower part 601, and a cylindrical part 603c is formed on the upper part of the gear 603b. Further, the flat plate portion 603d of the gear 603b of the winding core 603 is formed with an engaging portion 603a that can be elastically deformed, and can be engaged with and disengaged from the radial groove 601c formed on the bottom surface of the transfer tool case lower portion 601. Is engaged. The engaging portion 603a is formed as an arc-shaped engaging portion 603a by forming a "U" -shaped groove 603e in an arc shape on the flat plate portion 603d of the gear 603b, and the tip of the engaging portion 603a is formed. An engaging claw 603f is formed on the front side. The engaging claw 603f is formed in a state of protruding from the lower surface of the flat slope portion 603d of the gear 603b, and is engaged with the radial groove 601c so as to be detachable.
Further, a transfer head 606 is disposed in front of the winding core 603. When the transfer tool case lower part 601 and the upper part 602 are fitted, the case openings 601a and 602a in the vicinity of the transfer head 606 are disposed. Projection is possible from the opening 620 made of The transfer head 606 has a rectangular plate shape and is made of a material that can be elastically deformed. A pressing portion 606c having a substantially triangular cross section is formed at the front end portion of the transfer head 606. The pressing portion 606c is near the end opposite to the pressing portion 606c and close to the winding core 603. On the side, a travel path changing member 606b protruding in a columnar shape is disposed. Further, tape guides 606 a having a substantially triangular shape are formed on both sides in the width direction of the front portion of the transfer head 606.

An upper end portion of the travel path changing member 606b passes through a slide groove 602c formed in the transfer tool case upper part 602, and fits into a circular groove 607a of a slide member 607 provided outside the transfer tool case upper part 602. It is fixed. The groove 602c of the transfer tool case upper part 602 is formed from the opening 620 formed by the case openings 601a and 602a to the middle of the transfer tool case upper part 602, and is a rectangular long groove. Note that at least the length of the slide groove 602c is set in a range from the state in which the transfer head 606 protrudes from the case opening 620 to the state in which it can be stored. The slide member 607 has a rectangular shape and is rounded so that the side of the upper surface has no corners, and the upper end of the travel path changing member 606b is fitted in the center of the bottom surface. A circular groove 607a is provided. Further, in the transfer tool case upper portion 602, a transfer tool case groove 602d is formed along the shape of the take-up groove 605a above the take-up groove 605a to form an arcuate groove.
Further, the transfer tool case lower part 601 and the transfer tool case upper part 602 have a rectangular shape, and the four corners are rounded. Further, since it is necessary to fit and fix the transfer tool case lower part 601 and the upper part 602 for use as a transfer tool, 3 inside the transfer tool case lower part 601 other than the place where the case opening 601a is disposed. Case connecting portions 601f, 601g, and 601h are disposed in the corners in a cylindrical shape. On the other hand, case connection receiving portions 602f, 602g, and 602h are provided on the cylinders at the three corners inside the transfer tool case upper portion 601 other than the location where the case opening 602a is provided. The case upper portion 602 and the case lower portion 601 are fitted and fixed by connecting the portions 602f, 602g, and 602h to the case connecting portions 601f, 601g, and 601h, respectively.
Further, a plate-like movement regulating member 601b is disposed on the wall side near the case side surface of the slide groove 602c in the inner portion of the transfer tool case lower part 601. Similarly, a plate-like movement restricting member 602b is also arranged on the wall side near the case side surface of the slide groove 602c with respect to the transfer tool case upper portion 602.
In this embodiment, the transfer tool case lower portion 601, the transfer tool case upper portion 602, the winding core 603, the feeding core 604, the slip member 605, the transfer head 606, the slide mechanism 607, and the transfer tape T are configured. ing.

Next, the operation of this embodiment will be described. Since the travel path changing member 606b formed integrally with the transfer head 606 and the recess 607a positioned at the lower portion of the slide member 607 are connected, for example, the slide member 607 is moved forward and backward with respect to the case opening 620. When slid, the transfer head 606 appears and disappears from the case opening 620 of the transfer tool case 610.
Next, description will be made with reference to FIG. At the time of transfer of the correction tape, the transfer tape T is fed from the feeding core 604, winds the pressing portion 606c of the transfer head 606 via the travel path member 601i, and further winds the winding core 603 via the travel path changing member 606b. It is the structure wound up by.
Here, when the transfer head 606 is housed in the transfer tool case 610, the slide member 607 is moved to the rear of the transfer tool case 610 along the slide groove 602c. At this time, the travel path changing member 606b formed on the transfer head 606 is also retracted in conjunction with the slide member 607, and at the same time, the transfer tape T via the travel path changing member 606b is also stored in the transfer tool case 610. The At this time, even when the transfer tape T is stored, the engaging portion 603a of the winding core 603 is engaged with the radial groove 601c, so that it is prevented from rotating in the direction opposite to the winding direction, and the tape is wound. I don't take it. Therefore, as shown in FIG. 19, when the transfer head 606 is housed in the transfer tool case 610, the travel path changing member 606d moves backward, and the transfer tape T that has passed through the travel path changing member 606d is also moved by the travel path changing member 606d. It is pulled and stored. By this pulling operation, the transfer coating film S attached to the transfer tape T located at the lower part of the transfer head 606 wraps around the upper part of the transfer head 606. Because of the above-described configuration, the length of the transfer tape T that is fed from the feed core 604 and taken up by the take-up core 603 through the transfer head 606 and further through the travel path changing member 606b is the operation of immersing the transfer head 606. It is constant without sagging even at times.

Further, when the transfer head 606 is protruded from the opening 620, the transfer coating film S located on the upper portion of the transfer head 606 is transferred to the transfer tool case 610 by the pressing portion 606c of the transfer head 606. The tape T is pulled to return to the lower part of the transfer head 606, and the transfer operation can be resumed. (See Figure 20)
Here, when the transfer tape T is loosened, a thin rod-like member (for example, a toothpick or a pen tip of a ballpoint pen) is inserted from the transfer tool case groove 602d and engaged with the take-up groove 605a, and the slip member The slack is eliminated by rotating 605 clockwise. At this time, the feeding core 604 and the winding core 603 that meshes with the feeding core 604 also try to rotate, but the reverse rotation of the winding core 603 is prevented by the engagement between the engaging portion 603a and the radial groove 601c. Therefore, the winding core 603 and the feeding core 604 are prevented from rotating. That is, since the reverse rotation of the winding core 603 is prevented, even if the winding groove 605a is rotated, only the slip member 605 is rotated, thereby eliminating the slack of the tape.
Further, even when the winding diameter of the transfer tape T with respect to the feeding core 604 is larger than the winding core 603, the feeding core is set so that the tape winding speed by the winding core 603 is higher than the tape drawing speed from the feeding core 604. Since the outer diameter of the gear 604 is larger than the winding diameter of the transfer tape T around the feeding core 604, the winding core 603 always works to wind up the transfer tape T more than the feeding core 604. As a result, the used transfer tape T can be reliably wound around the winding core 603.
As described above, in this embodiment, the feeding core and the winding core are linked by the gear, but they may be linked by using a timing belt or the like.

The above configuration is a basic configuration, which will be described more specifically. The transfer tool case 610 is a resin molded product such as acrylonitrile / styrene copolymer resin, acrylonitrile / buditaene / styrene copolymer, reinforced polyethylene terephthalate, polycarbonate resin, polystyrene, or methacrylic resin. Further, the thickness of the transfer tool case 610 is preferably in the range of 0.5 mm to 2.0 mm. Incidentally, if it exceeds 2.0 mm, it becomes difficult to cool the molded product after molding, and if the thickness is less than 0.5 mm, there is a risk that the strength is impaired.
The transfer tape T is a transfer film S having adhesive properties such as a character correction coating film, a decorative colored coating film, an adhesive pressure-sensitive adhesive film, and a fluorescent coating film on the surface of a synthetic resin transfer tape T as a base material. It has.
The transfer tape T is wound around the slip member 605, and the transfer tape T fed from the feeding core 604 is pressed against the transfer surface such as paper from the back side of the transfer tape T by the transfer head 606, The transfer coating film S is transferred to the transfer surface. Further, the used transfer tape T (transfer tape as a base material) after passing through the transfer head 606 is wound up by a winding core 603. The transfer head 606 is preferably made of a material such as polyacetal resin, polypropylene resin, metal (stainless steel, brass, piano wire, etc.) in consideration of slidability, durability, and flexibility.
As materials for the feeding core 604 and the take-up core 603, if they are connected by a gear mechanism to transmit the rotation, slidable and durable polyacetal resin, polypropylene resin, polybutylene terephthalate, acrylonitrile, It is preferable to use a resin material such as a styrene copolymer resin, an acrylonitrile / buditaene / styrene copolymer, a reinforced polyethylene terephthalate, a polycarbonate resin, a polystyrene, or a methacrylic resin.

(Example 5)
Next, the structure of the coating film transfer tool of 5th Embodiment is demonstrated based on drawing of FIGS. 21-26. The description of the same configuration as that of the fourth embodiment is omitted. In addition, in the figure, the same code | symbol is attached | subjected about the structure similar to Example 4. FIG.
In the transfer tool case lower part 601, a travel path member 601i is erected in a columnar shape at a location near the inner wall of the transfer tool case lower part 601 below the rotation shaft 601d.
The transfer head 616 has a rectangular plate portion 616i. Cylindrical cylindrical portions 616g and 616h are integrally formed at both ends thereof, and the cylindrical portions 616g and 616h are formed at the centers. Are provided with through holes 606b and 606c, respectively. Furthermore, a plate-like travel path changing member 616e is formed in a “<” shape in a cylindrical shape 616h in which the through hole 616c is formed. A hinge-like movable portion 616a is provided at the central portion of the plate portion 616i between the through holes 616b and 616c, and the plate portion 616i bends and expands around the movable portion 616a. A rectangular through hole 616d is formed between the movable portion 616a and the through hole 616b and between the movable portion 616a and the through hole 616c. The travel route changing member 616e is also formed with a rectangular through hole 616f.
A head fixing portion 601j erected in a columnar shape is disposed near the lower end of the opening 620 in the upper portion of the connecting portion 601f inside the case of the transfer tool case lower portion 601, and a through hole 616b of the transfer head 616 is provided. Is rotatably supported. The through hole 616 c of the transfer head 616 is pivotally attached to a columnar head shaft 618 and is rotated with respect to the head shaft 618.
A head bearing groove 601k, which is a rectangular groove with respect to the width direction of the transfer tool case 610, is formed behind the case opening 601a inside the transfer tool case lower part 601 and in front of the winding core 603. . In addition, a slide groove 602k is formed as a through hole at the same position on the transfer tool case upper portion 602 as well.
A slide member 617 is provided as in the fourth embodiment, but a circular groove 617 a of the slide member 617 is fitted and fixed to the upper portion of the head shaft 618. More specifically, the upper end portion of the head shaft 618 passes through a slide groove 602k formed in the transfer tool case upper portion 602, and a circular groove 617a of a slide member 617 provided outside the transfer tool case upper portion 602. It is fitted and fixed to.
In this embodiment, the transfer tool case lower part 601, the transfer tool case upper part 602, the take-up core 603, the feeding core 604, the slip member 605, the transfer head 616, the slide member 617, the head shaft 618, and the transfer tape T It consists of parts.

Next, the operation of this embodiment will be described. Since the travel path changing member 616e formed integrally with the transfer head 616 and the groove 617a located at the lower part of the slide mechanism 617 are connected, the slide mechanism 617 is moved in the width direction of the transfer tool case 610, that is, When slid in the vertical direction, the transfer head 616 can appear and disappear from the transfer tool case 610 while bending and expanding. Incidentally, when the transfer head 616 is housed in the transfer tool case 610, the transfer head 616 is in a state in which three portions of the through hole 616b, the movable portion 616a, and the through hole 616c are arranged in the same straight line. On the other hand, when the transfer head 616 protrudes from the transfer tool case 610, the three portions of the through-hole 616b, the movable portion 616a, and the through-hole 616c become the apex of the triangle, and the movable portion 616a is implemented. The pressing portion corresponds to Example 4.
Next, a description will be given based on FIGS. At the time of transfer of the correction tape, the transfer tape T is fed out from the feeding core 604, passes through the through hole 616d near the through hole 616b of the transfer head 616 via the travel path member 601i, winds the movable portion 616a, and passes through the through hole 616c. It passes through the through hole 616d close to, passes through the through hole 616f of the travel path changing member 616e, and is wound by the winding core 603. At this time, the transfer tape T penetrates almost the center of the through hole 616f, that is, the transfer tape T can be fed out without contact with the edge of the through hole 616f.

Here, when the transfer head 616 is stored in the transfer tool case 610, the slide mechanism 617 is moved upward in the width direction of the transfer tool case 610 along the slide groove 602k. At this time, the travel path changing member 616e also operates in conjunction with the slide mechanism 617, and at the same time, the transfer tape T passing through the through hole 616f is pulled upward via the lower end portion of the travel path changing member 616e, The tape T is also accommodated in the transfer tool case 610. Even when the transfer tape T is stored, the take-up core 603 is prevented from rotating in the direction opposite to the take-up direction by the radial grooves 601c and the engaging portions 603a, and therefore the tape is not taken up. Therefore, as shown in FIG. 23, when the transfer head 616 is housed in the transfer tool case 610, the travel path changing member 616e rotates upward, and the transfer tape T that has passed through the travel path changing member 616e is also moved by the travel path changing member 616e. It is pulled by and stored. Because of the above-described configuration, the length of the transfer tape T that is fed from the feed core 604 and taken up by the take-up core 603 is constant without being loosened even during the immersing operation of the transfer head 616.
When the transfer head 616 is protruded from the opening 620, the transfer tape T via the transfer head 616 is pulled out by the movable portion 616a of the transfer head 616, and returns to a transferable state before being stored. The transfer operation can be resumed (see FIG. 24).
When the transfer tape T is loosened, the looseness is eliminated by winding the transfer tape T by the same means as in the fourth embodiment.

(Example 6)
Next, the structure of the coating film transfer tool of 6th Embodiment is demonstrated based on drawing of FIGS. The description of the same configuration as in the first embodiment is omitted. In addition, in the figure, the same code | symbol is attached | subjected about the structure similar to Example 1. FIG.
The transfer tool case 7a includes a transfer tool case lower part 310 and a transfer tool case upper part 320. The transfer tool case lower part 310 includes a front wall 310a, a rear wall 310b, a right wall 310c, a left wall 310d and a bottom wall 310e. It has a bottomed box shape. In addition, a projecting rotating shaft 310f is erected at the center of the transfer tool case lower portion 310, and the winding core 30 is rotatably supported on the rotating shaft 310f.
An engagement claw 30f is formed on the winding core 30, and the engagement claw 30f is detachably engaged with a radial groove 320k formed from the bottom surface of the transfer tool case upper portion 320. As in the first embodiment, the inner side of the feeding core 40 is fitted in a state of being pressed against the side surface of the slip portion 30a. As a result, the feeding core 40 is rotatably supported in a state in which a frictional resistance is applied, and a frictional resistance in the rotational direction with respect to the slip portion 30a of the feeding core 40 is given, and each other is assembled and disassembled. Is prevented. A transfer tape T is wound around the feeding core 40.

Further, in the bottom wall 310e of the transfer tool case lower part 310, a cylindrical assembly part 310g is provided in the vicinity of the front wall 310a on the left wall 310d side, and a cylindrical assembly part is provided in the vicinity of the rear wall 310b. 310h is formed. In the front wall 310a, a case lower opening 310k is vacated as a rectangular through hole in the vicinity of the right wall 310c. Two parallel rows of walls are formed along the right wall 310c of the lower part of the transfer tool case 310 up to the vicinity of the rear wall 310b on the side opposite to the side near the right wall 310c of the case lower opening 310k. The two rows of walls are the guide rail 310l and the guide rail 310m, and one guide rail 310m is formed only up to the center. Guide grooves 310n and 310o are formed as through holes in the vicinity of the upper portions of the opposing walls of the guide rails 310l and 310m, respectively.
In addition, a tape travel path fixing change member 310p is erected in a columnar shape near the outside of the guide rail 310m on the bottom wall 310e of the transfer tool case lower part 310 in the right wall 310c direction from the rotation shaft 310f. ing. A columnar spring installation portion lower part 310i is formed in the vicinity of the right wall 310c on the rear wall 310b side of the bottom wall 310e. On the upper surface of the spring installation part lower part 310i, a spring installation part upper part 310j smaller than the outer diameter of the spring installation part lower part 310i is erected in a columnar shape. Further, a cylindrical roller 350 having an inner diameter larger than the outer shape of the tape travel path fixing change member 310p is rotatably supported on the tape travel path fixing change member 310p.

On the other hand, the transfer tool case upper part 320 has a bottomed box shape having a front wall 320a, a rear wall 320b, a right wall 320c, a left wall 320d and a bottom wall 320e, and has the same shape as the transfer tool case lower part 310. It has a bottom surface. Also, cylindrical assembly parts 320g and 320h are formed on the bottom wall 320e of the transfer tool case upper part 320, and are fitted and assembled with the assembly parts 310g and 310h of the transfer tool case lower part 310.
Similarly, the assembling portion 320f and the assembling portion 320i also have a cylindrical shape, and are an assembling portion 320f that can be fitted to the rotating shaft 310f and an assembling portion 320i that can be fitted to the tape travel path fixing change member 310p. , Each assembled. A cylindrical anti-reverse member 320l having an inner diameter larger than the outer shape of the assembly portion 320f is formed around the rotation shaft 310f, and is formed at the upper end of the anti-reverse member 320l. Are formed with radial grooves 320k. The transfer tool case upper part 320 is formed with a case upper opening 320j at the same position as the transfer tool case lower part 310, and the case opening 7b is formed by matching with the case lower opening 310k. Is done.
A guide groove 320m is formed as a rectangular groove on the top surface of the transfer tool case upper portion 320 in the vicinity of the case opening 320j and in the vicinity of the right wall 320c up to the vicinity of the rear wall 320b. A transfer head guide hole 320n is formed in the guide groove 320m from the vicinity of the front wall 320a to the rear. The transfer head guide hole 320n is smaller in width than the guide groove 320m and has a rectangular shape. ing.
Within the guide groove 320m, a rectangular button guide hole 320o is formed at the substantially central portion of the guide groove 320m behind the transfer head guide hole 320n. In addition, a U-shaped hinge groove 320p in the guide groove 320m and closer to the rear wall 320b than the button guide groove 320o is near the center of the upper portion 320 of the transfer tool case with the left wall 320d opened. Is formed. A release button portion 320q that is a cylindrical protrusion is formed between the grooves of the hinge groove 320p. In addition, on the transfer tool case upper portion 320, a slide button locking portion 320r protrudes in a rectangular shape near the button guide groove 320o surrounded by the hinge groove 320p on the right wall 320c side from the release button portion 320q. It is installed.

The transfer head 360 has a rectangular plate shape and is made of a material that can be elastically deformed. Further, a pressing portion 360a having a substantially triangular cross section is formed at the front end portion of the transfer head 360, and a columnar shape is provided in the vicinity of the end opposite to the pressing portion 360a. A tape travel path movement changing member 360b and a spring installation portion 360h are provided. The spring installation portion 360h is disposed at the rear end of the transfer head 360 rather than the tape travel path movement changing member 360b.
Further, the side opposite to the surface on which the tape travel path movement changing member 360 b is disposed, is substantially the center portion of the transfer head 360, and the end portions on both side surfaces of the transfer head 360 are long. Rectangular slide protrusions 360c and 360d are provided upright. Locking protrusions 360e and 360f having a substantially triangular shape are formed inside the upper ends of the slide protrusions 360c and 360d. Also, tape guides 360g having a substantially triangular shape are formed on both sides in the width direction of the front portion of the transfer head 360. Incidentally, the plate thickness of the transfer head 360 is thinner than the guide grooves 310n and 310o, and the width is smaller than the width sandwiched between the guide grooves 310n and 310o, and within the guide grooves 310n and 310o. It can slide.
When the transfer head 360, the transfer tool case upper part 320, and the transfer tool case lower part 310 are assembled, the slide protrusions 360c and 360d of the transfer head 360 protrude from the transfer head guide holes 320n of the transfer tool case upper part 320. It becomes a state. As with the transfer head 360, the slide button 370 connected to the transfer head 360 has a rectangular plate shape and is made of a material that can be elastically deformed.

At the front end of the slide button 370, a button slide portion 370a, which is a rectangular projection, is formed. The button slide portion 370a is formed with a transfer head fitting hole 370b, which is a rectangular hole. In addition, it can be locked by the locking protrusions 360e and 360f of the transfer head 360 inserted from the transfer head fitting hole 370b and the guide groove 320m of the transfer tool case upper portion 320. Further, a rectangular case-sliding portion 370c is projected from the center of the sliding button 370 on the side where the button sliding portion 370a is formed, and an upper portion of the case sliding portion 370c. Is formed with a slide locking portion 370d, which is a rectangular protrusion larger than the upper surface of the case slide portion 370c.
Further, an elastic repulsion portion 370e is formed as a substantially triangular protrusion at the rear end of the slide button 370, and a button slip on the surface of the slide button 370 opposite to the case slide portion 370c. The stop portion 370f is formed as a plurality of substantially triangular projections, and is formed from the center portion to the end portion.
A tension coil spring 380 is engaged with the transfer head 360, and hooks 380 a and 380 b are provided at both ends of the tension coil spring 380. The hook 380 a is designed to be fitted to the spring installation part 360 h of the transfer head 360, and the hook 380 b is designed to be fitted to the spring installation part upper part 310 j of the transfer tool case lower part 310.
In this embodiment, the transfer tool case lower part 310, the transfer tool case upper part 320, the winding core 30, the feeding core 40, the roller 350, the transfer head 360, the slide button 370, the tension coil spring 380, and the transfer tape T It consists of parts.

Next, the operation of this embodiment will be described with reference to FIGS. Since the slide button 370 is locked by the locking protrusions 360e and 360f of the transfer head 360 inserted from the transfer head fitting hole 370b and the guide groove 320m of the transfer tool case upper part 320, for example, the slide button 370 Is slid back and forth with respect to the case opening 7b, the transfer head 360 protrudes / immerses from the case opening 7b of the transfer tool case 7a.
When projecting the transfer head 360, the slide button 370 is slid toward the case opening 7b. However, in order to maintain the projecting state of the transfer head 360, the elastic repulsion portion 370e of the slide button 370 is formed on the upper portion 320 of the transfer tool case 320. The slide button engagement portion 320r is engaged. When the transfer head 360 is housed in the transfer tool case 7a, the assembled tension coil spring 380 is kept in a normal state. However, as the transfer head 360 protrudes, the spring installation portion 360h is also changed. Since it protrudes toward the case opening 7a, the tension coil spring 380 is pulled by the spring installation part upper part 310j and the spring installation part 360h.
Here, when the transfer head 360 is stored in the transfer tool case 7a, the elastic repulsion part 370e and the slide button locking part 320r are unlocked, and the tension pulled when the transfer head 360 protrudes is released. The transfer head 360 is accommodated in the transfer tool case 7a by using the force with which the coil spring 380 returns. As an operation for releasing the lock, the release button portion 320q is pushed toward the lower part 310 of the transfer tool case to bend at both ends of the hinge groove 320p, which is a U-shaped groove, and interlocked therewith. Since the slide button locking part 320r is also pushed into the transfer tool case lower part 310 side, the lock is released and the transfer head 360 is stored in the transfer tool case 7a.
Because of the above configuration, when the transfer head 360 protrudes, it is performed by a slide operation. When the transfer head 360 is retracted, the transfer head 360 can be retracted by one-touch operation by simply pressing the release button part 320q. It is possible.
Furthermore, since the transfer head 360 is protruded by a slide operation, there is a concern that the transfer head 360 may inadvertently protrude even when the film transfer tool is accommodated in a container such as a pencil case. It is possible to prevent the transfer head 360 and the coating film S from being damaged.

  When the correction tape is transferred, the transfer tape T fed from the feed core 40 is fed toward the tape travel path fixing / changing member 310p, folded back on the side surface on the front wall 310a side of the roller 350, and the tape travel of the transfer head 360. It goes to the route movement changing member 360b. At this time, the transfer coating film S side of the transfer tape T contacts the side surface of the roller 350. Since the roller 350 is rotatably supported by the tape travel path fixing / changing member 310p, the transfer tape T can be smoothly fed out. Damage to the surface is prevented. Then, the side of the tape travel path movement changing member 360b on the side of the rear wall 310b of the tape travel path is folded back while contacting the transfer tape T, passes through the lower surface of the transfer head 360, and the transfer tape pressing portion 360a contacts the transfer tape T side. Wrapped while. The folded transfer tape T passes from the transfer head pressing portion 360a to the upper surface of the transfer head 360, and to the upper portion of the roller 350 while passing between the slide protrusions 360c and 360d. The transfer tape T folded back on the side surface on the right wall 310 c side of the upper portion of the roller 350 and on the rear wall 310 b side is wound up by the winding portion 30 b of the winding core 30. Further, the surface of the tape that is folded back and brought into contact with the side surface on the rear wall 310b side may be on the transfer tape T side or on the transfer coating film S side, but there is no damage to the coating film. The tape T side is desirable.

Here, when storing the transfer head 360 in the transfer tool case 7a, the release button portion 320q is pushed toward the lower side of the transfer tool case 310, and the slide button 370 is moved backward along the guide groove 320m to the transfer tool case 7a. Move. At this time, the tape travel path movement changing member 360b formed on the transfer head 360 also moves backward in conjunction with the slide button 370, and at the same time, the transfer tape T via the tape travel path movement changing member 360b is transferred to the transfer tool case 7a. Stored inside. Further, at that time, the transfer tape T between the tape travel path movement changing member 360b and the tape travel path movement changing member 310p is also separated by the retreat of the tape travel path movement changing member 360b. Housed in the tool case 7a. At this time, even when the transfer tape T is stored, the engaging portion 30d of the winding core 30 is engaged with the radial groove 320k, so that it is prevented from rotating in the direction opposite to the winding direction. The transfer tape T is not wound up.
Therefore, when the transfer head 360 is housed in the transfer tool case 7a, the tape travel path movement changing member 360b moves backward, and the transfer tape T that has passed through the tape travel path change member 360b is pulled by the tape travel path movement changing member 360b. The transfer tape T is accommodated by being pulled by the distance and the separation distance between the tape travel path movement changing member 360b and the tape travel path fixing / changing member 310p. That is, the transfer tape T is moved and stored approximately twice as much as the moving distance of the tape travel path changing member 360b.

By this pulling operation, the transfer coating film S applied to the transfer tape T located under the transfer head 360 is stored behind the transfer head 360. Because of this configuration, it is fed out from the feeding core 40 and is folded back at the pressing portion 360a of the transfer head 360 via the roller 350 having the tape running path fixing / changing member 310p as an axis and via the tape running path movement changing member 360b. The length of the transfer tape T that passes between the slide protrusions 360c and 360d and is taken up by the take-up portion 30b of the take-up core 30 through the upper portion of the roller 350 is constant without being loosened even during the immersion operation of the transfer head 360. It is.
The transfer tape T is in a state that does not always slack during the retracting operation, and is attached to the transfer tape T that is positioned below the transfer head 360 when the transfer head 360 described above is stored. Due to the configuration in which the transferred coating film S is stored behind the transfer head 360, the transfer coating film S is prevented from being damaged. At the same time, since the transfer tape T to which the transfer coating film S adheres does not interfere with the pressing portion 360a, the coating film peeling of the transfer coating film S from the transfer tape T is also prevented.
In addition, since the transfer tape T does not always slack when the transfer head 360 moves in and out, when the transfer head 360 is stored in the transfer tool case 7a, the transfer head 360 can be stored in the end of the case opening 7b. . That is, even if the transfer head 360 is at the end of the case opening 7b, the transfer tape T is protected because the transfer tape T is accommodated in the transfer tool case 7a. In addition, because of the above configuration, there is no need to house the transfer head 360 in the transfer tool case 7a, and there is an advantage that the transfer tool case 7a can be slimmed.

When the transfer head 360 is protruded from the case opening 7b, the transfer coating film S located at the lower rear of the transfer head 360 is stored in the transfer tool case 7a by the protrusion operation of the pressing portion 360a of the transfer head 360. Together with the transfer tape T, the transfer head 360 is pulled out to the tip (pressing portion 360a). This is because when the transfer head 360 described above is housed in the transfer tool case 7a, the tape travel path movement changing member 360b moves backward, and the transfer tape T that has passed through the tape travel path change member 360b moves to the tape travel path. This is because the transfer tape T is accommodated by the distance pulled by the change member 360b and the separation distance between the tape travel path movement change member 360b and the tape travel path fixing change member 310p. This is because only the transfer tape T located at the bottom is accommodated in the transfer tool case 7a.
Furthermore, when the transfer head 360 is projected, only the transfer tape T accommodated in the transfer tool case 7a is projected by the pressing portion 360a of the transfer head 360. Therefore, when the transfer head 360 is in the projected state, The transfer coating film S is configured such that the position of the coating film always comes to the tip of the transfer head 360. Further, since the winding diameter of the transfer tape T with respect to the feeding core 40 is smaller than the winding core 30, the tape winding speed by the winding core 30 becomes faster than the tape drawing speed from the feeding core 40, and the winding core 30 is always provided. However, it works to wind up the transfer tape T more than the feeding core 40.
As a result, the used transfer tape T can be reliably wound around the winding core 30.
As described above, in the present embodiment, the feeding core 40 and the take-up core 30 are provided on the same axis, but an independent shaft may be provided and interlocked using a gear, a timing bell, or the like.

(Example 7)
Next, the structure of the coating film transfer tool of 7th Embodiment is demonstrated based on drawing of FIGS. The description of the same configuration as that of the sixth embodiment is omitted. In addition, in the figure, the same code | symbol is attached | subjected about the structure similar to Example 6. FIG. The transfer tool case 8 a includes a transfer tool case lower part 410 and a transfer tool case upper part 420. The transfer tool case lower portion 410 has a bottomed box shape having a front wall 410a, a rear wall 410b, a right wall 410c, a left wall 410d, and a bottom wall 410e. The projecting rotary shaft 410f is erected, and the winding core 30 is rotatably supported on the rotary shaft 410f. An engagement claw 30f is formed on the winding core 30, and the engagement claw 30f is detachably engaged with a radial groove 420k formed from the bottom surface of the transfer tool case upper portion 420.

Further, in the bottom wall 410e of the lower part 410 of the transfer tool case, a columnar mounting portion 410g is formed in the vicinity of the front wall 410a on the left wall 410d side, and a columnar mounting portion 410h is also formed in the vicinity of the rear wall 410b. ing. A rectangular case lower opening 410k is formed as a through hole in the front wall 410a and in the vicinity of the right wall 410c. Furthermore, two rows of parallel walls are formed along the right wall 410c of the transfer tool case lower portion 410 to the vicinity of the rear wall 410b on the side surface opposite to the side surface in the vicinity of the right wall 410c of the case lower opening portion 410k. Although functioning as the guide rail 410l, one guide rail 410m is formed only to the vicinity of the center. Guide grooves 410n and 410o are formed as through holes in the vicinity of the upper part of the facing walls of the guide rails 410l and 410m. Furthermore, a guide rail 410j having a shape similar to that of the guide rail 410m is disposed in the vicinity of the right wall 410c, is disposed from the rear wall 410b, and has a guide groove 410r.
Further, a cylindrical tape travel path fixing / changing member 410i is erected on the bottom wall 410e of the transfer tool case lower part 410 in the vicinity of the outer side of the guide rail 410m in the direction of the right wall 410c from the rotation shaft 410f. In addition, a rectangular guide wall 410p is formed in the vicinity of the right wall 410c on the rear wall 410b side of the bottom wall 410e. A spring mounting portion 410q is formed in a columnar shape on the upper surface of the guide wall 410p on the rear wall 410b side.

On the other hand, the transfer tool case upper part 420 has a bottomed box shape having a front wall 420a, a rear wall 420b, a right wall 420c, a left wall 420d and a bottom wall 420e, and has the same shape as the transfer tool case lower part 410. In addition to having a bottom surface, a knock in / out hole 420p is formed as a through hole in a corner formed by the rear wall 420b and the right wall 420c of the transfer tool case upper part 420. Also, cylindrical assembly parts 420g and 420h are formed on the bottom wall 420e of the transfer tool case upper part 420, and can be fitted to the assembly parts 410g and 410h of the transfer tool case lower part 410. Similarly, the assembling portion 420f and the assembling portion 420i also have a cylindrical shape, and are an assembling portion 420f that can be fitted to the rotating shaft 410f and an assembling portion 420i that can be fitted to the tape travel path fixing changing member 410i. . Further, the transfer tool case upper part 420 is formed with a cylindrical anti-reverse member 420l having an inner diameter larger than the outer diameter of the assembling part 420f with the rotating shaft 410f as the center. The groove 420k is formed.
Further, the transfer tool case upper part 420 is formed with a case upper opening 420j at the same location as the transfer tool case lower part 410, and the case upper opening 420j and the case lower opening 410k form a case opening. 8b is formed. In addition, a button hinge hole 420n, which is a U-shaped hole, is open to the case opening 420j near the case opening 420j and in the vicinity of the right wall 420c on the top surface of the transfer tool case upper part 420. It is formed in shape. A cylindrical upper tape traveling path 420m is formed in the transfer tool case upper part 420, and the cylindrical upper tape traveling path 420m is on the right wall 420c side from the assembling part 420f, and the assembling part 420i. It is formed on the rear wall 420b side.
The width of the U-shaped hole of the button hinge hole 420n is substantially the same size as the case opening 420j, and the transfer tool case upper part 420 sandwiched between the grooves of the button hinge hole 420n. A release button portion 420o that is a triangular prism-shaped protrusion is formed on the top surface.
The hinge locking portion 420q is on the rear wall 420b side in the vicinity of the button hinge hole 420n on the surface opposite to the release button portion 420o, and has a protrusion having a width substantially equal to the button hinge hole 420n.

A knock portion 450 is disposed in the knock in / out hole 420p, and the knock portion 450 has a rectangular parallelepiped shape. A slide protrusion 450a, which is a rectangular parallelepiped protrusion, is formed at the center of one surface of the knock part 450 from the front end to the rear end, and the slide protrusion 450a is formed on the guide rail 410j. The projection is a rectangular parallelepiped smaller than the guide groove 410r. Further, a slide protrusion 450b having the same shape is formed on the surface opposite to the slide protrusion 450a, and one of the surfaces sandwiched in the short direction of the slide protrusions 450a and 450b is the surface of the surface. A knock fitting portion 450c which is a groove having a shape similar to that of the shape and smaller than the surface is formed.
The groove of the knock fitting portion 450c on the lower surface of the slide protrusion 450a is referred to as a head fitting portion 450d, and the groove of the knock fitting portion 450c on the lower surface of the slide protrusion 450b is referred to as a head fitting portion 450e. . The transfer head 460 has a rectangular plate shape and is made of a material that can be elastically deformed. In addition, a pressing portion 460a having a substantially triangular cross section is formed at the front end portion of the transfer head 460, and a cylindrical tape running path is formed at a substantially central portion in the longitudinal direction of the transfer head 460. A movement changing member 460b is provided. On the surface opposite to the tape travel path movement changing member 460b, a hinge portion 460c, which is an L-shaped protrusion, is erected substantially at the center of the transfer head 460, and the transfer head of the hinge portion 460c. A locking portion 460d is provided as a protrusion at the end opposite to the base of 460.
Further, a rectangular slot 460e is formed from the vicinity of the root portion of the hinge portion 460c at the substantially central portion of the transfer head 460 to the vicinity of the rear end portion of the transfer head 460. A spring mounting portion 460f is disposed as a cylindrical protrusion on the thick portion of the transfer head 460 at the rear end of the elongated hole 460e.
Further, tape guides 460g having a substantially triangular shape are formed on both sides in the width direction of the front portion of the transfer head 460. The plate thickness of the transfer head 460 is thinner than the guide grooves 410n and 410o. The width of the transfer head 460 is smaller than the width between the guide grooves 410n and 410o, and the transfer head 460 is slid in the guide grooves 410n and 410o. Since the rear end portion of the transfer head 460 is fitted to the head fitting portions 450d and 450e of 450, they slide together.
A coil spring 470 is engaged with the transfer head 460. The coil spring 470 is a coil spring that is generally used, but the outer diameters of the spring mounting portion 410q and the spring mounting portion 460f are fitted. It is arranged to be combined. That is, when the transfer head 460 slides in the transfer tool case 8a, it is always in a state of receiving the elastic force of the coil spring 470.
In this embodiment, the transfer tool case lower part 410, the transfer tool case upper part 420, the take-up core 30, the feeding core 40, the knock part 450, the transfer head 460, the coil spring 470, the tension coil spring 380, and the transfer tape T 9 Consists of two parts.

Next, the operation of this embodiment will be described with reference to FIGS. When the transfer head 460 is housed in the transfer tool case 8a, the knock portion 450 is projected from the knock in / out hole 420p when viewed from above the transfer tool case upper portion 420. Here, when the transfer head 460 is protruded from the transfer tool case 8a, the knock head 450 is pushed from the rear wall 420b side to the case opening 8b, and the transfer head 460 is moved from the case opening 8b in conjunction with the operation. Make it protrude. At this time, the coil spring 470 is compressed by the spring mounting portion 410q and the spring mounting portion 460f, and the engaging portion 460d of the transfer head 460 is bent with the L-shaped corner portion of the hinge portion 460c as a base point to engage with the hinge. Get over the stop 420q. By the overriding operation, the transfer head 460 is kept in the protruding state by being locked at the rear end of the locking portion 460d and the front end of the hinge locking portion 420q on the side close to the case opening 8b.
Next, in order to move the transfer head 460 from the protruding state to the retracted state, the locking at the rear end of the locking portion 460d and the front end of the hinge locking portion 420q are released, and the compressed coil spring 470 uses the restoring force to restore it and restores it. The locking is released by pushing the release button part 420o of the transfer tool case upper part 420 toward the transfer tool case lower part 410. That is, the surface surrounded by the button hinge hole 420n is bent from both ends of the U-shaped hole of the button hinge hole 420n of the upper part 420 of the transfer tool case 420, and the lower surface thereof is pushed in, whereby the locking portion 460d. Also, the bending lock is released with the L-shaped corner portion of the hinge portion 460c as a base point. By the release operation, the transfer head 460 is accommodated in the transfer tool case 8a.
Because of the above configuration, when the transfer head 460 is protruded, the knocking portion 450 is pushed, and when retracting, the release button portion 420o is simply pushed. Projection is possible with simple operation.
Further, even if the coating film transfer tool is housed in a container such as a pencil case, the rear end portion of the knock portion 450 is formed on the transfer tool case 8a in order to prevent the transfer head 460 from being inadvertently projected. It is designed not to protrude from the rear wall side. It is also possible to prevent the transfer head 460 and the coating film S from being damaged.
At the time of correction tape transfer, the transfer tape T fed from the feeding core 40 is sent out toward the tape travel path fixing / changing member 410i, folded back on the side surface of the tape travel path fixing / changing member 410i on the front wall 410a side, and transferred. The head 460 travels toward the tape travel path movement changing member 460b.

At this time, the transfer coating film S side of the transfer tape T comes into contact with the side surface of the tape travel path fixing changing member 410i. Then, the transfer tape T side is folded while contacting the side surface on the rear wall 410b side of the tape travel path movement changing member 460b, passes through the lower surface of the transfer head 460, and the transfer tape T side contacts the transfer head pressing portion 460a. Wrapped while. The folded transfer tape T passes through the upper surface of the transfer head 460 from the transfer head pressing portion 460a and travels toward the upper tape travel path 420m. The transfer tape T folded back on the side surface on the right wall 410c side of the upper tape traveling path 420m and on the rear wall 410b side is wound around the winding portion 30b of the winding core 30. Further, the surface of the tape that is folded back and brought into contact with the side surface on the rear wall 410b side may be the transfer tape T side or the transfer coating film S side, but there is no damage to the coating film. The tape T side is desirable.
Here, when the transfer head 460 is housed in the transfer tool case 8a, the release button part 420o is pushed to release the lock between the lock part 460d and the hinge lock part 420q, thereby moving the rear side of the transfer tool case 8a. The transfer head 460 is accommodated. At this time, the tape travel path movement changing member 460b formed on the transfer head 460 also moves back together, and at the same time, the transfer tape T via the tape travel path movement changing member 460b is stored in the transfer tool case 8a. The

Further, at that time, the transfer tape T between the tape travel path movement changing member 460b and the tape travel path movement changing member 410i is also separated by the backward movement of the tape travel path movement changing member 460b. It is stored in the tool case 7a. At this time, even when the transfer tape T is stored, the engaging portion 30d of the winding core 30 is engaged with the radial groove 320k, so that it is prevented from rotating in the direction opposite to the winding direction. The transfer tape T is not wound up. Therefore, when the transfer head 460 is housed in the transfer tool case 8a, the tape travel path movement changing member 460b moves backward, and the transfer tape T that has passed through the tape travel path movement changing member 460b is moved by the tape travel path movement changing member 460b. The transfer tape T is accommodated by being pulled by the pulled distance and the separation distance between the tape travel path movement changing member 460b and the tape travel path fixing / changing member 410i. That is, the transfer tape T moves approximately twice as much as the distance traveled by the tape travel path changing member 460b. By this pulling operation, the transfer coating film S applied to the transfer tape T located under the transfer head 460 is stored behind the transfer head 460.
Due to the above-described configuration, the tape is fed from the feeding core 40, is folded back by the pressing portion 460a of the transfer head 460 via the tape running path fixing / changing member 410i, and the tape running path moving / changing member 460b. Accordingly, the length of the transfer tape T taken up by the take-up portion 30b of the take-up core 30 is constant without being loosened even during the immersion operation of the transfer head 460. The transfer tape T is in a state that does not always slack during the retracting operation, and is attached to the transfer tape T that is positioned below the transfer head 460 when the transfer head 460 described above is stored. The transfer coating film S is prevented from being damaged because the transfer coating film S is stored behind the transfer head 460.
At the same time, since the transfer tape T to which the transfer coating film S adheres does not interfere with the pressing portion 460a, peeling of the transfer coating film S from the transfer tape T is also prevented. Further, since the transfer tape T does not always slack when the transfer head 460 appears and disappears, when the transfer head 460 is stored in the transfer tool case 8a, the transfer head 460 can be stored at the end of the case opening 8b. . That is, even when the transfer head 460 is at the end of the case opening 8b, the transfer tape T is protected because the transfer tape T is accommodated in the transfer tool case 8a. Further, because of the above configuration, there is no need to house the transfer head 460 in the transfer tool case 8a, and there is an advantage that the transfer tool case 8a can be slimmed.

When the transfer head 460 is protruded from the case opening 8b, the transfer coating film S located at the lower rear of the transfer head 460 is stored in the transfer tool case 8a by the protrusion operation of the pressing portion 460a of the transfer head 460. Together with the transfer tape T, the transfer head 460 is pulled out to the tip (pressing portion 460a). This is because when the transfer head 460 described above is housed in the transfer tool case 8a, the tape travel path movement changing member 460b moves backward, and the transfer tape T that has passed through the tape travel path movement changing member 460b is transferred to the tape travel path. This is because the transfer tape T is accommodated by the distance pulled by the movement change member 460b and the separation distance between the tape travel path movement change member 460b and the tape travel path fixing change member 410i. This is because only the transfer tape T located at the lower part is accommodated in the transfer tool case 8a.
Furthermore, when the transfer head 460 protrudes, only the transfer tape T accommodated in the transfer tool case 8a is protruded by the pressing portion 460a of the transfer head 460. The transfer coating film S is configured such that the position of the coating film is always at the tip of the transfer head 460. Further, since the winding diameter of the transfer tape T with respect to the feeding core 40 is smaller than the winding core 30, the tape winding speed by the winding core 30 becomes faster than the tape drawing speed from the feeding core 40, and the winding core 30 is always provided. However, it works to wind up the transfer tape T more than the feeding core 40. As a result, the used transfer tape T can be reliably wound around the winding core 30.
As described above, in the present embodiment, the feeding core 40 and the take-up core 30 are provided on the same axis, but an independent shaft may be provided and interlocked using a gear, a timing bell, or the like.

(Example 8)
Next, the configuration of the coating film transfer tool of the eighth embodiment will be described based on the drawings of FIGS. The description of the same configuration as in the first embodiment is omitted. In addition, in the figure, the same code | symbol is attached | subjected about the structure similar to Example 1. FIG. The transfer tool case 9a includes a transfer tool case lower part 510 and a transfer tool case upper part 520. The transfer tool case lower portion 510 has a bottomed box shape having a front wall 510a, a rear wall 510b, a right wall 510c, a left wall 510d, and a bottom wall 510e. A projecting rotating shaft 510f is erected, and the winding core 30 is rotatably supported on the rotating shaft 510f. The engaging claw 30f of the winding core 30 is detachably engaged with a radial groove 520k formed from the bottom surface of the transfer tool case upper portion 520.
Moreover, as the same structure as the said Example 1, the inner side of the feeding core 40 is fitted in the state press-contacted to the side surface of the said slip part 30a. As a result, the feeding core 40 is rotatably supported in a state in which a frictional resistance is applied, and a frictional resistance in the rotational direction with respect to the slip portion 30a of the feeding core 40 is given, and each other is assembled and disassembled. Is prevented. A transfer tape T is wound around the feeding core 40.

In the bottom wall 510e of the lower part 510 of the transfer tool case, a cylindrical assembly 510g is formed in the vicinity of the front wall 510a on the left wall 510d side, and a cylindrical assembly 510h is also formed in the vicinity of the rear wall 510b. Yes. In addition, a rectangular case lower opening 510k is formed as a through hole in the front wall 510a in the vicinity of the right wall 510c, and is opposite to the side surface of the case lower opening 510k in the vicinity of the right wall 510c. On the side surface, there are formed a guide rail 510l and a guide rail 510m in which two parallel walls are formed along the right wall 510c of the lower part 510 of the transfer tool case to the vicinity of the rear wall 510b. It is formed only up to near the center. Guide grooves 510n and 510o are formed as through holes in the vicinity of the upper portions of the opposing walls of the guide rails 510l and 510m, respectively.
A cylindrical tape travel path fixing / changing member 510i is erected on the bottom wall 510e of the lower part of the transfer tool case 510 in the right wall 510c side of the rotation shaft 510f and in the vicinity of the outside of the guide rail 510m. In addition, a spring installation base lower portion 510j, which is a rectangular parallelepiped projection, is erected on the bottom wall 510e in the vicinity of the right wall 510c on the rear wall 510b side. A spring installation portion lower portion 510p is formed as a columnar protrusion at a substantially central portion of the surface of the spring installation base lower portion 510j facing the front wall 510a.

On the other hand, the transfer tool case upper part 520 has a bottomed box shape having a front wall 520a, a rear wall 520b, a right wall 520c, a left wall 520d and a bottom wall 520e, and has the same shape as the transfer tool case lower part 510. The bottom wall 520e has assembly portions 520g and 520h formed in a cylindrical shape, and can be fitted and assembled with the assembly portions 510g and 510h of the transfer tool case lower portion 510.
Similarly, the assembling portion 520f and the assembling portion 520i also have a cylindrical shape, and are an assembling portion 520f that can be fitted to the rotating shaft 510f and an assembling portion 520i that can be fitted to the tape travel path fixing change member 510i. Assembled. In addition, a cylindrical reverse rotation preventing member 520l having an inner diameter larger than the outer diameter of the assembly portion 520f is formed around the rotation shaft 510f as a transfer tool case upper portion 520, and a radial groove is formed at the upper end portion thereof. 520k is formed.
The transfer tool case upper part 520 is formed with a case upper opening 520j at the same position as the transfer tool case lower part 510, and a case opening 9b is formed by the case lower opening 510k. Further, on the top surface of the transfer tool case upper part 520, in the vicinity of the case opening 520j and in the vicinity of the right wall 520c, a guide groove 520m is formed as a rectangular groove from the front wall 520a to the rear wall 520b side from the center of the case. In the guide groove 520m, a transfer head guide hole 520n is formed in a rectangular shape with a width smaller than that of the guide groove 520m in the vicinity of the front wall 520a.
A button guide hole 520o is formed in a rectangular shape behind the transfer head guide hole 520n in the guide groove 520m, and is sandwiched between the guide groove 520m and the rear wall 520b. A push button locking hole 520p, which is a rectangular through hole, is formed in the substantially central portion.
In addition, a spring installation base upper part 520q which is a protrusion of a rectangular parallelepiped is disposed on the surface of the button guide hole 520o and the push button locking hole 520p which is substantially in the center and on which the assembly portion 520f is disposed. A spring installation portion upper portion 520r is erected as a columnar protrusion on the surface on the rear wall 520b side, which is substantially the center of the spring installation base upper portion 520q.
Further, a push button slide hole 520s is formed at the rear end portion of the push button locking hole 520p on the surface on the rear wall 520b side of the transfer tool case upper portion 520.

The transfer head 560 has a rectangular plate shape and is made of a material that can be elastically deformed. A pressing portion 560a having a substantially triangular cross section is formed at the front end portion of the transfer head 560, and a tape running projecting in a cylindrical shape near the end opposite to the pressing portion 560a. A route movement changing member 560b is provided. A rectangular parallelepiped shape is formed on the opposite side of the surface on which the tape travel path movement changing member 360b is disposed, at the substantially central portion of the transfer head 560, and at substantially the end portions on both sides of the transfer head 560. Slide projections 560c and 560d are provided upright. Locking protrusions 560e and 560f having a substantially triangular shape are formed inside the upper ends of the slide protrusions 560c and 560d.
A tape guide 560g having a substantially triangular shape is formed on both sides in the width direction of the front portion of the transfer head 560, and a head portion spring installation base 560h is provided at the rear end portion of the transfer head 560. It is formed in a rectangular parallelepiped and is erected in the same direction as the tape travel path movement changing member 560b, and is substantially at the center of the head portion spring installation base 560h on the rear end side surface of the transfer head 560. The head portion spring installation portion 560i is erected as a columnar protrusion.
The plate thickness of the transfer head 560 is thinner than the guide grooves 510n and 510o, and the width thereof is smaller than the width sandwiched between the guide grooves 510n and 510o. The transfer head 560 slides in the guide grooves 510n and 510o. It comes to be moved. When the transfer head 560, the transfer tool case upper part 520, and the transfer tool case lower part 510 are assembled, the slide protrusions 560c and 560d of the transfer head 560 protrude from the transfer head guide hole 520n of the transfer tool case upper part 520. It becomes a state.

Like the transfer head 560, the slide button 570 has a rectangular plate shape and is made of a material that can be elastically deformed. Further, a button slide portion 570a that is a rectangular protrusion is formed at the front end portion of the slide button 570, and the button slide portion 570a has a transfer head fitting hole 570b that is a rectangular hole. . Further, the slide button 570 can be locked by the locking protrusions 560e and 560f of the transfer head 560 inserted from the transfer head fitting hole 570b and the guide groove 520m of the transfer tool case upper part 520.
A rectangular parallelepiped case slide portion 570c protrudes from the center of the slide button 570 on the side where the button slide portion 570a is formed, and on the upper portion of the case slide portion 570c, A slide locking portion 570d, which is a rectangular protrusion larger than the upper surface of the case slide portion 570c, is formed.
In addition, an elastic repulsion portion 570e is formed as a substantially triangular protrusion on the rear end of the slide button 570, and a button slip on the surface of the slide button 570 opposite to the case slide portion 570c. The stop portion 570f is formed as a plurality of substantially triangular protrusions, and is formed from the center portion to the end portion.
A push button 590 is disposed behind the transfer head 560. The push button 590 has a rectangular plate shape and is made of a material that can be elastically deformed. At one end portion of the push button 590, a locking portion 590a having a substantially triangular projection is formed. In addition, a push button portion 590b is formed as a rectangular protrusion at the other end which is the end opposite to the locking portion 590a.
A push button spring installation base 590c, which is a rectangular projection, is formed on the surface of the transfer head 560, which is on the side opposite to the locking portion 590a, and the push button spring installation base. A push button spring installation portion 590d is formed as a columnar protrusion on a surface that is substantially in the center of 590c and faces the locking portion 590a. A coil spring 550 is fixed to the push button spring installation portion 590d. The coil spring 550 is a commonly used coil spring, but the head portion spring installation portion 560i and the spring installation portion. It is designed to be fitted to the outer diameter of the lower part 510p. Similarly, the coil spring 580 is designed to be fitted to the outer diameters of the spring installation part upper part 520r and the push button spring installation part 590d. Further, the push button 590 slides in the push button slide hole 520s of the transfer tool case upper portion 520, and the sliding portion is from the front surface of the push button portion 590b to the rear surface of the push button spring installation base 590c. Is placed.
In this embodiment, the transfer tool case lower part 510, the transfer tool case upper part 520, the winding core 30, the feeding core 40, the coil spring 550, the transfer head 560, the slide button 570, the coil spring 580, the push button 590, and the transfer tape. It consists of 10 T parts.

Next, the operation of this embodiment will be described with reference to FIGS. Since the slide button 570 is locked by the locking protrusions 560e and 560f of the transfer head 560 inserted from the transfer head fitting hole 570b and the guide groove 520m of the transfer tool case upper part 520, for example, the slide button 570 Is slid back and forth with respect to the case opening 9b, the transfer head 560 protrudes / immerses from the case opening 9b of the transfer tool case 9a.
The transfer head 560 is housed in a state in which the head spring installation portion 560i of the transfer head 560 is in proximity to the spring installation portion lower portion 510p of the transfer tool case lower portion 510, and accordingly, the head portion spring installation portion 560i The coil spring 550 attached to the spring installation portion lower part 510p is in a compressed state. Further, the front surface of the elastic repulsion portion 570e of the slide button 570 and the rear surface of the locking portion 590a of the push button 590 are kept so that the coil spring 550 is kept compressed and the transfer head 560 does not protrude out of the transfer tool case 9a. It is comprised so that it may be latched by. Further, when the push button 590 is not used, the locking portion 590a protrudes from the push button locking hole 520p of the transfer tool case upper portion 520, but the push button 590 faces the case opening 9b. When the push-in operation is performed, the locking portion 590a of the push button 590 bends from the base portion of the push button spring installation base 590c protruding to the transfer tool case lower portion 510 side from the push button 590, and the transfer tool case The locking portion 590a is completely embedded in the upper portion 520.

At this time, since the coil spring 580 attached to the spring installation part upper part 520r of the transfer tool case upper part 520 and the push button spring installation part 590d of the push button 590 are in a compressed state, the push button 590 When the push-in operation is released, the coil spring attempts to restore the original state, so that the push button 590 and the coil spring 580 naturally shift to the state before the push button is pressed. With the above configuration, when the transfer head 560 is moved from the retracted state to the protruding state, the push button 590 is pushed toward the case opening 9b, whereby the elastic repulsion portion 570e of the slide button 570 and the push button are moved. The locking portion 590a of 590 is unlocked, and the transfer head 560 is projected from the transfer tool case 9a. On the contrary, when the transfer head 560 is housed in the transfer tool case 9a, the slide button 570 that moves in conjunction with the transfer head 560 is slid rearward of the transfer tool case 9a.
In order to keep the storage state of the transfer head 560, the slide button 570 is moved backward until the slide button 570 is locked between the front surface of the elastic repulsion portion 570e and the rear surface of the locking portion 590a of the push button 590. Need to slide to. Because of the above configuration, when the transfer head 560 is housed, it is necessary to slide the slide button 570. However, when the transfer head 560 protrudes, the transfer head 560 can be protruded by a one-touch operation by simply pressing the push button 590. Therefore, it can be used with a very simple operation.
Here, when the transfer head 560 is protruded, it is a one-touch operation in which only the push button 590 is pressed. Therefore, the transfer head 560 can be immediately protruded when desired to be used, and the transfer operation can be smoothly performed.
At the time of transfer of the correction tape, the transfer tape T fed from the feeding core 40 is sent out toward the tape travel path fixing / changing member 510i, folded back on the side surface on the front wall 510a side of the tape travel path fixing / changing member 510i, and transferred. The head 560 travels toward the tape travel path movement changing member 560b. At this time, the transfer coating film S side of the transfer tape T comes into contact with the side surface of the tape travel path fixing changing member 510i.

Then, the transfer tape T side is folded while contacting the side surface on the rear wall 510b side of the tape travel path movement changing member 560b, passes through the lower surface of the transfer head 560, and the transfer tape T side contacts the transfer head pressing portion 560a. Wrapped while. The folded transfer tape T passes through the upper surface of the transfer head 560 from the transfer head pressing portion 560a, and moves toward the upper portion of the tape travel path fixing / changing member 510i while passing between the slide protrusions 560c and 560d. The transfer tape T folded back on the side surface on the rear wall 510b side on the right wall 510c side of the upper portion of the tape travel path fixing change member 510i is wound by the winding portion 30b of the winding core 30. ing. The surface of the tape that is folded back and contacted on the side surface on the rear wall 510b side may be the transfer tape T side or the transfer coating film S side, but there is no damage to the coating film. The tape T side is desirable.
Here, when the transfer head 560 is accommodated in the transfer tool case 9a, the slide button 570 is locked until the slide button 570 is locked between the front surface of the elastic repulsion portion 570e and the rear surface of the lock portion 590a of the push button 590. 570 is moved to the rear of the transfer tool case 9a. At this time, the tape travel path movement changing member 560b formed on the transfer head 560 also moves backward in conjunction with the slide button 570, and at the same time, the transfer tape T via the tape travel path movement changing member 560b is transferred to the transfer tool case 9a. Stored inside. Further, at this time, the transfer tape T between the tape travel path movement changing member 560b and the tape travel path movement changing member 510i is also separated by the retreat of the tape travel path movement changing member 560b. It is stored in the tool case 9a. At this time, even when the transfer tape T is stored, the engaging portion 30d of the winding core 30 is engaged with the radial groove 520k, so that it is prevented from rotating in the direction opposite to the winding direction. The transfer tape T is not wound up.

Therefore, when the transfer head 560 is housed in the transfer tool case 9a, the tape travel path movement changing member 560b moves backward, and the transfer tape T that has passed through the tape travel path change member 560b is pulled by the tape travel path movement changing member 560b. The transfer tape T is accommodated by being pulled by the distance and the separation distance between the tape travel path movement changing member 560b and the tape travel path fixing / changing member 510i. That is, the transfer tape T moves approximately twice as much as the distance traveled by the tape travel path changing member 560b. By this pulling operation, the transfer coating film S applied to the transfer tape T located under the transfer head 560 is stored behind the transfer head 560. Because of the above-described configuration, it is fed out from the feeding core 40 and is folded back by the pressing portion 560a of the transfer head 560 via the tape running path fixing / changing member 510i and the tape running path moving / changing member 560b, and between the slide protrusions 560c and 560d. , The length of the transfer tape T taken up by the take-up portion 30b of the take-up core 30 through the upper part of the tape travel path fixing changing member 510i is constant without being loosened even during the immersion operation of the transfer head 560. is there.
The transfer tape T is in a state that does not always sag during the retracting operation, and is attached to the transfer tape T located under the transfer head 560 when the transfer head 560 described above is stored. Due to the configuration in which the transferred transfer coating S is housed behind the transfer head 560, the transfer coating S is prevented from being damaged. At the same time, since the transfer tape T to which the transfer coating film S adheres does not interfere with the pressing portion 560a, the coating film peeling of the transfer coating film S from the transfer tape T is also prevented. Further, since the transfer tape T does not always slack when the transfer head 560 appears and disappears, when the transfer head 560 is stored in the transfer tool case 9a, the transfer head 560 can be stored in the end portion of the case opening 9b. . That is, even if the transfer head 560 is at the end of the case opening 9b, the transfer tape T is protected because the transfer tape T is accommodated in the transfer tool case 9a.
In addition, because of the above configuration, there is no need to house the transfer head 560 in the transfer tool case 9a, and there is an advantage that the transfer tool case 9a can be slimmed.

Further, when the transfer head 560 is protruded from the case opening 9b, the transfer coating film S located at the lower rear side of the transfer head 560 is stored in the transfer tool case 9a by the protrusion operation of the pressing portion 560a of the transfer head 560. Together with the transfer tape T, the transfer head 560 is pulled out to the tip (pressing portion 560a). This is because, when the transfer head 560 described above is housed in the transfer tool case 9a, the tape travel path movement changing member 560b moves backward, and the transfer tape T that has passed through the tape travel path change member 560b moves the tape travel path. This is because the transfer tape T is accommodated by the distance pulled by the change member 560b and the separation distance between the tape travel path movement change member 560b and the tape travel path fixing change member 510i. This is because only the transfer tape T located at the lower part is accommodated in the transfer tool case 9a. Furthermore, when the transfer head 560 protrudes, only the transfer tape T accommodated in the transfer tool case 9a is protruded by the pressing portion 560a of the transfer head 560. The transfer coating film S is configured such that the position of the coating film is always at the tip of the transfer head 560. Further, since the winding diameter of the transfer tape T with respect to the feeding core 40 is smaller than the winding core 30, the tape winding speed by the winding core 30 becomes faster than the tape drawing speed from the feeding core 40, and the winding core 30 is always provided. However, it works to wind up the transfer tape T more than the feeding core 40. As a result, the used transfer tape T can be reliably wound around the winding core 30.
As described above, in the present embodiment, the feeding core 40 and the take-up core 30 are provided on the same axis, but an independent shaft may be provided and interlocked using a gear, a timing bell, or the like.

DESCRIPTION OF SYMBOLS 1 Transfer tool case 2 Case opening part 3 Transfer tool case 4 Case opening part 5 Transfer tool case 6 Case opening part 7a Transfer tool case 7b Case opening part 8a Transfer tool case 8b Case opening part 9a Transfer tool case 9b Case opening part 10 Transfer Lower part of case 10a Front wall 10b Rear wall 10c Right wall 10d Left wall 10e Bottom wall 10f Rotating shaft 10g Assembly part 10h Assembly part 10i Assembly part 10j Case lower opening 10k Guide rail 10l Guide rail 10m Guide groove 10n Guide groove 10o Tape running Path fixing change member 10p Semi-circular hole 20 Upper part of transfer tool case 20a Front wall 20b Rear wall 20c Right wall 20d Left wall 20e Bottom wall 20f Assembly part 20g Assembly part 20h Assembly part 20i Assembly part 20j Case upper opening 20k Radiation Groove 20l anti-reverse member 20m guide groove 20n transfer head guide hole 20o assembly part 20p button guide hole 20q square hole 30 take-up core 30a slip part 30b take-up part 30c cylindrical member 30d engagement part 30e "U" shaped groove 30f engaging claw 40 feeding core 40a bottom surface 40b winding groove 50 roller 60 transfer head 60a pressing portion 60b tape travel path movement changing member 60c slide projection 60d slide projection 60e locking projection 60f locking projection 60g tape guide 70 slide button 70a button Slide part 70b Transfer head fitting hole 70c Case slide part 70d Slide locking part 70e Elastic repulsion part 70f Button anti-slip part 100 Transfer tool case lower part 100a Rotating shaft 100b Guide rail 100c Guide rail 00d Guide groove 100e Guide groove 100f Tape travel path fixing change member 100g Tape travel path 100h Semi-arc-shaped hole 110 Upper part of transfer tool case 110a Assembly part 110b Assembly part 110c Reverse rotation prevention member 110d Radial groove 110e Slide groove 120 Transfer head 120a Press part 120b Tape travel path movement changing member 120c Tape guide 130 Slide button 130a Transfer head fitting part 200 Transfer tool case lower part 200a Front wall 200b Rear wall 200c Right wall 200d Left wall 200e Bottom wall 200f Rotating shaft 200g Traveling path member 200h Rotating shaft 200i Radial groove 200j Case lower opening 200k Case coupling part 200l Case coupling part 200m Case coupling part 200n Movement restricting member 200o Tape running path fixed Change member 210 Upper part of transfer tool case 210a Front wall 210b Rear wall 210c Right wall 210d Left wall 210e Bottom wall 210f Rotating shaft 210g Slide groove 210h Transfer restriction member 210i Transfer tool case groove 210j Case lower opening 210k Case connection receiving part 210l Case connection Receiving part 210m case connection receiving part 210n bearing part 220 feeding core 220a gear 220b cylindrical part 220c groove 230 slip member 230a large diameter cylindrical part 230b small diameter cylindrical part 230c protrusion 230d winding groove 240 winding core 240a gear 240b cylindrical part 240c flat plate part 240d Engaging portion 240e "U" -shaped groove 240f Locking claw 250 Transfer head 250a Pressing portion 250b Tape travel path movement changing member 250c Tape guide 260 Slide member 260a Shaped groove 310 Lower part of transfer tool case 310a Front wall 310b Rear wall 310c Right wall 310d Left wall 310e Bottom wall 310f Rotating shaft 310g Assembly part 310h Assembly part 310i Spring installation part lower part 310j Spring installation part upper part 310k Case lower opening part 310l Guide rail 310 m guide rail 310 n guide groove 310 o guide groove 310 p tape travel path fixing change member 320 upper part of transfer tool case 320 a front wall 320 b rear wall 320 c right wall 320 d left wall 320 e bottom wall 320 f assembly part 320 g assembly part 320 h assembly part 320 i assembly part 320 j case Upper opening 320k Radial groove 320l Anti-reverse member 320m Guide groove 320n Transfer head guide hole 320o Button guide hole 320p Hinge groove 320q Release Tan portion 320r Slide button locking portion 350 Roller 360 Transfer head 360a Pressing portion 360b Tape travel path movement changing member 360c Slide protrusion 360d Slide protrusion 360e Locking protrusion 360f Locking protrusion 360g Tape guide 360h Spring setting portion 370 Slide button 370a Button slide Portion 370b transfer head fitting hole 370c case slide portion 370d slide locking portion 370e elastic repulsion portion 370f button slip prevention portion 380 tension coil spring 380a hook 380b hook 410 transfer tool case lower portion 410a front wall 410b rear wall 410c right wall 410d left wall 410e Bottom wall 410f Rotating shaft 410g Assembly part 410h Assembly part 410i Tape running path fixing change member 410j Guide rail 410k Bottom opening 410l guide rail 410m guide rail 410n guide groove 410o guide groove 410p guide wall 410q spring mounting part 410r guide groove 420 transfer tool case upper part 420a front wall 420b rear wall 420c right wall 420d left wall 420e bottom wall 420f assembly part 420g Assembly part 420h Assembly part 420i Assembly part 420j Case upper opening 420k Radial groove 420l Reverse rotation prevention member 420m Tape travel path 420n Button hinge hole 420o Release button part 420p Knock in / out hole 420q Hinge locking part 450 Knock part 450a Slide protrusion 450b Slide protrusion 450c Knock fitting portion 450d Head fitting portion 450e Head fitting portion 460 Transfer head 460a Pressing portion 460b Tape running path Movement changing member 460c Hinge portion 460d Locking portion 460e Elongated hole 460f Spring mounting portion 460g Tape guide 470 Coil spring 510 Transfer tool case lower portion 510a Front wall 510b Rear wall 510c Right wall 510d Left wall 510e Bottom wall 510f Rotating shaft 510g Rotating shaft 510g Assembly part 510i Tape running path fixing change member 510j Spring installation base lower part 510k Case lower opening part 510l Guide rail 510m Guide rail 510n Guide groove 510o Guide groove 510p Spring installation part lower part 520 Transfer tool case upper part 520a Front wall 520b Rear wall 520c Right wall 520d Left wall 520e Bottom wall 520f Assembly part 520g Assembly part 520h Assembly part 520i Assembly part 520j Case top opening 520k Radial groove 520l Anti-reverse member 520m Guide groove 520n Transfer head guide hole 520o Button guide hole 520p Push button locking hole 520q Spring installation base upper part 520r Spring installation upper part 520s Push button slide hole 550 Coil spring 560 Transfer head 560a Press part 560b Tape travel path movement Change member 560c Slide protrusion 560d Slide protrusion 560e Locking protrusion 560f Locking protrusion 560g Tape guide 560h Head part spring installation base 560i Head part spring installation part 570 Slide button 570a Button slide part 570b Transfer head fitting hole 570c Case slide part 570d Slide Locking part 570e Elastic repulsion part 570f Button slip prevention part 580 Coil spring 590 Push button 590a Locking part 590b Push 590c Push button spring installation base 590d Push button spring installation part 601 Transfer tool case lower part 601a Case opening 601b Movement restricting member 601c Radial groove 601d Rotating shaft 601e Rotating shaft 601f Case connecting portion 601g Case connecting portion 601h Case connecting portion 601h Member 601j Traveling path member 601k Head bearing groove 602 Transfer tool case upper part 602a Case opening 602b Movement restricting member 602c Slide groove 602d Transfer tool case groove 602e Bearing part 602f Case connecting part 602g Case connecting part 602h Case connecting part 602i Traveling path member connecting part 602i 602k Slide groove 603 Winding core 603a Engaging portion 603b Gear 603c Cylindrical portion 603d Flat plate portion 603e Groove 603f Engaging claw 604 Feeding core 6 04a Groove 604b Gear 604c Cylindrical portion 605 Slip member 605a Winding groove 605b Protrusion 605c Large diameter cylindrical portion 605d Small diameter cylindrical portion 606 Transfer head 606a Tape guide 606b Travel path changing member 606c Front end portion 607 Slide mechanism 607a Recess case 616 Head 616a Movable part 616b Through hole 616c Through hole 616d Through hole 616e Travel path changing member 616f Through hole 617 Slide mechanism 617a Groove 618 Head shaft 620 Opening S Transfer film T Transfer tape

Claims (2)

Coating film transfer in which a transfer head is arranged so as to be able to protrude and retract with respect to the transfer tool case, and a take-up core around which the transfer tape is wound and a take-up core around which the transfer tape is taken out from the feed core are arranged. A tape travel path changing member that operates in conjunction with the movement operation of the transfer head is disposed on the transfer head, and at least during the immersion operation of the transfer head, the transfer tape is applied to the tape travel path change member. A coating film transfer tool characterized by being wound. The coating film transfer tool according to claim 1, wherein the feeding core and the winding core are arranged coaxially.

Images