JP5266378B2 - Painting equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To satisfactory perform a pattern transfer to a portion where a pattern film is closely attached regardless of the surface shape of a workpiece in a pattern transfer device for transferring a pattern layer of the pattern film to a surface of the workpiece. <P>SOLUTION: The circumference of the workpiece W is surrounded by a partition wall member 50 with a transfer film F being closely attached to the surface of the workpiece W by vacuuming, and steam generated in a steam generator is supplied to a closed space S around the workpiece surrounded by the partition wall member 50. In this case, the temperature of the steam is set to a temperature such that an adhesive layer provided on the side opposite to the base film of the pattern layer in the pattern film F can be melted from the base film side, and the resulting steam is brought into contact with the base film of the transfer film, whereby the adhesive layer of the transfer film is melted by the heat thereof to transfer the pattern layer to the surface of the workpiece W. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a picture attaching apparatus for painting a picture layer of a picture film on the surface of a work.

  As a method for painting the pattern layer of the pattern film on the surface of the work, a method of transferring the pattern layer of the transfer film to the surface of the work or a method of sticking an adhesive film having the pattern layer is known. As a thermal transfer device used when transferring the pattern layer of the transfer film to the surface of the work, for example, in Patent Document 1, by pressing the work on which the transfer film is placed on the upper surface with a heated rubber member from above, A film in which a pattern layer of a transfer film is thermally transferred onto the surface of a work is disclosed.

  Patent Document 2 discloses a lower chamber member on which a workpiece is placed, an upper chamber member placed on the lower chamber member with the transfer film sandwiched therebetween, and the sandwiched between both chamber members. Heating means for heating the transfer film, and evacuation means for evacuating the space in the lower chamber member partitioned by the transfer film, the transfer film being brought into close contact with the surface of the workpiece by this evacuation In this state, a thermal transfer device is disclosed that transfers the pattern layer of the transfer film to the surface of the workpiece by heat applied to the transfer film.

  Furthermore, as a technique for bringing the transfer film into close contact with the surface of the workpiece by evacuation, first, both the space in the upper chamber member and the space in the lower chamber member partitioned by the transfer film are in a vacuum state, It is known that air is introduced only into the space in the upper chamber member to completely remove the air from the surface of the workpiece and then bring the transfer film into close contact with the surface shape of the workpiece. Therefore, the transfer film can be reliably adhered to the surface of the workpiece.

JP 2002-120817 A JP 2007-168121 A

  By the way, in the thermal transfer apparatus described in Patent Document 1, since the work is pressed from above with a rubber member, when the work has an undercut portion, for example, the rubber member is applied to the undercut portion. There is a drawback in that it cannot be contacted, and therefore cannot be transferred to the undercut portion.

  On the other hand, a device that evacuates the transfer film, such as the thermal transfer device described in Patent Document 2, can securely attach the transfer film to the surface of the workpiece even in the case of a workpiece having an undercut portion. However, even in this case, depending on the shape of the workpiece, the transfer film may not be heated satisfactorily, which may cause partial transfer failure.

That is, as shown in FIGS. 13 and 14, the transfer surface of the transfer film F is heated by heating the transfer surface of the work W with the heater H arranged around the transfer film F in a state where the transfer film F is in close contact with the surface of the work W. when transferring the pattern layer on the surface of the workpiece W, the upper surface W ₁ or side W ₂ of the surrounding facing the heater H of the workpiece W, can be satisfactorily transferred to be able to sufficiently heat The surface W _{3 at} the back of the notch W ′ that is far from the heater H is less heated, the lower surface W _{4 of the} peripheral part not facing the heater H, the side surface W ₅ of the notch W ′, etc. The surface that does not face the heater H further reduces the amount of heating. In particular, the lower surface W ₄ and the side surface W ₅ of the cut portion W 'of the peripheral portion is insufficient amount of heat, it is impossible to satisfactorily transferred.

For this, it is conceivable to increase the temperature of the heater H or lengthen the heating time. However, in this case, the upper surface W ₁ and the side surface W ₂ directly facing the heater H become overheated, and the transfer film This adversely affects F and causes a new transfer failure. This is the same when a warm air heater is used instead of the heater that heats the transfer film by radiant heat.

  Note that this is not limited to the case where the pattern layer of the transfer film is transferred to the surface of the workpiece, but the pattern is applied to the surface of the workpiece using heat, such as when an adhesive film having a pattern layer is adhered to the surface of the workpiece. This also occurs when painting the pattern layer of the film.

  Therefore, an object of the present invention is to provide a painting apparatus capable of always satisfactorily painting a surface to which a pattern film is in close contact, regardless of the surface shape of the workpiece.

  In order to solve the above-mentioned problem, the invention according to claim 1 of the present application is either a transfer film or an adhesive film in which a picture layer and an adhesive layer are sequentially laminated on one surface of a base film on the surface of a work. A painting apparatus for painting using the design film, wherein a work placing table on which the work is placed is disposed inside, and the design film is disposed on the opened upper surface with the adhesive layer side facing the work. A lower chamber member having an open lower surface that is in contact with the open upper surface of the lower chamber member with the pattern film interposed therebetween, and forming a closed space with the lower chamber member, and the lower chamber member A vacuuming device for bringing the pattern film into close contact with the surface of the workpiece by bringing the space partitioned by the pattern film in the side chamber member into a vacuum state, and the upper and lower chambers A partition wall member that forms a closed space surrounding the periphery of the workpiece by contacting the workpiece mounting table with a lower surface in the space formed of the material, and a closed space formed by the partition wall member, And a steam supply device for supplying steam at a temperature at which the adhesive layer of the pattern film in close contact with the surface can be melted from the base film side.

  The invention according to claim 2 is the invention according to claim 1, wherein the partition wall member includes a top plate that covers the upper surface of the workpiece and a side plate that covers the side surface. A supply passage for supplying steam and a steam ejection hole for ejecting the steam into a space in the partition wall member are formed.

  The invention according to claim 3 is the invention according to claim 2, wherein the top plate and the side plate are each provided with a heater for heating the steam passing through the supply passage, and provided on the top plate. The heater and the heater provided on the side plate are configured to be temperature-controllable independently.

  Furthermore, the invention according to claim 4 is the invention according to claim 2 or claim 3, wherein a plurality of the steam ejection holes are provided in the partition wall member and can be selectively closed. And

  The invention according to claim 5 is the invention according to any one of claims 1 to 4, wherein a far-infrared ceramic coating is applied to the inner surface of the partition wall member. .

  Next, the effect of the present invention will be described.

  First, according to the first aspect of the present invention, steam is supplied to a closed space surrounding the work formed by the partition wall member in a state where the pattern film is in close contact with the surface of the work by a well-known technique. Then, this vapor comes into contact with the outer surface of the pattern film that is in close contact with the surface of the workpiece, that is, the surface on the base film side. At this time, the temperature of the steam is set to a temperature at which the adhesive layer provided on the side opposite to the base film of the pattern layer in the pattern film can be melted from the base film side. The adhesive forming the adhesive layer is melted by being transmitted to, and the pattern layer is painted on the surface of the workpiece.

  In that case, since the steam supplied to the periphery of the work spreads heat almost uniformly to all parts of the surface of the work, for example, a heater arranged around the lower surface of the peripheral part of the work, the side surface of the notch part, etc. Thus, even a portion that cannot be sufficiently heated can be sufficiently heated. As a result, the pattern layer of the film is satisfactorily painted on the part where the pattern film is in close contact, and good painting is always performed regardless of the surface shape of the workpiece.

  Further, according to the invention described in claim 2, basically, the same effect as that of the invention described in claim 1 can be obtained. In particular, the partition wall member includes a top plate that covers the top surface of the workpiece and a side plate that covers the side surface of the workpiece, and a supply passage for supplying steam to each of the top plate and the side plate is formed, and the space in the partition wall member The above-mentioned effect can be realized more specifically by forming a steam ejection hole for ejecting steam.

  Further, according to the invention described in claim 3, basically, the same effect as that of the invention described in claim 2 can be obtained. In particular, a heater for heating steam is provided on each of the top plate and the side plate, and the heater provided on the top plate and the heater provided on the side plate are configured so that the temperature can be controlled independently. Temperature control according to the type and shape of the workpiece can be performed.

  Furthermore, according to the invention described in claim 4, basically, the same effect as that of the invention described in claim 2 or claim 3 can be obtained. In particular, a plurality of the steam ejection holes are provided in the partition wall member and can be selectively closed, so that the steam supply position can be adjusted according to the shape of the workpiece.

  And according to invention of Claim 5, there can exist an effect similar to the invention of any one of Claim 1 to Claim 4 fundamentally. In particular, since the far-infrared ceramic coating is applied to the inner surface of the partition wall member, the pattern film can be heated more efficiently.

It is a schematic sectional drawing of the painting apparatus which concerns on the reference example of this invention. It is a schematic sectional drawing of the steam supply apparatus in the apparatus with a picture. It is sectional drawing of the transfer film used with the apparatus with a picture. It is a schematic sectional drawing which shows the evacuation state by the apparatus with a picture. It is a schematic sectional drawing which shows the same steam supply state. It is sectional drawing by the XX line of FIG. It is a schematic sectional drawing of the painting apparatus which concerns on embodiment of this invention. It is sectional drawing by the ZZ line of FIG. It is a top view of the steam plate in the apparatus with a picture. It is a schematic sectional drawing which shows the transfer film arrangement | positioning state by the apparatus with a picture. It is a schematic sectional drawing which shows the same vacuum drawing state. It is a schematic sectional drawing which shows the same steam supply state. It is a top view which shows the problem of the conventional thermal transfer apparatus. It is sectional drawing by the YY line of FIG.

  Hereinafter, a picture device according to an embodiment of the present invention will be described.

  First, a reference example provided with the configuration and operation that is a premise of the embodiment will be described. As shown in FIG. 1, a thermal transfer apparatus 1 as a painting apparatus according to this reference example has a lower chamber member whose upper surface is opened. 2 and an upper chamber member 3 disposed above the lower chamber member 2 and having an open lower surface. The upper chamber member 3 is installed above the lower chamber member 2 and both chamber members 2 are disposed. 3 to form a box-shaped closed space and a state in which the upper chamber 3 is retracted from above the lower chamber member 2 and the upper portion of the lower chamber member 2 is opened. Yes.

  A work placing table 4 is provided on the inner bottom surface of the lower chamber member 2, and the work W is placed on the placing table 4.

  Further, when the transfer film F is supplied so as to cover the upper surface of the lower chamber member 2 and the upper chamber member 3 is installed above the lower chamber member 2, it is shown in FIG. As described above, the chamber members 2 and 3 are closed with the transfer film F sandwiched between the upper surface of the lower chamber member 2 and the lower surface of the upper chamber member 3. The film F is partitioned.

  The thermal transfer apparatus 1 is provided with a pressure control device 10. The pressure control device 10 extends from a vacuum pump 11, a pressure pump 12, a vacuum passage 13 that branches from the vacuum pump 11 and communicates with the inside of the lower chamber member 2 and the upper chamber member 3, and the pressure pump 12. A pressure air passage 14 communicating with the upper chamber member 3, an on-off valve 15 a, 15 b disposed in the branch passages 13 a, 13 b of the vacuum passage 13, and an on-off valve 16 disposed in the pressure air passage 14 are provided. .

  Further, the thermal transfer apparatus 1 has a vapor supply apparatus 20 as shown in FIG. The steam supply device 20 is disposed in the lower chamber member 2 in a state where the upper chamber member 3 is retracted from above the lower chamber member 2, and the partition wall member 21 surrounding the work W on the mounting table 4. And a steam generator 22 disposed on the upper portion of the partition wall member 21.

  When the steam supply device 20 is installed in the lower chamber member 2, a closed space S is formed around the work W, and steam is supplied from the steam generator 22 into this space. It has come to be.

Here, as shown in FIG. 3, the transfer film F has a structure in which a release layer F ₂ , a pattern layer F _3, and an adhesive layer F ₄ are sequentially laminated on one surface of the base film F ₁ . The temperature of the steam supplied from the steam generator 22 is such that when the steam comes into contact with the transfer film F from the base film F ₁ side, the base film F ₁ , the release layer F _2, and the pattern layer F _3. there is a meltable temperature adhesive constituting the adhesive layer F ₄ through.

  In the case of a transfer film generally used, the temperature of this vapor is about 120 to 200 ° C., but the temperature is not necessarily limited to this range, and the material and thickness of each layer constituting the film Is set to an optimum temperature at which the adhesive can be melted. In addition, as the transfer film, various transfer films such as those that extend at room temperature and those that do not extend at room temperature can be used.

  Next, the operation of the thermal transfer apparatus 1 will be described.

First, as shown in FIG. 1, the work W is placed on the work placing table 4 in the lower chamber member 2, and transferred to the upper surface of the lower chamber member 2 with the base film F ₁ side facing up. Supply film F. In this state, the upper chamber member 3 is installed above the lower chamber member 2, and the transfer film F is sandwiched between the upper surface of the lower chamber member 2 and the lower surface of the upper chamber member 3, Both chamber members 2, 3 are closed.

  Next, in this state, the on-off valves 15a and 15b arranged in the branch passages 13a and 13b of the vacuum passage 13 are opened, the on-off valve 16 arranged in the compressed air passage 14 is closed, and the vacuum pump 11 is operated. By doing so, the space in the lower chamber member 2 partitioned by the transfer film F and the space in the upper chamber member 3 are simultaneously brought into a vacuum state. At this time, since the pressures on both sides of the transfer film F are kept substantially equal, the film F remains stretched between the chamber members 2 and 3 as shown in FIG.

  Next, the upper chamber member 3 partitioned by the transfer film F is closed by closing the on-off valve 15b on the branch passage 13b of the vacuum passage 13, opening the on-off valve 16 on the pressure passage 14, and operating the pressure pump 12. Supply compressed air only to the interior space.

As a result, as shown in FIG. 4, the lower space of the transfer film F is in a vacuum state, the upper space is in a compressed air supply state, and a large pressure difference is generated on both sides of the film F. The transfer film F is brought into close contact with the surface of the workpiece W. In this case, because they are pre air excluded from between the workpiece W and the film F, the transfer film F is not only the upper surface W ₁ or side W ₂ of the workpiece W, for example, the side lower surface W ₄ Ya of It will also adhere completely to the back surface W ₃ , the side surface W _5, etc. of the cut portion W ′.

  Next, after retracting the upper chamber member 3 from above the lower chamber member 2, the work W on the mounting table 4 is enclosed in the lower chamber member 2 as shown in FIGS. A steam supply device 20 is installed, and a partition wall member 21 of the device 20 and a steam generator 22 provided on the partition wall member 21 form a closed space S around the work W.

In this state, steam is generated by the steam generator 22, and steam is supplied to the space S. In this case, the temperature of the vapor is set to a temperature at which the adhesive constituting the adhesive layer F ₄ can be melted by the heat via the base film F ₁ , the release layer F _2, and the pattern layer F ₃ in the transfer film F. Is set.

Thus, in the space S, are heated when the vapor comes into contact with the base film F ₁ of the transfer film F in close contact with the surface of the workpiece W, up by the heat, the adhesive layer F ₄ of the transfer film F to melt That is, the image layer F _{3 of the} film is transferred to the surface of the work W when the adhesive layer F ₄ is melted while the film F is in close contact with the surface of the work W with a large pressure difference. become.

In this case, the steam is supplied to every corner of the space S, and also carries heat to the side lower surface W ₄ of the workpiece W, the back surface W ₃ and the side surface W _{5 of} the cut portion W ′, and the like. The portions of the film F that are in close contact with these portions are also heated in the same manner as other portions.

Thus, the heated transfer film F is the surface substantially uniformly contact the workpiece W, even in such aspects W ₅ of the above conventional heated sufficiently it can not be the side lower surface W ₄ and cut portions W ' , similarly to the upper surface W ₁ or side W _2, it is possible to satisfactorily transferred.

  Next, a thermal transfer apparatus as a painting apparatus according to an embodiment of the present invention will be described.

  The thermal transfer apparatus as a painting apparatus according to this embodiment has a space closed around the workpiece on the workpiece mounting table by the partition wall member without retracting the upper chamber member after the transfer film is brought into close contact with the surface of the workpiece. Formed and configured to supply steam to the space. In addition, the same code | symbol is attached | subjected about the structure similar to the said reference example, and description is abbreviate | omitted.

  As shown in FIG. 7, the thermal transfer apparatus 31 according to this embodiment includes a lower chamber member 32 having an upper surface opened, and an upper chamber member 33 having a lower surface opened. The upper chamber member 33 is driven. It is connected to the rod portion 35a of the cylinder 35 so as to be movable in the vertical direction. As a result, in the thermal transfer apparatus 31, a state in which a closed space is formed by the chamber members 32 and 33 and the upper chamber member 33 is retracted from the lower chamber member 32 and the upper portion of the lower chamber member 32 is opened. It can be switched to the state that has been.

  The lower chamber member 32 includes a workpiece mounting table 34 on the inner bottom surface thereof, and the workpiece W is mounted on the workpiece mounting table 34. The work mounting table 34 is connected to the rod portion 36a of the drive cylinder 36 and is configured to be movable in the vertical direction. As a result, the workpiece W on the workpiece mounting table 34 can be moved in the vertical direction within the lower chamber member 32.

  Further, the transfer film F is supplied so as to close the upper surface of the lower chamber member 32. After the upper chamber member 33 is retracted from the lower chamber member 32 and the upper side of the lower chamber member 32 is opened, the transfer film F is supplied to the upper surface of the lower chamber member 32, and then the upper chamber member 33 is moved downward. By doing so, both chamber members 32 and 33 are closed with the transfer film F in between.

  The thermal transfer device 31 also includes a steam supply device, and the steam supply device includes a steam generator (not shown) as a steam supply source, and a partition wall member 50 surrounding the work W on the work mounting table 34, Steam from the steam generator is supplied to the space in the partition wall member 50.

  The steam generator is disposed outside the upper chamber member 33, and the partition wall member 50 is disposed in the upper chamber member 33. The partition wall member 50 includes a top plate 51 that covers the upper surface of the workpiece W on the workpiece mounting table 34 and extends in a substantially horizontal direction, and a side plate 52 that covers the side surface of the workpiece W on the workpiece mounting table 34 and extends in a substantially vertical direction. It is formed in a box shape.

  As shown in FIG. 8, the top plate 51 includes a steam plate 56 formed in a box shape with a bottom surface 56a formed in a substantially flat plate shape and a side surface 56b extending upward at the peripheral edge of the bottom surface 56a, A heating plate 57 assembled to the steam plate 56 so as to close the upper surface is provided, and a supply passage 51 a for supplying steam to the space in the partition wall member 50 is formed on the top plate 51 by the steam plate 56 and the heating plate 57. Has been. The supply passage 51 a is supplied with steam generated by the steam generator disposed outside the upper chamber member 33 via the tubular member 47.

  In the top plate 51, a plurality of openings 56c are formed in the bottom surface 56a of the steam plate 56, and perforated bolts 58 are attached to the openings 56c. The perforated bolt 58 has a through hole 58a inside, the head 58b of the perforated bolt 58 protrudes from the bottom surface 56a of the steam plate 56, and the shaft portion 58c of the perforated bolt 58 is assembled to the opening 56c. It is attached in the state. Thus, the top plate 51 is formed with a plurality of steam ejection holes 58a through which steam is ejected from the supply passage 51a into the space in the partition wall member 50.

  In the top plate 51, the steam inlet portion from the supply passage 51 a to the steam ejection hole 58 a is provided at a position higher than the bottom surface 56 a of the steam plate 56, so that when steam is supplied to the space in the partition wall member 50. When steam condenses in the supply passage 51a and water droplets are generated, the water droplets can be prevented from falling into the space in the partition wall member 50.

  The heating plate 57 is formed of, for example, an aluminum plate, and the heating plate 57 incorporates a heater 57a for heating steam. The heater 57a built in the heating plate 57 is configured to be temperature-controllable by a control unit (not shown) described later. The heating plate 57 is also connected to a rod portion 37a of a drive cylinder 37 fixed to the upper chamber member 33 via a connecting rod 38 so as to be movable in the vertical direction. Thereby, the partition wall member 50 is supported by the upper chamber member 33 so that raising and lowering is possible. The partition wall member 50 is provided with a protective cover 54 that covers the periphery of the hot platen 57.

  The side plate 52 is formed therein with a supply passage 52a for supplying steam to the space in the partition wall member 50, and the supply passage 52a extends in the vertical direction through a communication passage 56d provided in the steam plate 56. It communicates with a supply passage 51 a formed in 51. The side plate 52 is also formed with a plurality of steam ejection holes 52b for ejecting steam from the supply passage 52a into the space in the partition wall member 50.

  Further, the side plate 52 has a built-in heater 52c for heating the steam, and the heater 52c is configured to be temperature-controllable by the control unit. The heater 52c provided on the side plate 52 and the top plate 51, specifically, the heater 57a provided on the heating plate 57 are configured to be temperature-controllable independently of each other.

  In the thermal transfer device 31, a dividing plate 53 that divides the space in the partition wall member 50 into two spaces is provided. The dividing plate 53 is configured in the same manner as the side plate 52, and a supply passage for supplying steam to the two spaces is formed, and a steam injection hole for discharging steam from the supply passage to the two spaces is formed. In addition, a heater for heating the steam is incorporated. This heater is also configured to be capable of temperature control independently by the control unit. As a result, painting on the two workpieces W can be performed under substantially the same conditions. In addition, a heat insulating material 55 for preventing the film F from being melted when the periphery of the work W is surrounded by the partition wall member 50 is provided on the lower end surfaces of the side plate 52 and the dividing plate 53, respectively.

  In the present embodiment, the inlet portion of the communication passage 56d provided in the steam plate 56 from the supply passage 51a is formed to protrude from the bottom surface 56a of the steam plate 56, and as shown in FIG. 9, at both ends of the protrusion portion 56e. A screw hole 56f is formed. If necessary, as shown in FIG. 8, a cover plate 68 that closes the communication path 56d is disposed on the upper surface of the protruding portion 56e, and the fastening bolt 69 is assembled to the screw hole portion 56f. When supplying steam to the space, it is possible to supply steam only from the top plate 51 and not supply steam from the side plate 52. Note that the steam can be prevented from being supplied to the dividing plate 53 in the same manner as the side plate 52.

  Further, the inner surface of the partition wall member 50 is provided with a far-infrared ceramic coating. Specifically, the far infrared ceramic coating is applied to the surfaces of the steam plate 56, the side plate 52, and the dividing plate 53 that constitute the inner surface of the partition wall member 50. Thereby, a film can be heated more efficiently.

  The thermal transfer device 31 is also provided with a pressure control device 40. The pressure control device 40 branches from the vacuum pump 41, the pressure air pump 42, and the vacuum pump 41 in the lower chamber member 32 and the upper chamber member 33. A vacuum passage 43 that leads to the pressure chamber, a pressure air passage 44 that extends from the pressure pump 42 and leads into the upper chamber member 33, open / close valves 45 a and 45 b disposed in the branch passages 43 a and 43 b of the vacuum passage 43, and a pressure passage 44, respectively. And an on-off valve 46 disposed therein.

  Further, the pressure control device 40 includes flow rate adjusting valves 48 a and 48 b disposed in the branch passages 43 a and 43 b of the vacuum passage 43, respectively. Further, the pressure control device 40 includes an atmosphere release valve 49a for releasing the space in the lower chamber member 32 to the atmosphere, and an atmosphere release valve 49b for releasing the space in the upper chamber member 33 to the atmosphere.

  The thermal transfer device 31 is provided with a control unit (not shown) that comprehensively controls the configuration related to the thermal transfer device 31. The control unit includes drive cylinders 35, 36, and 37, a vacuum pump 41, a compressed air. Various operations of the pump 42, the on-off valves 45a, 45b, 46, the flow rate adjusting valves 48a, 48b, the air release valves 49a, 49b, the heaters 52c, 57a, the steam generator and the like are controlled. The control unit is configured with a microcomputer as a main part, for example.

  Next, the operation of the thermal transfer device 31 will be described.

First, as shown in FIG. 7, the upper chamber member 33 is retracted from the lower chamber member 32 to open the upper side of the lower chamber member 32, and the open / close valves 45a, 45b, 46 and the air release valves 49a, 49b are closed. In the state, the workpiece W is placed on the workpiece placing table 34 in the lower chamber member 32 so that the upper surface of the workpiece W is lower than the upper end surface of the lower chamber member 33, and the base film is placed on the upper surface of the lower chamber member 32. supplying the transfer film F toward the top F ₁ side.

  Then, as shown in FIG. 10, the upper chamber member 33 is moved downward in a state where the lower end surface of the partition wall member 50 is disposed above the lower end surface of the upper chamber member 33, and the upper surface of the lower chamber member 32 is Both chamber members 32 and 33 are closed with the transfer film F sandwiched between the lower surface of the upper chamber member 33.

  Next, in this state, the open / close valves 45a and 45b disposed in the branch passages 43a and 43b of the vacuum passage 43 are opened, and the vacuum pump 41 is operated to lower the lower chamber member 32 partitioned by the transfer film F. The inner space and the space in the upper chamber member 33 are simultaneously brought into a vacuum state. At this time, by adjusting the suction speed by adjusting the flow rate adjusting valves 48a and 48b, the vacuum pressure in the space in the lower chamber member 32 and the space in the upper chamber member 33 is adjusted, and the transfer film F is substantially horizontal. Since the film F can be maintained in a state, the film F remains stretched between the chamber members 32 and 33.

  When the space in both the chamber members 32 and 33 is in a vacuum state, the on-off valve 45b is closed, the on-off valve 46 disposed in the compressed air passage 44 is opened, and the compressed air pump 42 is operated, so that the transfer film F The compressed air is supplied only to the space in the partitioned upper chamber member 33. In the present embodiment, although not limited to this, the pneumatic pump 42 is operated and the workpiece mounting table 34 is moved upward until it is substantially flush with the upper surface of the lower chamber member 32.

  As a result, as shown in FIG. 11, the lower space of the transfer film F is in a vacuum state, and the upper space is in a compressed air supply state, resulting in a large pressure difference on both sides of the film F. The transfer film F is brought into close contact with the surface of the workpiece W. As described above, in this case, since air is previously excluded from between the workpiece W and the film F, the transfer film F is not only the upper surface or side surface of the workpiece W, but also, for example, the lower surface or cut portion of the side portion. It will be completely in close contact with the back and sides of the.

  Next, the on-off valve 46 is closed, the partition wall member 50 disposed in the upper chamber member 33 is moved downward while the both chamber members 32, 33 are closed without retracting the upper chamber member 33, As shown in FIG. 12, the partition wall member 50 forms a closed space S around the workpiece W on the workpiece mounting table 34.

Then, the heaters 57a and 52c provided on the top plate 51, the side plate 52, and the dividing plate 53 are controlled to be heated, and the steam generator is operated to supply the steam from the steam generator to the supply passages 51a and 52a. Then, it is supplied into the space S from the steam ejection holes 58a and 52b. The temperature of the steam is set to a temperature at which the adhesive constituting the adhesive layer F ₄ can be melted by the heat through the base film F ₁ , the release layer F ₂ , and the pattern layer F ₃ in the transfer film F. .

Thus, in the space S, are heated when the vapor comes into contact with the base film F ₁ of the transfer film F in close contact with the surface of the workpiece W, up by the heat, the adhesive layer F ₄ of the transfer film F to melt Thus, the image layer F _{3 of the} film F is transferred to the surface of the work W by melting the adhesive layer F ₄ in a state where the film F is in close contact with the surface of the work W with a large pressure difference. It will be.

  In that case, the vapor is supplied to every corner in the space S, and also carries heat to the lower surface of the side portion of the work W, the back surface and the side surface of the cut portion, and adheres to these portions of the transfer film F. The heated part is heated in the same manner as other parts.

Thus, the heated transfer film F is the surface substantially uniformly contact the workpiece W, even in such aspects W ₅ of the above conventional heated sufficiently it can not be the side lower surface W ₄ and cut portions W ' , similarly to the upper surface W ₁ or side W _2, it is possible to satisfactorily transferred.

When the pattern layer F ₃ of the transfer film F on the surface of the workpiece W is transferred, the top plate 51 stops the operation of the steam generator with closed both chambers members 32 and 33, side plates 52, divider plate 53 The heating of the heaters 57a and 52c provided in each is stopped. Then, after the partition wall member 50 is moved upward, the atmosphere release valves 49a and 49b are opened to simultaneously open the space in the lower chamber member 32 and the space in the upper chamber member 33 to the atmosphere, and then the upper chamber member. 33 is retracted from the lower chamber member 32 and the upper side of the lower chamber member 32 is opened.

In this way, after the pattern layer F ₃ of the transfer film F on the surface of the workpiece W is transferred, the picture layer F ₃ is painting on the surface of the workpiece W by peeling off the base film F ₁ of the transfer film F . In the thermal transfer device 31, after the pattern layer of the transfer film F is transferred to the surface of the workpiece W, the vapor in the space S aggregates to allow water droplets to adhere to the transfer film F. It can be cooled quickly.

  Further, in the thermal transfer device 31, the partition wall member 50 is supported by the upper chamber member 33 so as to be movable up and down, so that the partition wall member around the work W to which the transfer film F is closely attached without moving the upper chamber member 33. Since it can be enclosed by 50, the workability of painting can be improved and the cycle time can be shortened.

  Furthermore, the top plate 51 and the side plate 52 are respectively provided with heaters 57a and 52c for heating steam, and the heater 57a provided on the top plate 51 and the heater 52c provided on the side plate 52 can be independently controlled in temperature. By being done, temperature control according to the kind of transfer film F and the shape of the workpiece | work W can be performed. Even when the temperature of the steam from the steam generating source is lowered, the steam can be heated by the heaters 57a and 52c, and the effect can be obtained more effectively.

  In this embodiment as well, the compressed air is supplied to the space in the upper chamber member 33 using the compressed air pump 42. However, the space in the upper chamber member 33 that is in a vacuum state by opening the atmosphere release valve 49b is used. You may make it open | release to air | atmosphere. In addition, after opening the atmosphere release valve 49b to open the space in the upper chamber member 33 to the atmosphere, the opening / closing valve 46 is opened and the compressed air pump 42 is operated to further increase the pressure in the space in the upper chamber member 33 at a predetermined timing. It is also possible to supply

  Further, if necessary, the heater 57a provided on the top plate 51 is moved while the partition wall member 50 is moved slightly downward after the chamber members 32 and 33 are closed and before the steam is supplied into the space S. The transfer film F may be heated and softened in advance. Further, if necessary, the upper chamber member 33 may be preheated by operating the heater 57a provided on the top plate 51 before closing both the chamber members 32 and 33.

  Furthermore, if necessary, some of the plurality of holed bolts 58 may be replaced with holeless bolts that do not have through holes therein, and the holeless bolts may be attached to the openings 56 c of the steam plate 56. . Thereby, the supply position of steam can be adjusted according to the shape of the workpiece.

  In the thermal transfer device 31, the perforated bolt 58 and the holeless bolt are attached from above the bottom surface 56 a of the steam plate 56. The holed bolt 58 and the holeless bolt are attached from the lower side of the bottom surface 56 a of the steam plate 56. You may do it. Even in such a case, preferably, the perforated bolt 58 and the shaft portion 58c of the holeless bolt protrude from the bottom surface 56a of the steam plate 56 in order to prevent water drops from falling into the space in the partition wall member 50. It is attached with. In this case, since the perforated bolt 58 and the holeless bolt can be assembled or replaced while the steam plate 56 and the heating plate 57 are assembled, workability can be improved.

In the above-described embodiment, the thermal transfer apparatus using the transfer film F in which the release layer F ₂ , the pattern layer F _3, and the adhesive layer F ₄ are sequentially laminated on one surface of the base film F ₁ is described as the picture attaching apparatus. In this apparatus, instead of the transfer film F, an adhesive film that is not provided with the release layer F ₂ and in which the picture layer F ₃ and the adhesive layer F ₄ are sequentially laminated on one surface of the base film F ₁ is used. can, in this case, would be painting without peeling off the base film F _1, it is possible to obtain the same effect as the case of using the transfer film F as described above.

  As described above, according to the present invention, when the pattern layer of the pattern film is painted on the surface of the workpiece, the pattern film is brought into close contact regardless of the surface shape of the workpiece by heating the film with steam. Therefore, it is possible to satisfactorily paint on the part, and therefore, there is a possibility that it is suitably used in the manufacturing industry of the painting apparatus and the industrial field where the painting printing is performed.

DESCRIPTION OF SYMBOLS 1, 31 Thermal transfer apparatus 2, 32 Lower chamber member 3, 33 Upper chamber member 11, 41 Pressure air pump 12, 42 Vacuum pump 20 Steam supply device 21, 50 Partition wall member 22 Steam generator 51 Top plate 51a, 52a Supply passage 52 Side plate 52b, 58a Steam ejection hole 52c, 57a Heater W Work F Transfer film

Claims (5)

A painting device for painting using either one of a transfer film or a sticking film in which a pattern layer and an adhesive layer are sequentially laminated on one surface of a base film on the surface of a work,
A lower chamber member in which a work placing table on which a work is placed is disposed; and a pattern film is disposed on the upper surface of the work with the adhesive layer side facing the work;
An upper chamber member having an open lower surface that is in contact with the open upper surface of the lower chamber member with the pattern film interposed therebetween and forms a closed space with the lower chamber member;
A vacuuming device for bringing the pattern film into close contact with the surface of the workpiece by bringing the space partitioned by the pattern film in the lower chamber member into a vacuum state;
A partition wall member that forms a closed space surrounding the work by having a lower surface in contact with the work mounting table in a space formed by the upper and lower chamber members;
A steam supply device that supplies steam at a temperature at which the adhesive layer of the pattern film in close contact with the surface of the workpiece can be melted from the base film side in a closed space formed by the partition wall member. A device with a picture.   The partition wall member includes a top plate that covers the top surface of the workpiece and a side plate that covers the side surface, a supply passage that supplies steam to the top plate and the side plate, and the steam is jetted into a space in the partition wall member. The apparatus for painting according to claim 1, wherein a vapor ejection hole is formed. The top plate and the side plate are each provided with a heater for heating steam passing through the supply passage,
The painting apparatus according to claim 2, wherein the heater provided on the top plate and the heater provided on the side plate are configured to be independently temperature-controllable.   The said vapor | steam ejection hole is provided with two or more in the partition wall member, and can be selectively obstruct | occluded, The painting apparatus of Claim 2 or Claim 3 characterized by the above-mentioned.   The farting infrared ceramic coating is given to the inner surface of the said partition wall member, The painting apparatus of any one of Claims 1-4 characterized by the above-mentioned.

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