JP5673999B2 - Coating film transfer tool with cutting completion mechanism - Google Patents

Description

  The present invention relates to an automatic winding-type coating film transfer tool used for pressing a transfer tape having a coating film formed on a surface of a base tape with a transfer head to transfer the coating film to a transfer surface. Is.

  As an example of a typical external design, an automatic winding type coating film transfer tool includes Design Registration No. 1289652. In addition, there exist things, such as design registration No. 1223792 gazette and design registration No. 1343344 gazette, for example, and the thing of various external design is sold. Although these external designs are different, the internal structure of the coating film transfer tool is basically the same.

  FIG. 1 is an explanatory diagram of an internal configuration of an automatic winding type film transfer tool 1. The transfer tape 4 on which the coating film 3 is formed on the surface of the base tape 2 is wound around the take-up reel 7 from the feed reel 5 via the transfer head 6, and the interlocking mechanism between the feed reel 5 and the take-up reel 7. In addition, the internal configuration is arranged in the case 8.

  The method of using the coating film transfer tool 1 for transferring the coating film 3 to the transfer surface 9 is to press the transfer tape 4 with the transfer head 6 protruding from the case 8 and to apply the coating film 3 on the transfer surface 9. The coating film transfer tool 1 is moved obliquely with respect to the transfer surface 9 while being brought into contact with the portion to be transferred. In FIG. 1, the coating film transfer tool 1 is moved in the right direction of the drawing with an inclination of about 45 degrees to the right.

  In order to finish the transfer, it is only necessary to stop the movement, remove the force, stop the pressing, and move the coating film transfer tool away from the transfer surface. At the time of separation, the film is cut so as to be torn between the coating film transferred to the transfer surface and the coating film not transferred on the surface of the base tape.

  Since the cutting is torn off, depending on the type of coating film, the coating film may be peeled off from the surface of the base tape so as to pull the thread without being cut cleanly in a straight line in the tape width direction. Moreover, before the coating film is cut, the transfer tape is pulled, the feeding reel rotates excessively, and the tape may sag.

  In view of this, Japanese Patent Application Laid-Open Nos. 05-178525 and 11-227386 propose a device provided with a rotation preventing member that prevents rotation of the reel in conjunction with the pressing operation of the transfer head.

  On the other hand, the thing which improved the cutting property of the coating film is also developed. For example, in Japanese Patent Application No. 2009-158468, the coating film is an adhesive layer that bonds paper or the like, but the cutting property is improved by forming voids in the adhesive layer.

  This method can be used for adhesive coatings, but not all coatings can be used. Therefore, it was necessary to improve the cutting performance depending on the structure of the coating film transfer tool. We have developed a coating film transfer tool with a mechanism for detecting cutting as disclosed in Japanese Patent Application No. 2010-105898. With this cutting recognition mechanism, it is possible to clearly recognize that the cutting has been performed, and it has become possible to cut cleanly in a straight line in the tape width direction regardless of the type of coating film.

Design Registration No. 1289652 Design Registration No. 1223792 Design Registration No. 1343344 JP 05-178525 A JP-A-11-227386 Japanese Patent Application No. 2009-158468 Japanese Patent Application No. 2010-105898

  However, in Japanese Patent Application No. 2010-105898, if the pressing force is large, the coating film transfer tool is inclined and moved with respect to the transfer surface even during transfer of the coating film to the transfer surface. Even while he was on the road, the knowledge mechanism sometimes worked.

  The problem to be solved by the present invention is that the cognitive mechanism is difficult to operate during the transfer of the coating film to the transfer surface, and the coating mechanism transfer tool that makes the cognitive mechanism easy to operate only when the transfer is finished. Is to provide.

  When finishing the transfer, if the coating film transfer tool is set up perpendicular to the surface to be transferred as shown in FIG. 2, it may be cut cleanly in a straight line in the tape width direction.

  The movement is stopped from the state where the coating film transfer tool is transferred while being inclined with respect to the transfer surface. With the contact point between the transfer head and the transfer surface as a fulcrum, the coating film transfer tool is set perpendicular to the transfer surface as shown in FIG. If the pressure is released and the pressing is stopped to move the coating film transfer tool away from the transfer surface, it may be cut cleanly in a straight line in the tape width direction.

  Further, before the pressing is stopped, the pressing can be strengthened once to cut more beautifully. It is equipped with a cutting notification mechanism that makes this operation conscious.

  The cutting recognition mechanism in the present invention is a mechanism that allows the user to know that the coating film has been reliably cut in conjunction with an operation of pressing the transfer tape with the transfer head.

  When this cutting notification mechanism was activated, the transfer tape was strongly pressed against the transfer surface by the transfer head, and was transferred to the transfer surface when the coating film transfer tool was separated from the transfer surface. The film is cut cleanly in a straight line in the tape width direction between the coating film and the coating film not transferred on the surface of the base tape. In other words, it is set so that the disconnection recognition mechanism is activated when the disconnection state is reached.

  Examples of the cutting recognition mechanism include a mechanism that generates sound, light, vibration, smell, and the like. These are the mechanisms that let the user know.

  In the case of sound generation, a simple configuration in which the members hit each other and make a sound can be achieved. In the case of light generation, it can be configured to emit light by incorporating an LED or the like. In the case of occurrence of vibration, it can be configured to vibrate by incorporating a motor or the like. Also in the case of odor generation, the switch can be configured such that the scent is emitted electrically by the switch. It can select suitably from these.

  Furthermore, since the operation of the cutting notification mechanism is linked to the transfer head, the transfer head is retracted in the case and returned to the case in order to prevent the transfer tape from sagging. It needs to be done smoothly without making the person aware. For this purpose, a resilient member is used.

In the present invention, a transfer tape having a coating film formed on the surface of a base tape is wound around a take-up reel from a feed reel via a transfer head. In the self-winding-type coating film transfer tool arranged, the transfer head protrudes from the case and can be retracted by the resilient member in the case in the direction of the shaft of the transfer head and in the case outward direction. The coating film transfer tool has a cutting notification mechanism unit, the cutting notification mechanism unit is fixed to the case, and a resilient member is installed in the cutting notification mechanism unit. And a coating transfer device with a cutting notification mechanism, wherein the cutting recognition mechanism is activated when the transfer head moves backward in the case.

  With the coating film transfer tool of the present invention, there is provided a coating film transfer tool that makes it difficult for the recognition mechanism to operate during transfer of the coating film to the surface to be transferred, and makes the recognition mechanism easy to operate only when the transfer is finished. Can now be offered.

It is explanatory drawing of the internal structure of a coating-film transfer tool. This is a coating film transfer tool standing perpendicular to the surface to be transferred. It is explanatory drawing of the coating-film transfer tool of Example 1. FIG. It is explanatory drawing of operation | movement of a cutting | disconnection recognition mechanism unit. It is explanatory drawing of operation | movement of a transfer head. It is use explanatory drawing of the coating-film transfer tool of this invention. It is external appearance explanatory drawing of a cutting | disconnection recognition mechanism unit. It is explanatory drawing of the internal structure of a cutting | disconnection recognition mechanism unit. It is a mechanism explanatory view of sound generation. It is explanatory drawing of the coating-film transfer tool of Example 2. FIG.

  FIG. 1 is an explanatory diagram of an internal configuration of an automatic winding type film transfer tool 1. The transfer tape 4 on which the coating film 3 is formed on the surface of the base tape 2 is wound around the take-up reel 7 from the feed reel 5 via the transfer head 6, and the interlocking mechanism between the feed reel 5 and the take-up reel 7. In addition, the internal configuration is arranged in the case 8.

  As the base tape 2, a paper base such as glassine paper or a synthetic resin base such as a polyethylene terephthalate (PET) film, a polypropylene film, or a polyethylene film may be used. A release layer may be provided on the surface of the base tape 2, or the base itself may be subjected to a release treatment.

  As the coating film 3, arbitrary things, such as a correction coating film, an adhesion coating film, and a pattern coating film, can be formed. Moreover, the functional coating film provided with functions other than these can be formed.

  As the interlocking mechanism between the supply reel 5 and the take-up reel 7, a mechanism that is interlocked by meshing the gears provided on the supply reel 5 and the take-up reel 7, or a mechanism that is interlocked by an endless rubber belt such as an O-ring is used. Can do.

  Further, the supply reel 5 and the take-up reel 7 are provided with a reverse rotation prevention mechanism for preventing the reverse rotation of the supply reel 5 and the take-up reel 7 so that the tape is not excessively drawn out or taken up. Better. As the reverse rotation prevention mechanism, a general mechanism may be used, and there is a mechanism such as an arbitrary ratchet.

  In FIG. 1, only the main members inside the case 8 are shown. When the main member looks as shown in FIG. 1, the portion related to the case 8 becomes a cross section, and the cross section is represented by oblique lines.

  As main parts other than the outer frame of the case 8, the following five places are shown. A reel central shaft 10 having a cylindrical cross section serving as a support shaft of the supply reel 5, a reel central shaft 10 having a cylindrical cross section serving as a support shaft of the take-up reel 7, and the transfer tape 4 fed from the supply reel 5 to the transfer head 6. The cylindrical tape guide 11 and the cylindrical tape guide 11 and the transfer head 6 that guide the substrate tape 2 to which the coating film 3 is transferred from the transfer head 6 to the take-up reel 7 are supported. The transfer head support 12 has a cylindrical cross section.

  The supply reel 5 is not in direct contact with the reel central shaft 10 having a cylindrical cross section, and is in contact with the four positions of the intermediate member 13 therebetween. The intermediate member 13 is connected to a gear 14 that is an interlocking mechanism between the supply reel 5 and the take-up reel 7.

  Although a reverse rotation prevention mechanism such as a ratchet is provided between the gear 14 and the case 8, it is not visible behind the feeding reel 5 in the drawing.

  The four places of the intermediate member 13 have elasticity. As a result, if the transfer tape 4 is pulled by some strong force, such as the timing is not synchronized between the interlocking mechanism and the reverse rotation prevention mechanism, the intermediate member 13 that is in contact with the feeding reel 5 has four locations. It comes to slip. This can prevent problems such as sagging due to excessive drawing and breakage of the tape.

  The transfer head 6 protrudes outside the case 8 and has a thick support shaft and a thin support shaft toward the inside of the case 8, and has a cylindrical shape at the end of the thin support shaft in the depth direction of the drawing. doing. The column is supported by the transfer head support 12 having a cylindrical cross section. In the figure, the transfer head 6 is shown with dots.

  The direction from the contact between the transfer head 6 and the transfer surface 9 to the center of the transfer head support 12 is the support shaft direction of the transfer head.

  The take-up reel 7 is in direct contact with the cylindrical central axis 10 having a cylindrical cross section, and is rotatable, but the gear of the take-up reel 7 that is hidden and invisible meshes with the gear 14 of the supply reel 5. Yes. As a result, the take-up reel 7 has a restricted movement linked to the rotation of the supply reel 5.

  Further, as the structure of the take-up reel 7, there are four short spokes from the cylindrical portion of the take-up reel 7 in contact with the reel center shaft 10, and a corrugated groove 15 is provided on the side surface of the take-up reel 7. The corrugated groove 15 has a wave shape, but is represented by a straight line toward the outer periphery like a circular fan in the drawing. The corrugated groove 15 is a groove used for tightening when the tape is slack.

  The method of using the coating film transfer tool 1 for transferring the coating film 3 to the transfer surface 9 is to press the transfer tape 4 with the transfer head 6 protruding from the case 8 and to apply the coating film 3 on the transfer surface 9. The coating film transfer tool 1 is moved obliquely with respect to the transfer surface 9 while being brought into contact with the portion to be transferred. In FIG. 1, the coating film transfer tool 1 is moved in the right direction of the drawing with an inclination of about 45 degrees to the right.

  By moving in this way, the tape travels, the transfer tape 4 is fed out, the feeding reel 5 is rotated, the gear 14 of the feeding reel 5 is also rotated, and the winding reel 7 is engaged by the gear of the winding reel 7. Reel 7 turns. The base tape 2 is wound up by adjusting the gear ratio and the reel diameter ratio. In this way, automatic winding is performed. For this adjustment, a spoke of the take-up reel 7 is provided.

  In such a normal use, since the coating film transfer tool 1 has the above-described internal configuration, the tape does not sag. However, when it sags due to some timing shift, the corrugated groove of the take-up reel 7 15 can be tightened.

  FIG. 2 shows the coating film transfer tool 1 erected vertically with respect to the transfer surface 9. FIG. 2 is the same as FIG. 1 except that the inclination of the coating film transfer tool 1 is different.

  When finishing the transfer, if the coating film transfer tool 1 is set up vertically with respect to the transfer surface 9 as shown in FIG. 2, it may be cut cleanly in a straight line in the tape width direction.

  The movement is stopped from the state of FIG. 1 in which the coating film transfer tool 1 is moved while being inclined with respect to the surface 9 to be transferred. With the contact point between the transfer head 6 and the transfer surface 9 as a fulcrum, the coating film transfer tool 1 is set up vertically with respect to the transfer surface 9 as shown in FIG. If the pressure is released and the pressing is stopped to separate the coating film transfer tool 1 from the transfer surface 9, the tape may be cut cleanly in a straight line in the tape width direction.

  Further, before the pressing is stopped, the pressing can be strengthened once to cut more beautifully. The present invention is provided with a cutting notice mechanism that makes this operation conscious.

  FIG. 3 is an explanatory diagram of the coating film transfer tool 1 according to the first embodiment. The coating film transfer tool 1 includes a cutting completion mechanism unit 16. The transfer head 6 includes a thick spindle and a thin spindle in the case 8. The thin support shaft is connected to the connection portion 17 of the cutting notification mechanism unit 16. The cutting notification mechanism unit 16 is fixed to the case 8. The other configuration of FIG. 3 is the same as that of FIG.

  Accordingly, in the figure, the direction perpendicular to the transfer surface 9 is the direction of the spindle of the transfer head. By strengthening the pressing in this direction, the cutting notification mechanism is activated, and it can be conscious of cutting more beautifully.

  FIG. 4 is an explanatory diagram of the operation of the cutting notification mechanism unit 16. FIG. 4A shows a state in which the disconnection recognition mechanism is not operated, and FIG. 4B shows an activated state. It operates when the connecting portion 17 moves backward. In addition, a resilient member is installed in the disconnection recognition mechanism unit 16 so that the connecting portion 17 can be returned from the backward movement, that is, from FIG. 4B to FIG. 4A.

  The cutting notification mechanism unit 16 is fixed to the coating film transfer tool 1, and the transfer head 6 is connected to the connection portion 17 of the cutting notification mechanism unit 16. This is FIG.

  Before the pressing is stopped, once the pressing is strengthened, the transfer head 6 is moved backward, and the connected connecting portion 17 is further moved backward, so that the cutting recognition mechanism is activated.

  FIG. 5 is an explanatory diagram of the operation of the transfer head 6. FIG. 2 is a view showing only the periphery of the transfer head 6 in the coating film transfer tool 1 and showing only the appearance without showing the internal configuration. 4 (a) and 4 (b) correspond to FIGS. 5 (a) and 5 (b), respectively.

  FIG. 5A shows a state in which the disconnection recognition mechanism is not operating, and FIG. 5B shows an operating state. The transfer head 6 in FIG. 5B is retracted from that in FIG. However, since the position of the transfer head 6 with respect to the transfer surface 9 is the same in FIG. 5A and FIG. 5B, the case 8 in FIG. 5B is moved downward in the drawing. .

  Since the elastic member is installed in the cutting recognition mechanism unit 16 so that the connecting portion 17 can be restored from the backward movement, the transfer head is moved in the case in the direction of the shaft of the transfer head by the elastic member. It is arranged so that it can be retracted back and returned to the outside of the case.

  FIG. 6 is an explanatory diagram of the use of the coating film transfer tool 1 of the present invention. The coating film transfer tool 1 includes a cutting completion mechanism unit 16. The transfer head 6 includes a thick spindle and a thin spindle in the case 8. The thin support shaft is connected to the connection portion 17 of the cutting notification mechanism unit 16. The cutting notification mechanism unit 16 is fixed to the case 8. The other configuration of FIG. 6 is the same as that of FIG. FIG. 6 is the same as FIG. 3 except that the inclination of the coating film transfer tool 1 is different.

  Thus, in the figure, the direction of about 45 degrees to the right with respect to the transfer surface 9 is the support shaft direction of the transfer head. By increasing the pressure in this direction, the cutting acknowledgment mechanism is activated.

  The method of using the coating film transfer tool 1 for transferring the coating film 3 to the transfer surface 9 is to press the transfer tape 4 with the transfer head 6 protruding from the case 8 and to apply the coating film 3 on the transfer surface 9. The coating film transfer tool 1 is moved obliquely with respect to the transfer surface 9 while being brought into contact with the portion to be transferred. In FIG. 6, the coating film transfer tool 1 is moved in the right direction of the drawing with an inclination of about 45 degrees to the right.

  By moving in this way, the tape travels, the transfer tape 4 is fed out, the feeding reel 5 is rotated, the gear 14 of the feeding reel 5 is also rotated, and the winding reel 7 is engaged by the gear of the winding reel 7. Reel 7 turns. The base tape 2 is wound up by adjusting the gear ratio and the reel diameter ratio. In this way, automatic winding is performed.

  In such a normal use, since the coating film transfer tool 1 has the above-described internal configuration, the tape does not sag. However, when it sags due to some timing shift, the corrugated groove of the take-up reel 7 15 can be tightened.

  In the usage method as shown in the figure, the transfer head 6 can be retracted in the direction of the support shaft by the cutting recognition mechanism unit 16 provided, but the coating film transfer tool 1 is moved in the right direction of the drawing. The transfer head 6 is configured not to easily retract in the case 8 in the direction of the support shaft.

  As a result, the recognition mechanism is difficult to operate during the transfer of the coating film to the transfer surface, and when the transfer is finished, it is completed for the first time by standing perpendicular to the transfer surface 9 as shown in FIG. The intelligence mechanism is easy to operate.

  FIG. 7 is an external explanatory view of the cutting notification mechanism unit 16. It is represented by a perspective view. It is a cylindrical object, and the site | part for fixing to a coating-film transfer tool is abbreviate | omitted. Once fixed, a cylindrical object will not rotate in the circumferential direction. The connection part 17 is retracted, and the disconnection recognition mechanism is activated. The cutting recognition mechanism unit 16 is not limited to this shape.

  If it is such a unit, the cutting acknowledgment mechanism includes a mechanism that generates sound, light, vibration, odor, etc., so it is possible to prepare multiple units with different generation mechanisms and replace them depending on the purpose. It becomes possible. Fixation to the coating film transfer tool 1 may also be fixed to be exchangeable.

  FIG. 8 is an explanatory diagram of the internal configuration of the cutting notification mechanism unit 16. Here, the disconnection recognition mechanism is a sound generation mechanism. The cutting notifying mechanism unit 16 is disassembled and the members are shown in a perspective view. This sound generation mechanism is similar to the mechanism of a knock-type writing instrument in order to make the explanation easy to understand, but is not limited to this mechanism.

  The cutting notification mechanism unit 16 is composed of five members. It comprises a cover 21, a coil spring 22 that is a resilient member, a rotating member 23, a movable member 24, and a positioning member 25.

  The cover 21 and the positioning member 25 are fitted and fixed, although the fitting portion is not shown in the drawing. When fixed, the result is as shown in FIG. As a result, the coil spring 22, which is a resilient member, the rotating member 23, and the movable member 24 are provided inside, and the rotating member 23 and the movable member 24 move in fixed positions. However, the connection part 17 which is a part of the movable member 24 protrudes from the lower left direction of the positioning member 25 as shown in FIG.

  When the lower left end of the coil spring 22 comes into contact with the upper surface 26 on the upper right side of the rotating member 23 and the cover 21 and the positioning member 25 are fitted, the coil spring 22 is always pressing the top surface 26. Since the coil spring 22 and the top surface 26 are not fixed, the rotating member 23 having the top surface 26 can rotate while being pressed by the coil spring 22.

  The movable member 24 is provided with a rotation hole 28 into which the cylindrical portion 27 of the rotation member 23 can be rotatably inserted. Rotation driving protrusions 29 are provided at three locations on the outer circumferential wall surface of the cylindrical portion 27 of the rotating member 23. Only two locations are visible in the figure. The rotational drive protrusion 29 extends from the back side 30 of the top surface 26 with a width in the lower left direction, and has an oblique shape with respect to the circumference.

  Sliding protrusions 32 are provided at three locations on the outer circumferential wall surface of the cylindrical portion 31 of the movable member 24. Only two locations are visible in the figure. In addition, on the upper right cylindrical end surface of the cylindrical portion 31 of the movable member 24, movable cam teeth 33 including six sets of peaks and valleys are provided.

  There is a structure inside the cylinder of the positioning member 25, which is indicated by a thin line in the figure. The cylindrical interior of the positioning member 25 includes a first inner wall surface 34 and a second inner wall surface 35. The inner diameter of the second inner wall surface 35 is smaller than that of the first inner wall surface 34.

  The first inner wall surface 34 is inside the upper right cylinder of the positioning member 25 in the figure, and the second inner wall surface 35 is inside the lower left cylinder of the positioning member 25 in the figure. It has a structure at the boundary of the inner wall surface 35.

  The first inner wall surface 34 is in contact with the outer circumferential wall surface of the top surface 26 of the rotating member 23 and the outer wall surface of the rotation driving projection 29, and the outer wall surface of the sliding projection 32 of the movable member 24. A circumferential outer wall surface of the cylindrical portion 31 of the movable member 24 is in contact with the second inner wall surface 35.

  The structure at the boundary between the first inner wall surface 34 and the second inner wall surface 35, which is the cylindrical inner structure of the positioning member 25, is composed of six diagonal shapes (wave shapes) that are diagonal to the circumference. Positioning cam teeth 36 are provided, and sliding grooves 37 are provided on the lower side of the three oblique shapes.

  The radial thickness of the sliding protrusion 32 of the movable member 24 is set substantially equal to the radial thickness of the sliding groove 37 of the positioning member 25. With this setting, the sliding protrusion 32 of the movable member 24 fits in the sliding groove 37 of the positioning member 25 and moves in the upper right and lower left direction of the drawing. That is, as long as the sliding protrusion 32 is fitted in the sliding groove 37 with respect to the positioning member 25, the movable member 24 moves only in the upper right and lower left direction of the drawing without rotating.

  Further, the radial thickness of the rotation drive protrusion 29 of the rotary member 23 is substantially equal to the sum of the radial thickness of the movable cam teeth 33 of the movable member 24 and the radial thickness of the positioning cam teeth 36 of the positioning member 25. Set equal. With this setting, the rotation drive protrusion 29 of the rotation member 23 comes into contact with either or both of the movable cam teeth 33 of the movable member 24 and the positioning cam teeth 36 of the positioning member 25.

  This is a sound generating mechanism having such a configuration. Next, the mechanism of sound generation will be described in detail with reference to the drawings.

  FIG. 9 is an explanatory diagram of the mechanism of sound generation. One of the rotation drive protrusions 29 is fixed to the center of the figure, and a configuration of about 2/3 on the circumference thereof is represented by a plan view for explanation.

  The rotation drive protrusion 29 is provided on the rotation member 23, extends from the back side 30 of the top surface 26 with a width in the downward direction of the drawing, and has an oblique shape with respect to the circumference. In the outer circumferential wall surface of FIG.

  The movable cam teeth 33 are located on the movable member 24 and have a mountain shape and a valley shape with respect to the vertical direction of the drawing. Six sets are provided on the cylindrical end face of FIG.

  The positioning cam teeth 36 are located on the positioning member 25 and have an oblique shape (wave shape) with respect to the circumference. Six sets are provided on the inner wall surface of the cylinder. However, sliding grooves 37 are provided on the lower side of the three oblique shapes.

  FIG. 9A shows a state where the disconnection recognition mechanism of FIG. 4A or FIG. 5A is not operating. The rotational drive protrusion 29 is on the lower side of the oblique shape provided with the sliding groove 37 of the positioning cam tooth 36. The upper side of the positioning cam teeth 36 is in contact with the back side 30 of the top surface 26 of the rotating member 23. In this arrangement, the top of the movable cam teeth 33 is located near the center of the oblique shape of the rotation drive projection 29.

  Although not shown, since the sliding protrusion 32 of the movable member 24 is fitted in the sliding groove 37 of the positioning member 25, the movable cam teeth 33 of the movable member 24 and the positioning cam teeth 36 of the positioning member 25 are The left and right positions do not change, and the movable cam teeth 33 move up and down with respect to the positioning cam teeth 36.

  In addition, since the rotation member 23 actually rotates, the rotation drive protrusion 29 of the rotation member 23 moves in the drawing. However, since the rotation drive protrusion 29 is fixed in the drawing, the movable cam teeth 33 and the positioning cam teeth 36 moves to the left of the drawing.

  FIG. 9 (b) shows a state where the pressure has once started to increase. The crests of the movable cam teeth 33 of the movable member 24 connected to the support shaft of the transfer head 6 move the rotation drive protrusion 29 upward in the drawing, so that the rotation drive protrusion 29 is on the diagonally upper side of the positioning cam teeth 36. It has just been engaged.

  FIG. 9C shows a further pressed state. The rotational drive protrusion 29 moves from the slightly engaged state to the valley of the movable cam tooth 33 at a stroke by the force of the resilient member. At this time, an acute angle portion in the lower right of the rotation driving projection 29 hits the valley of the movable cam teeth 33, and a sound is generated.

  Although the rotating member 23 having the rotation drive protrusion 29 actually rotates by the amount moved to the valley of the movable cam teeth 33, the movable cam teeth 33 and the positioning cam teeth 36 are moved to the left in the drawing.

  FIG. 9D shows a state where the pressing is stopped. Due to the force of the elastic member, the rotation drive projection 29 pushes the movable cam teeth 33 downward in the drawing, and the rotation drive projection 29 comes into contact with the positioning cam teeth 36.

  FIG. 9E shows a state where the pressing is stopped and all the forces are released. Due to the force of the elastic member, the rotational drive protrusion 29 moves at a stroke downward to the oblique shape of the positioning cam tooth 36. At this time, the right side wall of the rotation driving projection 29 in the figure collides with the vertical wall of the positioning cam teeth 36 in the vertical direction in the figure, and a sound is generated.

  The rotating member 23 having the rotation driving projection 29 actually rotates by the amount of the downward movement of the positioning cam teeth 36, but in the drawing, the movable cam teeth 33 and the positioning cam teeth 36 are moved to the left.

  At the same time, the movable cam teeth 33 are pushed down, and the transfer head 6 connected to the movable member 24 having the movable cam teeth 33 also returns to the original position.

  These are a series of operations. 9 (a) and 9 (e), there is a difference that there is no sliding groove 37 in the valley of the positioning cam teeth 36, but the operation of the members is the same.

  If the sound is expressed in characters and expressed as “kacha”, the sound “ka” is generated in FIG. 9C, and the sound “cha” is generated in FIG. 9E.

  FIG. 10 is an explanatory diagram of the coating film transfer tool of Example 2. An inner case is further used in the case. Although the detailed structure such as the case opening / closing mechanism is omitted, the tape can be refilled by replacing the inner case. For example, the inner case may be provided as a tape refill cartridge.

  The transfer tape 4 on which the coating film 3 is formed on the surface of the base tape 2 is wound around the take-up reel 7 from the feed reel 5 via the transfer head 6, and the interlocking mechanism between the feed reel 5 and the take-up reel 7. At the same time, it is disposed in the inner case 40, and the inner case 40 is disposed in the case 8.

  With the resilient member connected to the inner case 40, the transfer head 6 is disposed so that it can be retracted inward in the case 8 in the support shaft direction of the transfer head 6 and can be returned in the outward direction of the case 8. The cutting notifying mechanism is activated by retreating inward in the case 8. Note that portions such as grooves and protrusions necessary for the inner case 40 to move smoothly are omitted in the drawing. Further, when the inner case is provided as a tape refill cartridge, the inner case 40 and the resilient member may be fitted and removed.

  The inner case 40 in FIG. 10 is a rectangular parallelepiped. Two rectangular transparent plates are positioned in parallel, and they are connected by four vertical walls. In the figure, only one transparent plate 41 is visible, and the four vertical walls 42 have a cross section, and are represented by diagonal lines as in the case 8 cross section.

  Support shafts of main members are disposed on the transparent plate 41 of the inner case 40. In the figure, the reel central shaft 10, the two tape guides 11, and the transfer head support portion 12 of each of the supply reel 5 and the take-up reel 7 are arranged, but the present invention is not limited to these. The supply reel 5 and the take-up reel 7 partially protrude from the inner case 40.

  The transfer head 6 protrudes from the inner case 40, and further protrudes outside the case 8 due to the arrangement of the inner case 40 in the case 8.

  The coating film transfer tool 1 includes a cutting completion mechanism unit 16. The inner case 40 is directly connected to the connection portion 17 of the disconnection recognition mechanism unit 16. The cutting notification mechanism unit 16 is fixed to the case 8. Since the cutting notifying mechanism unit 16 is configured as shown in FIG. 8, the resilient member is disposed in the cutting notifying mechanism unit 16. Thus, the inner case 40 is connected to the elastic member.

  Therefore, the inner case 40 in which the transfer head 6 is arranged is arranged so that it can be retracted inward in the case 8 in the support shaft direction of the transfer head 6 and can be returned in the outer direction of the case 8 by a resilient member. . Thereby, the transfer head 6 is provided so as to protrude from the case 8, and can be retracted in the case 8 in the support shaft direction of the transfer head 6 by the resilient member and can be returned to the outside of the case 8. When the transfer head 6 moves backward in the case, the cutting recognition mechanism is activated.

  The usage description of the coating film transfer tool 1 of Example 2 is the same as the usage description of FIG. 6, although the internal configuration of the coating film transfer tool 1 is different. Since it is the same as FIG. 6, the direction of about 45 degrees to the right with respect to the transfer surface 9 is the spindle direction of the transfer head. By increasing the pressure in this direction, the cutting acknowledgment mechanism is activated.

  The method of using the coating film transfer tool 1 for transferring the coating film 3 to the transfer surface 9 is to press the transfer tape 4 with the transfer head 6 protruding from the case 8 and to apply the coating film 3 on the transfer surface 9. The coating film transfer tool 1 is moved obliquely with respect to the transfer surface 9 while being brought into contact with the portion to be transferred. In FIG. 6, the coating film transfer tool 1 is moved in the right direction of the drawing with an inclination of about 45 degrees to the right.

  By moving in this way, the tape travels, the transfer tape 4 is fed out, the feeding reel 5 is rotated, the gear 14 of the feeding reel 5 is also rotated, and the winding reel 7 is engaged by the gear of the winding reel 7. Reel 7 turns. The base tape 2 is wound up by adjusting the gear ratio and the reel diameter ratio. In this way, automatic winding is performed.

  In such a normal use, since the coating film transfer tool 1 has the above-described internal configuration, the tape does not sag. However, when it sags due to some timing shift, the corrugated groove of the take-up reel 7 15 can be tightened.

  In the usage method as shown in the figure, the transfer head 6 can be retracted in the direction of the support shaft by the cutting recognition mechanism unit 16 provided, but the coating film transfer tool 1 is moved in the right direction of the drawing. The transfer head 6 is configured not to easily retract in the case 8 in the direction of the support shaft.

  As a result, the recognition mechanism is difficult to operate during the transfer of the coating film to the transfer surface, and when the transfer is finished, it is completed for the first time by standing perpendicular to the transfer surface 9 as shown in FIG. The intelligence mechanism is easy to operate.

DESCRIPTION OF SYMBOLS 1 Coating film transfer tool 2 Base material tape 3 Coating film 4 Transfer tape 5 Feeding reel 6 Transfer head 7 Take-up reel 8 Case 9 Transfer surface 10 Reel central axis 11 Tape guide 12 Transfer head support part 13 Intermediate member 14 Gear 15 Waveform Groove 16 Cutting acknowledgment mechanism unit 17 Connection portion 21 Cover 22 Coil spring 23 Rotating member 24 Movable member 25 Positioning member 26 Top surface 27 Cylindrical portion 28 Rotating hole 29 Rotating drive projection 30 Back side of top surface 31 Cylindrical portion 32 Sliding projection 33 Movable Cam teeth 34 First inner wall surface 35 Second inner wall surface 36 Positioning cam teeth 37 Sliding groove 40 Inner case 41 Rectangular transparent plate 42 Vertical wall

Claims (1)

The transfer tape on which the coating film is formed on the surface of the base tape is wound around the take-up reel from the feed reel via the transfer head, and the automatic mechanism placed in the case along with the interlocking mechanism between the feed reel and the take-up reel. In roll-up type film transfer tool,
The transfer head is provided so as to protrude outside the case and be retractable by the resilient member in the case inward in the support shaft direction of the transfer head and returnable in the case outward direction.
The coating film transfer tool comprises a cutting notification mechanism unit, the cutting notification mechanism unit is fixed to the case, and a resilient member is installed in the cutting notification mechanism unit.
A coating film transfer tool with a cutting notice mechanism, wherein the cutting notice mechanism is activated when the transfer head moves backward in the case.

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