JPWO2014108995A1 - Metal film forming method and printing apparatus - Google Patents

Abstract

Metal film formation for forming a metal film on a circuit board by a printing apparatus 10 including a substrate holding device 32 that supports the circuit board 12 and a discharge head that discharges a particle dispersion in which metal particles are dispersed in a solvent. In the method, a particle dispersion liquid is discharged by a discharge head to form a coating film 70 of the particle dispersion liquid on the circuit board. The coating film is heated from the surface in contact with the circuit board by irradiating the electromagnetic wave absorbing material 72 included in at least one of the electromagnetic waves with electromagnetic waves. Thereby, since evaporation of the solvent proceeds from the lower side to the upper side of the coating film, the fusion of the metal particles is not inhibited and a dense metal film is formed. Further, the coating film is heated from the surface on the side in contact with the circuit board, so that the metal particles are efficiently diffused into the circuit board. Thereby, the adhesiveness of a metal film and a circuit board becomes high.

Description

  The present invention relates to a metal film forming method for forming a metal film on a print medium using a printing apparatus, and a printing apparatus.

  A printing apparatus for forming a metal film on a print medium includes a stage that supports the print medium and a discharge head that discharges a particle dispersion liquid in which metal particles are dispersed. In the apparatus, first, the particle dispersion is discharged onto the printing medium by the discharge head, whereby a coating film of the particle dispersion is formed. And the metal film is formed on a printing medium because the coating film is heated. In the printing apparatus described in the following patent document, the coating film of the particle dispersion is heated by irradiation with electromagnetic waves.

JP 2005-95849 A

  In the particle dispersion in which the metal particles are dispersed, the surface of the metal particles is coated with a dispersant in order to improve the dispersibility of the metal particles. For this reason, at the time of heating the coating film of the particle dispersion, first, the solvent evaporates, and then the dispersant is decomposed. A metal film is formed by fusing a plurality of metal particles.

  In the printing apparatus described in the above-mentioned patent document, the coating film of the particle dispersion is heated by irradiation with electromagnetic waves, and the temperature inside the coating film rises rapidly. For this reason, in the coating film, the evaporation of the solvent and the decomposition of the dispersant proceed at the same time, and the dispersant may be deteriorated. Since the altered dispersant remains in the coating film and inhibits fusion of the metal particles, there is a possibility that a dense metal film cannot be formed.

  Further, when the coating film of the particle dispersion liquid is heated by hot air or the like, solvent evaporation, decomposition of the dispersing agent, and fusion of the metal particles proceed from the surface of the coating film to the inside. . For this reason, first, the metal particles are fused on the surface of the coating film. This makes it difficult for oxygen to enter the inside of the coating film due to the metal particles fused on the surface of the coating film. Since oxygen is necessary for the decomposition of the dispersant, the dispersant may not be properly decomposed inside the coating film covered with the metal particles whose surfaces are fused. In such a case, the residual dispersant may inhibit the fusion of the metal particles, and a dense metal film may not be formed.

  The present invention has been made in view of such circumstances, and used a printing apparatus capable of appropriately heating a coating film of a particle dispersion and forming a dense metal film, and the printing apparatus. It is an object to provide a metal film forming method.

  In order to solve the above-described problems, a metal film forming method according to claim 1 of the present application is configured such that a stage that supports a printing medium and a particle dispersion in which metal particles are dispersed in a solvent are supported by the stage. A metal film forming method for forming a metal film on the print medium using a printing apparatus comprising a discharge head for discharging the print medium, wherein the discharge head is applied to the print medium supported by the stage. A coating film forming step of forming a coating film of the particle dispersion liquid by discharging the particle dispersion liquid, and a heating step of heating the coating film formed in the coating film forming step. The step of irradiating the electromagnetic wave absorbing material contained in at least one of the stage, the printing medium, and the lower part of the coating film between the printing medium and the coating film, thereby applying the electromagnetic wave to the coating film. On print media A step of heating the surface on the side.

  Moreover, in the metal film formation method of Claim 2, in the metal film formation method of Claim 1, the said particle dispersion liquid is what the said electromagnetic wave absorber was disperse | distributed in the solvent with the metal particle. The heating step is a step of heating the surface of the coating film in contact with the print medium by irradiating the electromagnetic wave absorbing material settled below the coating film with electromagnetic waves.

  The metal film forming method according to claim 3 is the metal film forming method according to claim 1, further comprising: an application step of applying the solution containing the electromagnetic wave absorbing material to the print medium supported by the stage. The coating film forming step is a step of forming the coating film on the solution applied in the application step, and the solution applied in the application step includes the printing medium and the coating film. It functions as the electromagnetic wave absorbing material included between the two.

  Further, in the metal film forming method according to claim 4, in the metal film forming method according to claim 1, the heating step irradiates the electromagnetic wave absorbing material included in the stage with electromagnetic waves, whereby the printing medium is used. It is the process of heating from the surface of the side which touches the said printing medium of the said coating film via.

  Moreover, in the metal film formation method of Claim 5, in the metal film formation method of Claim 1, the said heating process irradiates the electromagnetic wave absorber contained in the said print medium with electromagnetic waves, The said application | coating. It is a step of heating from the surface of the film in contact with the print medium.

  Further, the printing apparatus according to claim 6, a stage for supporting the print medium, a discharge head for discharging a particle dispersion liquid in which metal particles are dispersed in a solvent to the print medium supported by the stage, A printing apparatus including a moving device that moves the discharge head to an arbitrary position on the stage, wherein the discharge head discharges the particle dispersion liquid onto the print medium supported by the stage. Then, the coating film of the particle dispersion is formed, and the printing apparatus includes an electromagnetic wave included in at least one of the stage, the printing medium, and the lower part of the coating film between the printing medium and the coating film. An electromagnetic wave irradiation device is provided that heats the absorbing material from the surface that is in contact with the print medium by irradiating the absorbing material with electromagnetic waves.

  Further, in the printing apparatus according to claim 7, in the printing apparatus according to claim 6, the electromagnetic wave irradiation device is fixedly connected to the ejection head, and is moved to an arbitrary position by the moving device together with the ejection head. It is possible to move to.

  The method for forming a metal film according to claim 1 and the printing apparatus according to claim 6, wherein the electromagnetic wave absorption is included in at least one of a stage, a printing medium, and a lower part of the coating film between the printing medium and the coating film. By irradiating the material with electromagnetic waves, the coating film is heated from the surface in contact with the print medium. As a result, the evaporation of the solvent, the decomposition of the dispersant, and the fusion of the silver nanoparticles proceed from the bottom to the top of the coating, so that the fusion of the silver nanoparticles is not hindered, and a dense metal film is formed. It is formed. Further, the coating film is heated from the surface on the side in contact with the print medium, so that the metal particles in contact with the print medium are efficiently diffused into the print medium. Thereby, it becomes possible to make the adhesiveness of the metal film and printing medium by a metal particle high.

  In the metal film forming method according to claim 2, the electromagnetic wave absorbing material is dispersed in the particle dispersion together with the metal particles. And an electromagnetic wave is irradiated to the electromagnetic wave absorber which settled in the lower part of the coating film, and a coating film is heated from the surface in the side which contact | connects a printing medium. Thereby, it becomes possible to heat a coating film suitably from the surface of the side in contact with a printing medium. Moreover, in the metal film formation method of Claim 2, only the electromagnetic wave absorber which has settled in the coating film is heated. That is, only the portion to be heated is heated, and it is possible to increase the energy efficiency when forming the metal film. This makes it possible to reduce the energy required for heating and shorten the time required for heating, thereby realizing high throughput and low cost.

  In the metal film forming method according to claim 3, a solution containing an electromagnetic wave absorbing material is applied to a printing medium, and a coating film is formed on the applied solution. That is, the electromagnetic wave absorbing material is interposed between the printing medium and the coating film. Thereby, it becomes possible to heat a coating film suitably from the surface of the side in contact with a printing medium.

  Moreover, in the metal film formation method of Claim 4, the stage contains the electromagnetic wave absorber. Then, the electromagnetic wave is irradiated onto the electromagnetic wave absorbing material, whereby the coating film is heated from the surface on the side in contact with the printing medium through the printing medium. That is, the coating film can be heated from the surface in contact with the printing medium without performing the work of dispersing the electromagnetic wave absorbing material in the particle dispersion or the operation of applying the solution containing the electromagnetic wave absorbing material to the printing medium. It becomes possible. Therefore, according to the metal film forming method of the fourth aspect, it is possible to form a dense metal film by a relatively simple method.

  Moreover, in the metal film formation method of Claim 5, the electromagnetic wave absorber is contained in the printing medium. And the electromagnetic wave is irradiated to the electromagnetic wave absorber, and the coating film is heated from the surface on the side in contact with the print medium. As a result, a dense metal film can be formed by a relatively simple method as in the metal film forming method according to claim 4.

  In the printing apparatus according to the seventh aspect, the electromagnetic wave irradiation device is fixedly connected to the ejection head, and is moved to an arbitrary position by the moving device together with the ejection head. This eliminates the need to provide a dedicated device for moving the electromagnetic wave irradiation device. In addition, when irradiating the discharged particle dispersion with electromagnetic waves, it is not necessary to move the electromagnetic wave irradiation device, so that high throughput can be achieved.

It is a figure which shows the printing apparatus which is an Example of this invention. It is sectional drawing which shows the coating film heated by the electromagnetic wave irradiation to the electromagnetic wave absorber contained in the lower part of a coating film. It is sectional drawing which shows the coating film heated by irradiation of the electromagnetic wave to the electromagnetic wave absorber contained between a coating film and a circuit board. It is sectional drawing which shows the coating film heated by irradiation of the electromagnetic wave to the electromagnetic wave absorber contained in a circuit board. It is sectional drawing which shows the coating film heated by irradiation of the electromagnetic wave to the electromagnetic wave absorber contained in a board | substrate holding | maintenance apparatus.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments and modifications of the present invention will be described in detail with reference to the drawings as modes for carrying out the present invention. In addition, this invention is not limited to the following Examples and modifications, It can implement in the various aspect which gave various change and improvement based on the knowledge of those skilled in the art.

<Configuration of printing device>
FIG. 1 shows a printing apparatus 10 according to an embodiment of the present invention. The printing apparatus 10 is an apparatus for printing a circuit pattern on the circuit board 12. The printing apparatus 10 includes a transport device 20, a discharge head 22, an irradiation device 24, and a discharge head moving device (hereinafter, sometimes abbreviated as “moving device”) 26.

  The conveyance device 20 includes a pair of conveyor belts 30 extending in the X-axis direction and an electromagnetic motor (not shown) that rotates the conveyor belt 30. The circuit board 12 is supported by the pair of conveyor belts 30 and is conveyed in the X-axis direction by driving an electromagnetic motor. Further, the transfer device 20 has a substrate holding device 32. The substrate holding device 32 is disposed between the pair of conveyor belts 30 and holds the circuit board 12 supported by the conveyor belts 30 in a fixed manner.

  The discharge head 22 is an ink jet type discharge head, and discharges conductive ink, specifically, a silver nanoparticle paste. In the silver nanoparticle paste, the surface of silver nanoparticles is coated with a dispersant, and the silver nanoparticles are dispersed in a solvent. The ejection head 22 that ejects the silver nanoparticle paste has a head body 36 and an ejection nozzle 38. The discharge nozzle 38 is attached to the lower end of the head body 36, and the discharge nozzle 38 has a plurality of nozzle holes (not shown) for discharging the silver nanoparticle paste. Then, in accordance with the electrical signal, the silver nanoparticle paste is ejected from the nozzle hole using a piezoelectric element (not shown) or a vapor bubble caused by heat as a drive source.

  The irradiation device 24 is a device that irradiates electromagnetic waves, specifically, electromagnetic waves having a relatively high frequency of several MHz to several hundred GHz, and is attached to the lower end portion of the head main body 36 of the ejection head 22. As a result, electromagnetic waves are emitted from above the circuit board 12 toward the circuit board 12.

  The moving device 26 includes an X-axis direction slide mechanism 50 and a Y-axis direction slide mechanism 52. The X-axis direction slide mechanism 50 has an X-axis slider 56 provided on the base 54 so as to be movable in the X-axis direction. The X-axis slider 56 moves to an arbitrary position in the X-axis direction by driving an electromagnetic motor (not shown). The Y-axis direction slide mechanism 52 has a Y-axis slider 60 provided on the side surface of the X-axis slider 56 so as to be movable in the Y-axis direction. The Y-axis slider 60 moves to an arbitrary position in the Y-axis direction by driving an electromagnetic motor (not shown). A head main body 36 of the ejection head 22 is attached to the Y-axis slider 60. With such a structure, the discharge nozzle 38 and the irradiation device 24 are moved to arbitrary positions on the base 54 by the moving device 26.

<Operation of printing device>
With the configuration described above, in the printing apparatus 10, a silver nanoparticle paste coating film is formed on the upper surface of the circuit board 12 by discharging the silver nanoparticle paste. Then, by heating the coating film of the silver nanoparticle paste, the silver nanoparticles are fused, and the circuit pattern is printed on the circuit board 12. Specifically, first, the circuit board 12 is transported to the working position by a command from a control device (not shown) that controls the operation of the printing apparatus 10, and the circuit board 12 is fixed by the board holding device 32 at that position. Retained.

  Then, the ejection head 22 moves above the circuit board 12 by the operation of the moving device 26. Subsequently, the silver nanoparticle paste is discharged from the discharge nozzle 38 onto the upper surface of the circuit board 12. Thereby, as shown in FIG. 2, a coating film 70 of the silver nanoparticle paste is formed on the upper surface of the circuit board 12.

  In the silver nanoparticle paste, a particulate electromagnetic wave absorbing material 72 is dispersed in a solvent together with silver nanoparticles. The electromagnetic wave absorber 72 is formed of a material that easily absorbs electromagnetic waves, for example, copper oxide, silver oxide, nickel oxide, carbon black, carbon nanotube, carbon fullerene, and the like. It is larger than the diameter. Specifically, the silver nanoparticles have a particle size of several nm to several hundred nm, and the electromagnetic wave absorber 72 has a particle size of 0.5 μm to 5 μm. For this reason, the electromagnetic wave absorbing material 72 settles inside the coating film 70 and is positioned below the coating film 70 as shown in FIG.

  Then, the electromagnetic wave is irradiated by the irradiation device 24 toward the coating film 70. The irradiated electromagnetic wave is absorbed by the electromagnetic wave absorber 72 that has settled in the coating film 70, and heats the coating film 70 from below. That is, the surface of the coating film 70 that is in contact with the circuit board 12 is heated. Thereby, the solvent of the silver nanoparticle paste which comprises the coating film 70 evaporates sequentially from the surface of the coating film 70 on the side in contact with the circuit board 12. Then, the dispersant coated on the surface of the silver nanoparticles is sequentially decomposed from the surface of the coating film 70 on the side in contact with the circuit board 12, and the plurality of silver nanoparticles are fused to each other. At this time, silver nanoparticles are diffused into the circuit board 12 on the surface of the coating film 70 on the side in contact with the circuit board 12. When the evaporation of the solvent, the decomposition of the dispersant, and the fusion of the silver nanoparticles proceed to the upper surface of the coating film 70, the circuit pattern is printed on the circuit board 12. That is, the silver nanoparticles in contact with the circuit board 12 are diffused into the circuit board 12, and the silver nanoparticles are fused on the entire coating film 70, whereby the circuit pattern is printed on the circuit board 12.

  As described above, in the printing apparatus 10, when the coating film 70 is heated from the surface on the side in contact with the circuit board 12, the silver nanoparticles in contact with the circuit board 12 diffuse into the circuit board 12, and the silver nanoparticles are The film 70 is fused from below to above. On the other hand, in the conventional printing apparatus, the coating film of the silver nanoparticle paste formed on the upper surface of the circuit board is heated by an electric furnace or the like. When the coating film of the silver nanoparticle paste is heated using an electric furnace or the like, first, the solvent is evaporated, the dispersant is decomposed, and the silver nanoparticles are fused on the surface of the coating film. Evaporation, decomposition of the dispersing agent, and fusion of the silver nanoparticles proceed toward the inside of the coating film 70.

  However, when the silver nanoparticles are fused on the surface of the coating film, the coating film is covered with the fused silver nanoparticles, and oxygen does not easily enter the coating film. Since oxygen is necessary for the decomposition of the dispersant, the dispersant may not be properly decomposed inside the coating film. In such a case, the remaining dispersant inhibits the fusion of the silver nanoparticles, and there is a possibility that a dense metal film, that is, a circuit pattern cannot be formed.

  In view of such a situation, in the printing apparatus 10, as described above, the electromagnetic wave absorbing material 72 has settled in the coating film 70, and the electromagnetic wave absorbing material 72 is irradiated with electromagnetic waves, whereby the coating film 70. Is heated from the surface in contact with the circuit board 12. As a result, the evaporation of the solvent, the decomposition of the dispersant, and the fusion of the silver nanoparticles proceed from the lower side to the upper side of the coating film 70, so that the fusion of the silver nanoparticles is not hindered, and the dense metal film Is formed.

  In addition, when the coating film 70 is heated from the surface in contact with the circuit board 12, the silver nanoparticles in contact with the circuit board 12 are efficiently diffused into the circuit board 12. Thereby, the adhesiveness between the metal film made of silver nanoparticles and the circuit board 12 can be increased.

  Furthermore, when the coating film is heated by an electric furnace or the like, the entire circuit board 12 is heated. On the other hand, in the printing apparatus 10, only the electromagnetic wave absorber 72 settled on the coating film 70 is heated. That is, in the printing apparatus 10, only the part to be heated is heated, and it is possible to increase the energy efficiency at the time of forming the metal film. As a result, it is possible to suppress the energy required for heating and shorten the time required for heating, thereby realizing high throughput, low cost, and the like.

<Modification 1>
In the said Example, although the coating film 70 is heated from the bottom by irradiating electromagnetic waves to the electromagnetic wave absorber 72 settled in the coating film 70, if it is a position which can heat a coating film from the bottom, It is possible to arrange the electromagnetic wave absorbing material in various places. Specifically, a printing apparatus in which an electromagnetic wave absorbing material is disposed between the coating film and the circuit board and the coating film is heated by the electromagnetic wave absorbing material is shown in FIG. The printing apparatus 80 has the same configuration as that of the printing apparatus 10 except for the silver nanoparticle paste coating film and the electromagnetic wave absorbing material. Therefore, the same reference numerals are used for components having the same functions as the printing apparatus 10. The description will be omitted or simplified.

  In the printing apparatus 80 according to the first modification, as shown in FIG. 3, the solution 84 containing the electromagnetic wave absorbing material 82 is applied onto the circuit board 12 held by the board holding device 32. The electromagnetic wave absorbing material 82 is formed of the same material as the electromagnetic wave absorbing material 72, but the particle size thereof may not be larger than the particle size of the silver nanoparticles. The application of the solution 84 can be performed by various methods such as mask printing using a mask and a squeegee, and discharging the solution 84 using a discharge head or the like.

  Then, the silver nanoparticle paste is ejected by the ejection head 22 onto the solution 84 applied on the circuit board 12. Thereby, a coating film 86 of the silver nanoparticle paste is formed on the solution 84. In addition, although silver nanoparticle is disperse | distributed to this silver nanoparticle paste, the electromagnetic wave absorber is not disperse | distributed.

  When the coating film 86 is formed on the solution 84, electromagnetic waves are irradiated by the irradiation device 24 toward the coating film 86. The irradiated electromagnetic wave is absorbed by the electromagnetic wave absorbing material 82 contained in the solution 84 and heats the coating film 86 from below. Thereby, also in the coating film 86, the evaporation of the solvent, the decomposition of the dispersing agent, and the fusion of the silver nanoparticles proceed from the bottom to the top of the coating film 86 in the same manner as in the above-described embodiment. The same effect can be obtained.

<Modification 2>
Unlike the above examples and modifications, an electromagnetic wave absorbing material may be disposed in a circuit board, and the coating film of the silver nanoparticle paste may be heated by the electromagnetic wave absorbing material. Specifically, a printing apparatus in which a coating film of silver nanoparticle paste is formed on a circuit board including an electromagnetic wave absorbing material and the coating film is heated by the electromagnetic wave absorbing material is referred to as a printing apparatus 90 of Modification 2 as shown in FIG. Shown in Since the printing apparatus 90 has the same configuration as that of the printing apparatus 10 except for the circuit board, the same reference numerals are used for the components having the same functions as those of the printing apparatus 10 and description thereof is omitted or simplified.

  In the printing apparatus 90 according to the second modification, as illustrated in FIG. 4, an electromagnetic wave absorbing material 96 is contained in the circuit board 92. Then, the silver nanoparticle paste is ejected by the ejection head 22 on the circuit substrate 92, thereby forming a coating film 98 of the silver nanoparticle paste. In addition, although silver nanoparticle is disperse | distributed to this silver nanoparticle paste, the electromagnetic wave absorber is not disperse | distributed.

  When the coating film 98 is formed on the circuit board 92, electromagnetic waves are irradiated by the irradiation device 24 toward the coating film 98. The irradiated electromagnetic wave is absorbed by the electromagnetic wave absorbing material 96 included in the circuit board 92 and heats the coating film 98 from below. As a result, in the coating film 98, similarly to the coating film 70, the evaporation of the solvent, the decomposition of the dispersant, and the fusion of the silver nanoparticles proceed from the bottom to the top of the coating film 98. The same effect can be obtained.

<Modification 3>
Unlike the above embodiments and modifications, an electromagnetic wave absorbing material may be disposed in a substrate holding device for holding a circuit board, and the coating film of the silver nanoparticle paste may be heated by the electromagnetic wave absorbing material. Specifically, the circuit board is held by a substrate holding device containing an electromagnetic wave absorber, and the silver nanoparticle paste coating film formed on the circuit board is heated by the electromagnetic wave absorber contained in the substrate holding device. The apparatus is shown in FIG. 5 as a printing apparatus 100 according to the third modification. Since the printing apparatus 100 has the same configuration as the printing apparatus 10 except for the substrate holding apparatus, the same reference numerals are used for the components having the same functions as the printing apparatus 10 and the description thereof is omitted or simplified. .

  In the printing apparatus 100 of Modification 3, as shown in FIG. 5, the substrate holding device 102 contains an electromagnetic wave absorber 106, and the circuit board 12 is held by the substrate holding device 102. Then, a silver nanoparticle paste coating film 108 is formed on the circuit board 12 by discharging the silver nanoparticle paste by the discharge head 22. In addition, although silver nanoparticle is disperse | distributed to this silver nanoparticle paste, the electromagnetic wave absorber is not disperse | distributed.

  When the coating film 108 is formed on the circuit board 12, electromagnetic waves are irradiated by the irradiation device 24 toward the coating film 108. The irradiated electromagnetic wave is absorbed by the electromagnetic wave absorber 106 included in the substrate holding device 102 and heats the circuit board 12. The coated substrate 108 is heated from the surface on the side in contact with the circuit substrate 12 by the heated circuit substrate 12. That is, the coating film 108 is heated from below through the circuit board 12 by irradiation with electromagnetic waves. Thereby, also in the coating film 108, the evaporation of the solvent, the decomposition of the dispersing agent, and the fusion of the silver nanoparticles proceed from the bottom to the top of the coating film 108, as in the above-described coating film 70. The same effect can be obtained.

  Incidentally, in the above-described embodiment, the printing apparatus 10 is an example of a printing apparatus. The circuit boards 12 and 92 are examples of print media. The ejection head 22 is an example of an ejection head. The irradiation device 24 is an example of an electromagnetic wave irradiation device. The moving device 26 is an example of a moving device. The substrate holding devices 32 and 102 are an example of a stage. The coating films 70, 86, 98, and 108 are examples of coating films. The electromagnetic wave absorbers 72, 82, 96, and 106 are examples of the electromagnetic wave absorber. The silver nanoparticle paste is an example of a particle dispersion, and the silver nanoparticles are an example of metal particles.

  Moreover, the formation method of the metal film by the silver nanoparticle in the said Example and modification is an example of the metal film shaping | molding method. The step of discharging the silver nanoparticle paste onto the circuit boards 12 and 92 by the discharge head 22 to form the coating films 70, 86, 98, and 108 of the silver nanoparticle paste is an example of the coating film forming step. Irradiating the electromagnetic wave absorbing material 72 settled in the coating film 70, the electromagnetic wave absorbing material 82 contained in the solution 84, the electromagnetic wave absorbing material 96 contained in the circuit board 92, and the electromagnetic wave absorbing material 106 contained in the substrate holding device 102. Thus, the process of heating the coating films 70, 86, 98, 108 is an example of the heating process. The process of applying the solution 84 on the circuit board 12 is an example of the application process.

  DESCRIPTION OF SYMBOLS 10: Printing apparatus 12: Circuit board (printing medium) 22: Discharge head 24: Irradiation apparatus (electromagnetic wave irradiation apparatus) 26: Moving apparatus 32: Substrate holding apparatus (stage) 70: Coating film 72: Electromagnetic wave absorber 82: Electromagnetic wave absorption Material 86: Coating film 92: Circuit board (printing medium) 96: Electromagnetic wave absorbing material 98: Coating film 102: Substrate holding device (stage) 106: Electromagnetic wave absorbing material 108: Coating film

Claims (7)

A stage for supporting the print medium;
A metal film that forms a metal film on the print medium using a printing apparatus that includes a discharge head that discharges a particle dispersion liquid in which metal particles are dispersed in a solvent to the print medium supported by the stage. In the forming method,
The metal film forming method is
A coating film forming step of forming a coating film of the particle dispersion liquid by discharging the particle dispersion liquid to the print medium supported by the stage by the discharge head;
A heating step of heating the coating film formed in the coating film forming step,
The heating step is
By irradiating the electromagnetic wave absorbing material contained in at least one of the stage, the printing medium, and the lower part of the coating film between the printing medium and the coating film, electromagnetic waves are applied to the printing medium of the coating film. A method for forming a metal film, which is a step of heating from the surface on the side in contact. The particle dispersion is
Along with the metal particles, the electromagnetic wave absorbing material is dispersed in a solvent,
The heating step is
2. The method of forming a metal film according to claim 1, which is a step of heating the surface of the coating film in contact with the printing medium by irradiating the electromagnetic wave absorbing material settled below the coating film with electromagnetic waves. The metal film forming method is
An application step of applying a solution containing the electromagnetic wave absorbing material to the print medium supported by the stage;
The coating film forming step
A step of forming the coating film on the solution applied in the application step;
The solution applied in the application step is
The metal film forming method according to claim 1, which functions as the electromagnetic wave absorbing material contained between the print medium and the coating film. The heating step is
2. The metal film formation according to claim 1, wherein the electromagnetic wave absorbing material included in the stage is heated from the surface of the coating film in contact with the printing medium through the printing medium by irradiating the electromagnetic wave with the electromagnetic wave. Method. The heating step is
2. The method of forming a metal film according to claim 1, wherein the method is a step of heating the surface of the coating film in contact with the printing medium by irradiating the electromagnetic wave absorbing material contained in the printing medium with electromagnetic waves. A stage for supporting the print medium;
A discharge head for discharging a particle dispersion liquid in which metal particles are dispersed in a solvent to the printing medium supported by the stage;
In a printing apparatus comprising: a moving device that moves the discharge head to an arbitrary position on the stage;
The ejection head is
By discharging the particle dispersion onto the printing medium supported by the stage, a coating film of the particle dispersion is formed,
The printing device is
By irradiating the electromagnetic wave absorbing material contained in at least one of the stage, the printing medium, and the lower part of the coating film between the printing medium and the coating film, electromagnetic waves are applied to the printing medium of the coating film. A printing apparatus provided with an electromagnetic wave irradiation device that heats from the surface on the side in contact. The electromagnetic wave irradiation device is
The printing apparatus according to claim 6, wherein the printing apparatus is fixedly connected to the discharge head and is movable together with the discharge head to an arbitrary position by the moving device.

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