KR20190056301A - Film formation apparatus - Google Patents

Abstract

Provided is a film forming apparatus capable of removing a cooling plate, which is in close contact with a protective sheet on which electronic components are arranged, without separation of the electronic components from the protective sheet. To this end, the film forming apparatus (7) peels off the protective sheet (61) from the cooling plate (63) through which an air hole (632) passing through two sides of the plate is formed. The film forming apparatus (7) is provided with a film forming processing portion (3) and a plate releasing portion (4). The film forming processing portion (3) deposits a film forming material by sputtering with respect to the electronic component (60) on the protective sheet (61) which is in close contact with the cooling plate (63), and forms a film. The plate releasing portion (4) has an air pressure supply hole (423) and a fixing portion. The air pressure supply hole (423) faces the cooling plate (63) and is provided in a range including a component arrangement region (615) to generate a static pressure. The fixing portion presses a frame (62) firmly while the component arrangement region (615) is being pressed, and releases the firm press after the component arrangement region (615) is separated from the cooling plate (63).

Description

[0001] FILM FORMATION APPARATUS [0002]

The present invention relates to a film forming apparatus.

BACKGROUND ART A plurality of electronic components such as semiconductor devices are mounted on a wireless communication device represented by a cellular phone. In order to prevent the electronic component from affecting the communication characteristics, it is required to suppress the influence of electromagnetic waves on the inside and outside, such as leakage of electromagnetic waves to the outside. For this reason, electronic parts having a shielding function for electromagnetic waves are used.

Generally, an electronic component is formed by mounting an element on an interposer substrate as a relay substrate for a mounting substrate, and sealing the element with a resin. Electronic parts having a shielding function by providing a conductive electromagnetic wave shielding film on the upper and side surfaces of the sealing resin have been developed (see Patent Document 1).

Such an electromagnetic wave shielding film can be a laminated film of a plurality of kinds of metal materials. For example, an electromagnetic wave shielding film having a laminated structure in which a Cu film is formed after forming an SUS film and an SUS film is formed thereon is known.

In order to obtain a sufficient shielding effect in the electromagnetic wave shield film, it is necessary to lower the electric resistivity. For this reason, the electromagnetic wave shielding film is required to have a certain thickness. In a semiconductor device, it is generally considered that a good shielding property can be obtained when the film thickness is about 1 to 10 mu m. It is known that a good shielding effect can be obtained when the electromagnetic wave shielding film having the laminated structure of SUS, Cu, and SUS has a thickness of about 1 to 5 mu m.

As a method of forming an electromagnetic wave shielding film, a sputtering method which is a dry process has attracted attention. As a film forming apparatus by the sputtering method, there has been proposed a plasma processing apparatus for forming a film by using plasma. In the plasma processing apparatus, an inert gas is introduced into a vacuum container in which a target is placed, and a DC voltage is applied. Ions of a plasma-generated inert gas are caused to collide against a target of a film-forming material, and a film formed by depositing a material, which is pounded from the target, on the work.

A general plasma processing apparatus is used for forming a film having a thickness of several tens to several hundreds of nanometers, which can be formed at a processing time of several ten seconds to several minutes. However, as described above, it is necessary to form a film having a micron level thickness as the electromagnetic wave shielding film. The sputtering technique is a technique for forming a film by depositing particles of a film forming material on an object to be film-formed, so that the thicker the film to be formed, the longer the time required for forming the film.

Therefore, in order to form an electromagnetic wave shield film, a processing time of several tens minutes to one hour is required, which is longer than a general sputtering method. For example, in the electromagnetic shielding film of the laminated structure of SUS, Cu, and SUS, a processing time exceeding one hour is required to obtain a film thickness of 5 mu m. Then, in the sputtering method using the plasma, the package, which is an enclosure of the electronic component, is continuously exposed to the heat of the plasma during the processing time. As a result, the package may be heated up to about 200 캜 until a film having a thickness of 5 탆 is obtained.

On the other hand, the heat-resistant temperature of the package is about 200 ° C for temporary heating of about several seconds to several tens of seconds, but usually about 150 ° C when heating is more than several minutes. For this reason, it has been difficult to form a microwave-level electromagnetic wave shielding film by using a general plasma sputtering method.

Therefore, the applicant of the present invention proposes to arrange an electronic component on a protective sheet in Japanese Patent Application No. 2016-240856, and to adhere the protective sheet to the cooling plate. The protective sheet can be brought into close contact with the cooling plate through the adhesive sheet, for example. Even if the electronic component is heated during the film forming process by the sputtering method, the heat of the electronic component is transferred to the cooling plate, so that the excessive accumulation of heat in the electronic component is suppressed.

Patent Document 1: International Publication No. 2013/035819

The electronic component is finally detached from the cooling plate and peeled off from the protective sheet. In order to remove the cooling plate, it is conceivable to fix the cooling plate and hook the outer periphery of the protective sheet to lift it from the surrounding area. According to this method, the central area of the protective sheet remains to the end of the cooling plate, and the protective sheet is bent into a cone shape. Then, when the central region is peeled from the cooling plate, the elasticity of the protective sheet repels the central region to adhere to the outer periphery. In the worst case, the electronic parts arranged on the protective sheet are accelerated by the repulsive force of the protective sheet, and are peeled off from the protective sheet and scattered. If the electronic parts are scattered, it is necessary to rearrange and rearrange the electronic parts, and the electronic parts may be damaged.

An object of the present invention is to provide a film forming apparatus capable of removing a cooling plate in close contact with a protective sheet on which electronic components are arranged while preventing the electronic components from being detached from the protective sheet.

In order to achieve the above object, the present invention is a film forming apparatus for an electronic component arranged on a protective sheet in close contact with a cooling plate, wherein the electronic component on the protective sheet adhered to the cooling plate is sputtered to form a film forming material And a plate releasing portion for releasing the cooling plate after passing through the film forming portion, wherein the cooling plate has an air hole passing through the front and back in a region including the region where the electronic component is arranged, Wherein the plate releasing portion includes an arrangement base having a static pressure generating hole for generating a static pressure and facing the air hole of the cooling plate, While the pressing is performed, the electronic parts in the protective sheet are arranged Is characterized by having a fixing portion for firmly depressing a portion deviated from the region and releasing the pressing after the region where the electronic component is arranged is separated from the cooling plate.

Wherein the plate releasing portion has a flat surface spaced apart from the protective sheet and located on the side opposite to the cooling plate with the protective sheet interposed therebetween, , The protrusion of the protective sheet in the region where the electronic component is arranged may be pressed firmly.

Wherein the plate releasing portion has a negative pressure generating hole opened on the flat surface and generating a negative pressure and the negative pressure generating hole is pressed against a region where the electronic component is arranged through the positive pressure generating hole, It is also possible to suck it out.

Wherein the cooling plate has an insertion hole at a portion which is out of the region where the electronic component is arranged and is pressed firmly by the fixing portion and the plate releasing portion is located at a position where the region where the electronic component is arranged is separated from the cooling plate, And a pusher which advances inside the insertion hole of the cooling plate and pushes up a portion of the protective sheet which is firmly pressed by the fixing portion in a direction away from the cooling plate, The pusher may be moved away from the cooling plate together with the advance of the pusher.

According to the present invention, the cooling plate can be detached from the protective sheet while preventing the electronic component from being detached from the protective sheet.

1 is a side view showing an electronic component subjected to film formation.
2 is a side view showing the state of an electronic component subjected to a film forming process.
3 is an exploded perspective view showing the state of the electronic component when the film forming process is performed.
4 is a transition diagram showing a film forming process flow of the electronic component.
5 is a block diagram showing the configuration of the film forming apparatus.
6 is a schematic diagram showing a configuration of an embedding processing unit.
7 is a transition diagram schematically showing a state in each step of the embedding processing section.
8 is an enlarged view of the electronic parts in the embedding processing unit.
9 is a schematic diagram showing the configuration of the plate mounting portion.
10 is a transition diagram schematically showing a state of each step of the plate mounting portion.
11 is a schematic diagram showing the configuration of the film forming unit.
12 is a schematic diagram showing the configuration of the plate releasing portion.
13 is a transition diagram schematically showing a state in each step of the plate releasing portion.
14 is a schematic diagram showing another configuration of the plate releasing portion.
15 is a schematic view showing another configuration of the plate releasing portion.
16 is a schematic diagram showing the configuration of the peeling treatment section.
Fig. 17 is a view showing the top surface of the part-embedded sheet in the peeling treatment section. Fig.
18 is a transition diagram schematically showing the state in each step of the peeling treatment section.
Fig. 19 is a schematic diagram showing an embodiment for preventing the rising of the electronic parts.
Fig. 20 is a photograph of the electrode after the electronic component is peeled off from the protective sheet by the peeling treatment unit. Fig.
21 is a plan view showing another embodiment of the part-embedded sheet in the peeling process section.
22 is a plan view showing still another embodiment of the part-embedded sheet in the peeling treatment section.
23 is a plan view showing still another embodiment of the part-embedded sheet in the peeling treatment section.
24 is a block diagram showing another configuration of the film forming apparatus.
25 is a schematic diagram showing a configuration of a conventional pull-up device.
26 is a schematic diagram showing the lifting of an electronic component in the conventional pull-up device.
27 is a photograph showing a state of the electrode after the adhesive film is reattached to the electronic component.

(Electronic parts)

1 is a side view showing an electronic component subjected to film formation. As shown in Fig. 1, an electromagnetic wave shield film 605 is formed on the surface of the electronic component 60. Fig. The electronic component 60 is a surface mount component such as a semiconductor chip, a diode, a transistor, a capacitor, or a SAW filter. A semiconductor chip is an integrated circuit such as an IC or an LSI in which a plurality of electronic elements are integrated. This electronic component has a substantially rectangular parallelepiped shape such as BGA, LGA, SOP, QFP, and WLP, and one surface is an electrode exposed surface 601. The electrode exposed surface 601 is a surface exposed to the electrode 602 and connected to the mounting substrate facing the mounting substrate. The electrode 602 is an electrode called a ball bump or a solder ball bump, and is formed by mounting a ball-shaped solder (solder ball) having a diameter of several tens of micrometers to several hundreds of micrometers on a pad electrode.

The electromagnetic shielding film 605 shields electromagnetic waves. The electromagnetic wave shield film 605 is formed of a material such as Al, Ag, Ti, Nb, Pd, Pt, Zr, or the like. The electromagnetic wave shield film 605 may be formed of a magnetic material such as Ni, Fe, Cr, or Co. Further, SUS, Ni, Ti, V, Ta or the like may be formed as a base layer of the electromagnetic wave shield film 605, and SUS, Au or the like may be formed as a top protective layer.

The electromagnetic shielding film 605 is formed on the outer surface other than the upper surface 603 and the side surface 604 of the electronic component 60, that is, the electrode exposed surface 601. The upper surface 603 is a surface opposite to the electrode-exposed surface 601. The side surface 604 is an outer circumferential surface that connects the upper surface 603 and the electrode exposed surface 601 and extends at an angle different from that of the upper surface 603 and the electrode exposed surface 601. In order to obtain a shielding effect of electromagnetic wave shielding, the electromagnetic shielding film 605 may be formed on at least the upper surface 603. On the side surface 604, there is a ground pin outside the drawing. The formation of the electromagnetic shielding film 605 on the side surface is also for the grounding of the electromagnetic shielding film 605.

(At the time of film formation)

2 is a side view showing the state of the electronic component after the film forming process. 3 is an exploded perspective view showing the state of the electronic component when the film forming process is performed. 2 and 3, in the electronic component 60, the electrode 602 is embedded in the protective sheet 61 in advance, and the electrode exposed surface 601 is in close contact with the protective sheet 61 . By embedding the electrode 602 in the protective sheet 61, the particles of the electromagnetic shielding film 605 are prevented from reaching the electrode 602. The electrode 602 and the protective sheet 61 can be prevented from entering the space between the electrode exposed surface 601 and the protective sheet 61 by the contact of the electrode exposed surface 601 and the protective sheet 61, The possibility of the particles of the electromagnetic wave shielding film 605 reaching is lowered.

The protective sheet 61 is a heat-resistant synthetic resin such as PEN (polyethylene naphthalate) or PI (polyimide). One side of the protective sheet 61 is an adhesive surface (adhesive layer) 611 having flexibility to which the electrode 602 fills and adherence to which the electrode exposed surface 601 adheres. As the adhesive surface 611, a variety of adhesive materials such as silicone-based, acrylic-based resin, urethane resin, and epoxy resin are used.

The adhesive surface 611 has an outer mold area 613 extending to a certain distance inward from the end of the protective sheet 61 and an inner mold area 613 reaching a predetermined distance inward from the inner periphery of the outer mold area 613 614, and a component arrangement region 615 inside the inner mold region 614. The electronic component 60 is adhered to the component arrangement region 615. Shaped frame 62 is bonded to the outer frame region 613. [ The inner frame area 614 is a range in which the deflection of the protective sheet 61 occurs and neither the frame 62 nor the electronic component 60 is bonded. Further, the opposite surface of the adhesive surface 611 is the non-adhesive surface 612.

The protective sheet 61 is adhered to the cooling plate 63 through the adhesive sheet 64. [ The cooling plate 63 is made of metal such as SUS, ceramics, resin, or other material having high thermal conductivity. The cooling plate 63 is a heat dissipation furnace that dissolves the heat of the electronic components and suppresses excessive heat accumulation. The adhesive sheet 64 has adhesiveness on both sides and enhances the adhesion between the protective sheet 61 and the cooling plate 63 to secure the heat transfer area to the cooling plate 63. [

The height H1 from the surface of the component arrangement region 615 to the top surface of the frame 62 is the height H2 from the surface of the component arrangement region 615 to the top surface 603 of the electronic component 60, (See Fig. 4). Here, the height H1 is equivalent to the thickness H1 for the sake of convenience. In other words, assuming that a flat plate is placed on the frame 62, the upper surface 603 of the electronic component 60 is not in contact with the flat plate.

At one end of the frame 62, a guide portion insertion hole 621 is formed. The guide portion insertion hole 621 has an opening such as an elongated ellipse, a rectangle or a round circle along the end portion of the frame 62 and has a surface to be adhered to the protective sheet 61 of the frame 62, As shown in FIG. That is, for example, the rod-shaped member is inserted into the guide portion insertion hole 621 and the end of the protective sheet 61 is pressed (see Fig. 18), and one end of the protective sheet 61 is peeled off from the frame 62 .

A pusher insertion hole 631 is formed in the cooling plate 63 and the adhesive sheet 64. The pusher inserting hole 631 is formed so as not to coincide with the guiding portion inserting hole 621 but at a position closed by the frame 62. [ The pusher inserting hole 631 is formed so that the entire frame 62 is lifted in parallel when the frame 62 is pushed up from the front end of the rod member by inserting a rod member, for example, into the pusher inserting hole 631, do. For example, if the frame 62 is a rectangular frame, the pusher insertion holes 631 are located at the four corners or at the center of each side. From the viewpoint of maintaining the frame 62 in parallel, it is preferable that the rod-like member has a rectangular front end face, that is, a slender plate or L-shaped cross section, but the present invention is not limited to this, There may be. The pusher inserting hole 631 has a rectangular, L-shaped or rounded circular shape correspondingly.

The cooling plate 63 and the adhesive sheet 64 are provided with fine air holes 632 at regular intervals over the entire region where the inner frame region 614 and the component arrangement region 615 of the protective sheet 61 are bonded Are formed. The air holes 632 are, for example, microcylindrical or slit-shaped. The air hole 632 is provided in order to apply a negative pressure or a positive pressure to the at least part arrangement region 615 of the protective sheet 61 adhered to the cooling plate 63 through the air hole 632 without smudging. The number of the air holes 632 and the through-forming interval and the through-forming range are not limited to this. For example, even if the air holes 632 are formed only in the range corresponding to the component arrangement region 615, the cooling plate 63 and the adhesive sheet 64 Air holes 632 may be arranged closely to the center of the component arranging region 615 and only one of the air holes 632 may be formed at a position corresponding to the center of the component arranging region 615.

(Film forming process flow)

In the film forming process, the electromagnetic shielding film 605 is formed and the individual separated electronic components 60 are obtained through the component placing process, the component embedding process, the plate mounting process, the film forming process, the plate removing process and the component peeling process have.

Fig. 4 is a view showing a film forming process flow of an electronic part. 4, in the component placement step, the electrode-exposed surface 601 of the electronic component 60 is exposed to the component-unseated sheet 65 to which the frame 62 is adhered to the protective sheet 61, The electronic component 60 is laid out in the component arrangement region 615. In this case, A state in which the frame 62 is bonded to the protective sheet 61 and the electronic component 60 is arranged but the electrode 602 is not yet embedded is referred to as a component placement completed sheet 66. [

The electrode 602 is embedded in the protective sheet 61 with respect to the component placement completed sheet 66 and the electrode exposed surface 601 is brought into close contact with the protective sheet 61. [ The state in which the electrode 602 is buried in the protective sheet 61 is referred to as a part embedding complete sheet 67 regardless of whether the electromagnetic shielding film 605 is formed or not. In the plate attaching step, the part-embedded sheet 67 is brought into close contact with the cooling plate 63 through the adhesive sheet 64. The state in which the cooling plate 63 is mounted is referred to as a component placement plate 68.

Particles of the electromagnetic shielding film 605 are deposited from the side of the top surface 603 of the electronic component 60 to form the electromagnetic shielding film 605 on the electronic component 60. [ At this time, the electrode 602 of the electronic component 60 is buried in the protective sheet 61, and the electrode exposed surface 601 is in close contact with the protective sheet 61, so that the particles 605 of the electromagnetic shielding film 605 Is prevented from adhering to the electrode (602).

In the plate releasing step, the cooling plate 63 is removed and returned to the form of the part-embedded-sheet 67. In the component peeling process, the electronic component 60 is peeled off from the protective sheet 61 and separated into the component-unequipped sheet 65 and the individual electronic component 60. Further, in order to reuse the frame 62, the protective sheet 61 is peeled off from the frame 62. Thus, the film forming process is completed.

(Film forming apparatus)

FIG. 5 shows a film forming apparatus that performs the component filling step, the plate mounting step, the film forming step, the plate releasing step and the component stripping step in the film forming process flow described above. 5, the film forming apparatus 7 is provided with an embedding processing section 1, a plate mounting section 2, a film forming section 3, a plate releasing section 4, and a peeling processing section 5. The parts between the parts are connected by the carrying part 73, the members necessary for each step are put in, and the members after the processing in each step are discharged. The carry section 73 is, for example, a conveyor, and may be a conveyance table that can move along a linear track by a ball screw or the like.

The film forming apparatus 7 is also provided with control means for controlling the operation timing of each component provided in the embedding processing section 1, the plate mounting section 2, the film forming section 3, the plate releasing section 4 and the peeling processing section 5 A control section 74 such as a computer or a microcomputer having a CPU, a ROM, a RAM, and a signal transmission circuit is accommodated. An air pressure circuit 75 for supplying a positive pressure and a negative pressure to the embedding processing section 1, the plate mounting section 2, the film forming section 3, the plate releasing section 4 and the peeling processing section 5 is accommodated. The control unit 74 also controls the electromagnetic valves in the air pressure circuit 75 to switch between negative pressure generation, negative pressure release, positive pressure generation, and positive pressure release.

(Landfill processing section)

The embedding processing section 1 responsible for the part embedding process will be described. Fig. 6 is a schematic diagram showing the configuration of the embedding processing unit 1. Fig. In the embedding processing section 1, the component placement completion sheet 66 is inserted. The embedding processing unit 1 pulls the protective sheet 61 close to the electronic part 60 while holding the electronic part 60 and presses the protective sheet 61 against the electronic part 60. [ Thus, the embedding processing unit 1 causes the electrode 602 of the electronic component 60 to penetrate the protective sheet 61, and the electrode exposed surface 601 is brought into close contact with the protective sheet 61.

As shown in Fig. 6, this embedding processing unit 1 includes a ceiling portion 11 and a placement table 12. [ The ceiling portion 11 and the placement table 12 are blocks having the internal spaces 111 and 121 together. The ceiling portion 11 and the placement table 12 are disposed opposite to each other and have flat surfaces 112 and 122 parallel to each other on the opposite sides. The both flat surfaces 112 and 122 are the same size as the component placement completion sheet 66 or wider than the component placement completion sheet 66. [ The placement table 12 is position immovable. On the other hand, the ceiling portion 11 is movable up and down with respect to the placing table 12. [ The ceiling portion 11 is at least close to the placement table 12 up to the distance of the thickness H1 of the frame 62 of the component placement completed sheet 66. [

A component placement completion sheet 66 is placed on the stage 12. The flat surface 122 of the placement table 12 serves as the placement surface of the component placement completed sheet 66. [ The flat surface 122 is made of a non-slip member having adhesion. A plurality of air holes 123 communicating with the internal space 121 are formed in the flat surface 122 of the placement table 12. The through hole formation area of the air hole 123 is a shape having the same size as the inside of the frame 62 of the component placement completion sheet 66 or a shape at least equal to the component arrangement area 615. The through-hole forming position of the air hole 123 is a position facing the region inside the frame 62 or a region facing the component arrangement region 615 when the component placement completion sheet 66 is placed on the placement table 12 Location.

An air pressure supply hole 124 is further formed in the inner space 121 of the placement table 12 at a portion different from the flat surface 122. The air pressure supply hole 124 is connected to an air pressure circuit 75 including a compressor, a negative pressure supply pipe, a static pressure supply pipe and the like outside the drawing. Therefore, a positive pressure or a negative pressure is selectively generated in the air hole 123 through the air pressure supply hole 124 and the inner space 121. The air hole 123, the air pressure supply hole 124, and the air pressure circuit 75 function as a pressure adjusting portion.

A pusher insertion hole 125 is formed in the flat surface 122 of the placement table 12 so as to penetrate the placement table 12. The pusher inserting hole 125 is formed outside the through-forming range of the air hole 123. The penetration forming position of the pusher inserting hole 125 is such that when the component placement completion sheet 66 is loaded, the pusher inserting hole 621 is closed by the frame 62 by avoiding the guide portion inserting hole 621 of the frame 62, . A pusher 13 is inserted through the pusher insertion hole 125. The pusher 13 is capable of protruding and retracting from the flat surface 122 of the placement table 12. The pusher 13 has a rigidity enough to support the component placement completion sheet 66 away from the placement table 12 when lifted from the pusher insertion hole 125, Are installed at intervals. For example, if the outer shape of the frame 62 is rectangular, the film replacement is arranged corresponding to each corner of the frame 62.

Next, a plurality of air holes 113 communicating with the inner space 111 are formed in the flat surface 112 of the ceiling portion 11 as well. The through-hole forming range of the air hole 113 is a shape having the same size as the inside of the frame 62 of the component placement completion sheet 66 or at least the same size as the component arrangement region 615, Area 615 as shown in FIG. The through-hole forming position of the air hole 113 is set so that the position where the component placement completion sheet 66 faces the inner region of the frame 62 or the position where the component placement region 615 faces the component placement region 61, .

An air pressure supply hole 114 is formed in an inner space 111 of the ceiling portion 11 at a portion different from the flat surface 112. The air pressure supply hole 114 is connected to an air pressure circuit 75 including a compressor, a negative pressure supply pipe and the like outside the drawing. Therefore, a negative pressure is generated in the air hole 113 through the air pressure supply hole 114 and the inner space 111. The air hole (113), the air pressure supply hole (114), and the air pressure circuit (75) function as a pressure reducing portion.

An O-ring (not shown) is formed on the flat surface 112 of the ceiling portion 11 so as to surround the through-forming range of the air hole 113 along the frame 62 of the component placement completed sheet 66 placed on the stage 12. [ (Not shown).

Fig. 7 shows the flow of the operation of the embedding processing unit 1. Fig. Fig. 7 is a transition diagram schematically showing the state of each step of the embedding processing section 1. Fig. First, as shown in Fig. 7 (a), the component placement completion sheet 66 is put into the embedding processing section 1. [ The ceiling portion 11 is sufficiently spaced from the placement table 12 and the pusher 13 projects its tip from the flat surface 122 of the placement table 12. [ When the component placement completion sheet 66 is inserted, the frame 62 of the component placement completion sheet 66 is aligned with the pusher 13 to support the component placement completion sheet 66 in the pusher 13.

Then, as shown in Fig. 7 (b), the pusher 13 is retracted into the pusher inserting hole 125. Thus, the component placement completion sheet 66 is lowered to the flat surface 122 of the placement table 12. Further, the ceiling portion 11 is moved toward the placement table 12. The frame 62 of the component placement completed sheet 66 is sandwiched between the flat surface 112 of the ceiling portion 11 and the flat surface 122 of the placement table 12. The height H1 from the surface of the component arrangement region 615 to the top surface of the frame 62 is the height H2 from the surface of the component arrangement region 615 to the top surface 603 of the electronic component 60, . The upper surface 603 of the electronic component 60 is less than the flat surface 112 of the ceiling portion 11 when the frame 62 is sandwiched. The electronic part 60 is enclosed in the closed space 14 surrounded by the flat surface 112 of the ceiling part 11 and the protective sheet 61 and the frame 62 and sealed by the O- The component arrangement region 615 is seized.

7 (c), a negative pressure is generated in the air hole 123 of the placement table 12, so that the protective sheet 61 And is sucked into the flat surface 122. Subsequently, as shown in Fig. 7 (d), a negative pressure is also generated in the air hole 113 of the ceiling portion 11 to reduce the pressure of the closed space 14 in which the component arrangement region 615 is trapped. It is preferable that the degree of the depressurization is the same as that at which the air holes 113 and 123 affect, and is close to a vacuum. The reason why the air hole 123 of the placement table 12 precedes and generates a negative pressure is that the protective sheet 61 is pulled into the placement table 12 to pull the protective sheet 61 The upper side air pressure is excessively high with respect to the upper side air pressure and thus the electronic component 60 is prevented from leaning on the flat surface 112 of the ceiling portion 11. [ At this stage, since the electronic component 60 is disposed on the protective sheet 61 without the electrode 602 embedded in the adhesive surface 611 of the protective sheet 61, the electrode exposed surface 601 And the adhesive surface 611, and this gap is also reduced in pressure.

7 (e), while maintaining the negative pressure on the side of the ceiling portion 11, the air hole 123 on the side of the placing table 12 is gradually changed from a negative pressure to a positive pressure, And the air hole 123 of the base 12 is switched to a positive pressure. The electronic component 60 and the protective sheet 61 are gently sucked up to the flat surface 112 of the ceiling portion 11 and gently pushed up. The electronic component 60 is pressed against the flat surface 112 of the ceiling portion 11 to be restrained. On the other hand, since the adhesive sheet 611 has flexibility, the protective sheet 61 is pulled further toward the flat surface 112 even after the electronic component 60 is padded, and is further pushed toward the flat surface 112 I will go.

The electrode 602 of the electronic component 60 is buried in the protective sheet 61, more specifically the adhesive surface 611 of the protective sheet 61 and the electrode exposed surface 601 of the electronic component 60 Is brought into close contact with the protective sheet 61. At this time, the flat surface 112 of the ceiling portion 11 includes the component arrangement region 615, and the component arrangement region 615 is planarized. In other words, the component array region 615 is not curved. As a result, the shortage of the electrode 602 or the shortage of the electrode exposed surface 601 at the end of the component array region 615 is prevented.

The contact process between the electrode exposed surface 601 and the protective sheet 61 is performed under a reduced pressure environment, and the airtight space is free or very little in the sealed space. Therefore, the possibility of bubbles entering between the electrode exposed surface 601 and the protective sheet 61 is lowered.

8 is an enlarged view of the electronic part 60 in the embedding processing unit 1. [ As shown in Fig. 8, the positive pressure generated in the placement table 12 pushes at least the component arrangement region 615 of the protective sheet 61 evenly. The flexible protective sheet 61 is further pushed toward the flat surface 112 of the ceiling portion 11 without being blocked by the electronic component 60 in each gap between the adjacent electronic components 60 do. The adhesive surface 611 of the protective sheet 61 rises until reaching the lower side of the side surface of the electronic component 60 so that the protective sheet 61 adheres to the lower side surface of the electronic component 60 as well. Therefore, it is possible to more reliably prevent the particles of the electromagnetic-shielding film 605 from entering between the electrode-exposed surface 601 and the protective sheet 61.

When the electrode 602 of the electronic component 60 is buried in the protective sheet 61 and the electrode exposed surface 601 and the lower side surface of the electronic component 60 are in close contact with the protective sheet 61, The pusher 13 is moved in the axial direction along the pusher inserting hole 125 and reappears from the flat surface 122 of the placing table 12 as shown in Fig. At the same time, the ceiling portion 11 is dropped from the placement table 12 at the speed and the constant speed of the pusher 13. Finally, as shown in Fig. 7 (g), the pusher 13 is stopped and the ceiling portion 11 is separated from the placement table 12, thereby releasing the fitting of the part embedment finished sheet 67 do. Thus, the embedding processing unit 1 completes the embedding of the electronic component 60 in the protective sheet 61.

The negative pressure on the side of the ceiling portion 11 and the positive pressure on the side of the placement table 12 are such that the close contact of the electrode exposed surface 601 of the electronic component 60 to the protective sheet 61 in Fig. 7 (g) until the ceiling portion 11 is lifted up. The negative pressure on the ceiling portion 11 side is released immediately before the ceiling portion 11 is lifted in Fig. 7 (g) It can be stably held on the protective sheet 61, which is preferable.

Thus, the ceiling portion 11 and the placement table 12 are fixed to sandwich the component placement completed sheet 66 by sandwiching the frame 62 on both sides. The ceiling portion 11, the protective sheet 61, and the frame 62 define a closed space 14 that holds the component arrangement region 615. The O-ring 115 enhances the reliability of the closed space 14 by sealing. The air hole 113 of the ceiling portion 11 is a depressurizing portion for depressurizing the closed space 14.

Then, the flat surface 122 of the placement table 12 becomes the placement surface of the component placement completed sheet 66. The air hole 123 opened in the flat surface 122 of the placement stand 12 generates a negative pressure in advance when the closed space 14 is depressurized so that the electronic component 60 is placed on the flat surface of the ceiling portion 11 The component arranging region 615 is pressed against the flat surface 112 of the ceiling portion 11 by a static pressure in conjunction with the negative pressure of the ceiling portion 11 to prevent the electronic component 60 (602).

The flat surface 112 of the ceiling portion 11 is a planarization means for flattening the component arrangement region 615 to enhance the buried effect of the electrode 602 and the adhesion effect of the electrode exposed surface 601. [ The air hole 113 opened in the flat face 112 of the ceiling portion 11 is engaged with the positive pressure of the placing stand 12 so that the component arrangement region 615 is pressed against the flat face 112 of the ceiling portion 11 Up device for pressing the electrode 602 of the electronic component 60 and sucking up the protective sheet 61 to the gap between the electronic component 60 and the static pressure of the placement table 12, And the lower side covering means is brought into close contact with the lower side of the side surface.

As described above, the embedding processing unit 1 embeds the electrode 602 of the electronic component 60 on the adhesive surface 611 of the protective sheet 61, but the electrode 602 of the electronic component 60 includes the electronic component 60 and the component arrangement region 615 And a depressurizing portion for depressurizing the space. After the pressure reduction, the electronic component 60 and the protective sheet 61 are pressed against each other. As a result, air bubbles do not enter between the electrode exposed surface 601 of the electronic component 60 and the protective sheet 61 and the adhesion between the electrode exposed surface 601 of the electronic component 60 and the protective sheet 61 61, and the particles of the electromagnetic shielding film 605 adhere to the electrode 602 can be avoided.

The embedding processing section 1 is provided with a pressure adjusting section for adjusting the pressure in the space opposite to the flat surface 112 with the flat surface 112 of the ceiling section 11 and the protective sheet 61 interposed therebetween . The flat surface 112 is located opposite to the protective sheet 61 with the electronic component 60 therebetween and faces the electronic component 60. [ Further, for example, the air hole 123, the air pressure supply hole 124, and the air pressure circuit 75 are examples of the pressure adjusting portion. The pressure adjusting section is disposed between the mounting table 12 and the protective sheet 61, that is, between the flat surface 112 and the flat surface 112 with the protective sheet 61 therebetween, The pressure in the opposite space was relatively large.

This allows the electronic component 60 and the protective sheet 61 to face the flat surface 112 and the flat surface 112 to serve as a brake to press the electronic component 60 and the protective sheet 61 against each other. The component arrangement region 615 of the protective sheet 61 is flattened so that the electrode exposed surface 601 of the electronic component 60 and the protective sheet 61 are pressed against each other in parallel. As a result, there is no room for bubbles to enter.

The thicknesses of the electronic component 60 and the protective sheet 61 are not uniform and there is a variation. The differential pressure between the pressure in the sealed space 14 and the pressure between the placement table 12 and the protective sheet 61 is such that the pressure difference between the electronic part 60 and the protective sheet 61 It is possible to securely apply a sufficient pressing force between the plurality of electrodes 602 of each of the plurality of electronic components 60 and the adhesive surface 611 of the protective sheet 61, Each electrode 602 of each electronic component 60 can be embedded in the protective sheet 61.

The embedding processing unit 1 has a placement surface located opposite to the flat surface 112 of the placement table 12, that is, opposite to the flat surface 112 with the protective sheet 61 interposed therebetween. An air hole 123 is formed in the placing table 12 to open a negative pressure in the sealed space 14 before the depression of the sealed space 14 to separate the protective sheet 61 from the flat surface 112 . This can prevent the electronic component 60 from being damaged by strongly urging the electronic component to the flat surface 112 under reduced pressure in the closed space 14.

The air hole 113 of the ceiling portion 11 and the air hole 123 of the placement table 12 that press the electronic component 60 and the protective sheet 61 against each other are used as the depressurization portion, A third air hole may be separately formed in the third air hole, and a negative pressure may be generated in the third air hole to reduce the pressure.

The air hole 123 on the placement table 12 side is replaced with the generation of a positive pressure after the airtight space 14 is depressurized and the airtightness of the protective sheet 61). As a result, the adhesive surface 611 rises along with the protective sheet 61 in the gap between the electronic components 60, and the lower surface of the electronic component 60 can also be covered with the protective sheet 61. [ Therefore, it is possible to reliably prevent the gap between the electrode exposed surface 601 and the protective sheet 61 from being generated. Even in the case of electronic components such as SOP or QFP having a thin plate-shaped electrode on the lower side, the electrode 602 is covered with the protective sheet 61 to prevent the particles of the electromagnetic shielding film 605 from adhering So that the film forming apparatus 7 can be applied.

In the present embodiment, a negative pressure is generated in the ceiling portion 11, and a positive pressure is generated in the placement table 12 opposite to the ceiling portion 11 with the protective sheet 61 therebetween. In order to press the electronic component 60 and the protective sheet 61 against each other and secondly to cover the lower side surface of the electronic component 60 by burying the adhesive surface 611 in the gap between the electronic components 60 .

However, in order to achieve pressing of the electronic component 60 and the protective sheet 61 against each other, differential pressure of this size is not essential. The differential pressure in which the electrode 602 of the electronic component 60 is embedded in the protective sheet 61 follows the flexibility of the protective sheet 61. Even if the position of the placement table 12 is not changed to the positive pressure, May be made to be smaller than the negative pressure on the side of the ceiling portion (11). That is, the relatively large value means that the negative pressure on the side of the ceiling portion 11 is positive and the negative pressure on the side of the ceiling portion 11 is equal to or higher than the atmospheric pressure It is sufficient that the differential pressure capable of embedding the electrode 602 in the protective sheet 61 can be produced by the ceiling portion 11 side and the placement stand 12 side.

The pressure difference between the negative pressure on the ceiling portion 11 side and the atmospheric pressure or the pressure exceeding the atmospheric pressure generated in the placement table 12 opposite to the ceiling portion 11 with the protective sheet 61 interposed therebetween, The plurality of electrodes 602 of each of the plurality of electronic components 60 and the surface of the adhesive surface 611 of the protective sheet 61 can be pressed against the protective sheet 61, And the electrodes 602 of the respective electronic components 60 can be embedded in the protective sheet 61. As a result,

Further, the differential pressure causes the protective sheet 61 to be pushed up. The amount of push-up of the component arrangement region 615 is determined by the flat surface 112. That is, since the amount of deformation of the protective sheet 61 is defined as the flat surface 112, the pushing force due to the differential pressure is transmitted to the protective sheet 61 ). At this time, since the protective sheet 61 located in the gap between the electronic components 60 is not in contact with the flat surface 112, there is a reduced pressure space therebetween. Therefore, the adhesive surface 611 of the gap portion rises by the differential pressure together with the protective sheet 61, so that the lower side surface of the electronic component 60 can also be covered with the protective sheet 61.

Therefore, in this embodiment, in order to cover the lower side of the electronic component 60, a negative pressure is generated in the ceiling portion 11, and a static pressure is generated in the placement table 12 so that the component arrangement region 615 is connected to the ceiling portion 11 ) On the flat surface 112 of the flat plate. However, depending on the flexibility of the protective sheet 61, even if the pressure difference between the pressure close to the vacuum on the side of the ceiling portion 11 and the pressure exceeding the atmospheric pressure or the atmospheric pressure on the placement table 12 side is not the adhesive surface 611, There may be a case where the gap between the parts 60 can be raised. Therefore, in order to cover the lower portion of the side surface of the electronic component 60, it is preferable to change the side of the placement table 12 to a static pressure, but it is not necessary to adjust the side of the placement table 12 to a constant pressure. That is, the differential pressure can be adjusted according to the flexibility of the protective sheet 61. Depending on the flexibility of the protective sheet 61, the pressure on the side of the stage 12 after the pressure reduction on the side of the ceiling portion 11 is lowered to the atmospheric pressure The negative pressure may be weakened even if it does not go away.

The electromagnetic shielding film 605 described later can be connected to the ground wiring of the electronic component 60 to improve the shielding performance. This ground wiring is a wiring for pushing out unnecessary electromagnetic waves to the outside, and is generally formed on the side surface of the electronic component 60. It is necessary to avoid obstructing the connection between the electromagnetic shielding film 605 and the ground wiring due to the protrusion of the adhesive surface 611 reaching the lower side of the electronic component 60. [

This embedding processing section 1 can independently adjust the pressures on the side of the ceiling section 11 and the side of the placement table 12 to produce a desired differential pressure so that the height of the ridge leading to the lower side surface of the electronic component 60 And can be uniformly controlled to the lower side of the side surface of the electronic component (60). That is, by sealing the gap between the lower portion of the side surface of the protective sheet 61 and the electrode 602 more securely, or when the electronic component 60 is of SOP or QFP, The ground wiring of the side surface 604 can be exposed to the ground wiring without the protective sheet 61 being affected.

The operation mechanism of the ceiling portion 11 and the operation mechanism of the pusher 43 may be a well-known mechanism, and the present invention is not limited to the mechanism of the mechanism.

For example, the ceiling portion 11 is connected to a ball screw extending from the ceiling portion 11 in the direction toward the placement table 12 and a rail guide extending from the ceiling portion 11 in the direction toward the placement table 12 have. The ceiling portion (11) moves toward the arrangement along the rails along the rotation direction of the screw shaft. The ball screw and the rail guide are extended such that the ceiling portion 11 comes close to the placement table 12 up to the distance of the thickness H1 of the frame 62 of the component placement completed sheet 66. [ It is to be noted that the ceiling portion 11 and the placing table 12 may be relatively movable so that the placing table 12 may be moved instead of moving the ceiling portion 11, Both of the placement table 12 may be moved.

The pusher 13 has a cam hole at its rear end. The cam ball follows the circumferential surface of the ovoid cam. The cam is pivotally supported by the rotary motor and is rotatable in the circumferential direction. When the rotation motor is driven to rotate the cam, the cam ball rises up the swollen portion of the cam, and the pusher 13 is pushed up, and the tip of the pusher 13 protrudes from the insertion hole.

As a fixing method of the component placement completion sheet 66, the frame 62 is sandwiched between the ceiling portion 11 and the placement stand 12 and the ceiling portion 11, the protective sheet 61, and the frame 62 The closed space 14 is defined to selectively generate both the positive pressure and the negative pressure in the air hole 123 of the placement table 12, but the present invention is not limited thereto. For example, even if one or both of the ceiling portion 11 and the placement table 12 is formed into a cup shape and the component placement completion sheet 66 is accommodated in the internal space defined by the ceiling portion 11 and the placement table 12 good. And a block body for inserting the frame 62 from both sides may be provided so as to sandwich the component placement completion sheet 66 with the block body. In this case, the height of the frame 62 does not matter. A through hole for generating a negative pressure and a through hole for generating a positive pressure may be formed on the flat surface 122 of the stage 12.

(Plate mounting portion)

Next, the plate mounting portion 2 responsible for the plate mounting process will be described. Fig. 9 is a schematic diagram showing the configuration of the plate mounting portion 2. Fig. In the plate mounting portion 2, the component-embedded sheet 67 formed in the embedding processing portion 1 and the cooling plate 63 to which the adhesive sheet 64 is adhered in advance are inserted. The plate mounting portion 2 presses the component-embedded-in sheet 67 against the cooling plate 63 and pulls the component-filled-in sheet 67 to the cooling plate 63, The part-embedded-sheet 67 is brought into close contact with the cooling plate 63.

As shown in Fig. 9, the plate mounting portion 2 includes a ceiling portion 21 and a mounting table 22. As shown in Fig. The ceiling portion 21 and the placement table 22 are disposed opposite to each other. The stage 22 is stationary. On the other hand, the ceiling portion (21) is movable up and down with respect to the placing table (22). The ceiling portion 21 is at least close to the placement table 22 up to the distance of the thickness H1 of the frame 62 of the part embedment finished sheet 67. [

The ceiling portion 21 is a block having an internal space 211 and has a flat surface 212 on a surface facing the placement stand 22. The placement table 22 has a cup shape having a bottom. The opening 221 of the placement table 22 is directed to the ceiling portion 21. [ The flat surface 212 of the ceiling portion 21 is shaped like the same size as the part embedment finished sheet 67 or wider than the part embedment finished sheet 67. [ On the other hand, the opening 221 of the placement table 22 has a coverage area equal to or smaller than the component arrangement region 615 and the inner frame region 614. The edge 222 around the opening 221 of the placement table 22 has a width equal to or greater than the width of the frame 62. [

The edge 222 supports the cooling plate 63 and the opening 221 is closed by the cooling plate 63. In this arrangement, The cooling plate 63 abuts the edge 222 on the side opposite to the side to which the adhesive sheet 64 is adhered. Further, the part-embedded-sheet 67 is placed on the cooling plate 63 so as to face the adhesive sheet 64. An air pressure supply hole 223 is formed through the bottom of the placement table 22. The air pressure supply hole 223 is connected to an air pressure circuit 75 including a compressor, a negative pressure supply pipe and the like outside the drawing. Therefore, a negative pressure is generated in the air hole 632 of the cooling plate 63 arranged by closing the opening 221. The adhesive sheet 64 may be adhered to the non-adhesive surface 612 of the protective sheet 61 before being put into the plate mounting portion 2 in advance.

Further, a pusher insertion hole 224 penetrating through the placement table 22 is formed in the edge 222 of the placement table 22. The through-hole forming position of the pusher inserting hole 224 coincides with the pusher inserting hole 631 of the cooling plate 63. On the other hand, when the part embedding complete sheet 67 is loaded, (621), and is closed by the frame (62). A pusher 23 is inserted through the pusher insertion hole 224. The pusher 23 is capable of protruding through the placement table 22, the cooling plate 63, and the adhesive sheet 64.

The pusher 23 is provided in a rigid, water-tight, and positional relationship such that it can support the part-embedded sheet 67 from the cooling plate 63 in parallel while projecting from the cooling plate 63 have. For example, if the outer shape of the frame 62 is rectangular, it is arranged as a film substitute corresponding to each corner of the frame 62. The pusher insertion holes 224 are also provided corresponding to the number and positional relationship of the pushers 23.

A large number of air holes 213 communicating with the internal space 211 are formed through the flat surface 212 of the ceiling portion 21. [ The through-hole forming range of the air hole 213 is a shape having the same size as the inside of the frame 62 of the part-embedded landing sheet 67 or a shape at least equal in size to the component arrangement area 615. The through-hole formation position of the air hole 213 is a position where the component arrangement region 615 covers (see Fig. 10 (a)) when the component-embedded sheet 67 is placed on the placement table 22.

An air pressure supply hole 214 is formed in the inner space 211 of the ceiling portion 21 at a portion different from the flat surface 212. The air pressure supply hole 214 is connected to an air pressure circuit 75 including a compressor, a static pressure supply pipe, a negative pressure supply pipe, and the like outside the drawing. Therefore, positive pressure and negative pressure are selectively generated in the air hole 213 through the air pressure supply hole 214 and the internal space 211. That is, the inner space 211, the flat surface 212, the air hole 213, the air pressure supply hole 214 and the air pressure circuit 75 of the ceiling portion 21 function as a protection sheet holding portion and a function as a static pressure portion Respectively. When the air pressure circuit 75 generates a negative pressure in the air hole 213 and the air pressure circuit 75 generates a positive pressure in the air hole 213, do.

An O-ring (not shown) is formed on the flat surface 212 of the ceiling portion 21 so as to surround the through-forming range of the air hole 213 along the frame 62 of the part- (Not shown). That is, the outer peripheral portion of the flat surface 212 of the ceiling portion 21 presses the frame 62 through the O-ring 215 and presses the outer peripheral portion of the protective sheet 61 against the cooling plate 63. That is, the ceiling portion 21 has a function as an urging portion for urging the outer peripheral portion of the protective sheet 61 against the cooling plate 63.

Fig. 10 shows the flow of operation of such a plate mounting portion 2. Fig. 10 is a transition diagram schematically showing the state of the plate mounting portion 2 in each step. First, as shown in Fig. 10 (a), the ceiling portion 21 is first separated from the placement table 22. A cooling plate 63 is disposed in advance on the placement table 22. Further, the pusher 23 is pierced by the cooling plate 63 and the adhesive sheet 64 and is projected toward the ceiling portion 21. [ In this state, the frame 62 of the part-embedded-in-sheet 67 is aligned with the pusher 23, and the pusher 23 supports the part-embedded sheet 67. The ceiling portion 21 is lowered toward the pusher 23 and the frame 62 of the part-embedded sheet 67 is sandwiched by the ceiling portion 21 and the pusher 23.

The height H1 from the surface of the component arrangement region 615 to the top surface of the frame 62 is equal to the height from the surface of the component arrangement region 615 to the top surface 603 of the electronic component 60 H2. The upper surface 603 of the electronic component 60 is less than the flat surface 212 of the ceiling portion 21 when the frame 62 is sandwiched. Therefore, at least the part arrangement region 615 is confined in the closed space 24a partitioned by the ceiling portion 21, the protective sheet 61 and the frame 62, and sealed by the O-ring 215. [

A negative pressure is generated on the flat surface 212 of the ceiling portion 21 when the component arrangement region 615 is enclosed in the closed space 24a. The electronic component 60 is sucked into the flat surface 212. The part embedded land 67 is distorted in the inner frame area 614 so that the whole area of the part arrangement area 615 is sucked to the flat surface 212 while being flattened. Therefore, the component array region 615 is not curved and the buried electrode 602 is not separated from the protective sheet 61. [ The electronic component 60 may be gradually depressurized to generate a negative pressure on the flat surface 212 of the ceiling portion 21 so as to prevent the electronic component 60 from rushing toward the flat surface 212 momentarily. The magnitude of the negative pressure at this time is set in advance in the control unit 74. It is preferable that the pressure is close to vacuum (0 atm) in consideration of the relationship with the decompression of the closed space 24b described later.

Then, as shown in Fig. 10 (b), the pusher 23 and the ceiling portion 21 are lowered at the constant speed toward the placing table 22. Then, the area of the frame 62 of the part-embedded-sheet 67 is brought into contact with the adhesive sheet 64 on the cooling plate 63. The area of the frame 62 is adhered to the adhesive sheet 64 by moving the ceiling part 21 toward the placement table 22 and pressing it. The negative pressure of the ceiling portion 21 is maintained at the time when the area of the frame 62 of the above-mentioned parts embedding complete sheet 67 is brought into contact with the pressure sensitive adhesive sheet 64 on the cooling plate 63, 67 are pulled by the flat surface 212 of the ceiling portion 21, the component arrangement region 615 is not in contact with the adhesive sheet 64 (spaced apart).

Here, when the negative pressure is not generated in the ceiling portion 21, the part-embedded-sheet 67 comes into contact with the adhesive sheet 64 under the presence of air. Thereby, air bubbles may enter between the part-embedded-sheet 67 and the adhesive sheet 64. [ When bubbles enter, the heat transfer area to the cooling plate 63 decreases, and the heat radiation effect of the electronic component 60 at the time of film formation is lowered. However, in the plate mounting portion 2, in the presence of air, since the part-embedded-sheet 67 is raised in the direction of detaching from the adhesive sheet 64, bubbles are prevented from entering.

The cooling plate 63 and the frame 62 when the frame 62 is brought into close contact with or pressed against the pressure sensitive adhesive sheet 64 through the protective sheet 61, The non-adhesive surface 612 and the adhesive sheet 64 side of the cooling plate 63 are confined in the closed space 24b. When the closed space 24b is formed, a negative pressure is also generated on the stage 22 while the negative pressure of the ceiling portion 21 is maintained, as shown in Fig. 10 (c). In other words, the enclosed space 24b is decompressed under the condition that the outer peripheral portion (outer mold region 613) of the protective sheet 61 is pressed by the ceiling portion 21. [ A sealed space 24b between the cooling plate 63 provided with the adhesive sheet 64 and the protective sheet 61 is provided through the air hole 632 of the cooling plate 63 and the air hole 632 of the adhesive sheet 64 ) Is decompressed. The negative pressure generated in the placement table 22 at this time is a negative pressure which is slightly lower than the negative pressure generated in the ceiling portion 21 and is a size that can hold the suction of the electronic component 60 to the ceiling portion 21 . The negative pressure is set in advance in the control unit 74.

When the pressure reduction of the closed space 24b between the cooling plate 63 provided with the adhesive sheet 64 and the protective sheet 61 to a predetermined negative pressure is completed, as shown in Fig. 10 (d) 22, the negative pressure of the ceiling portion 21 is gradually changed to a constant pressure. In other words, the holding of the protective sheet 61 by the ceiling portion 21 is released under the condition that the reduced pressure of the sealed space 24b is maintained. The component-embedded sheet 67 is slowly sucked down toward the adhesive sheet 64 and pushed down so that the component-embedded sheet 67 is pressed against the adhesive sheet 64 adhered to the cooling plate 63 do. Then, the part-embedded-sheet 67 is mounted on the cooling plate 63 through the adhesive sheet 64.

When the negative pressure on the placement table 22 side and the negative pressure on the ceiling portion 21 side are the same or substantially equal to each other, the protective sheet 61 elastically shrinks and the protective sheet 61 contacts the adhesive sheet 64 . Therefore, the negative pressure on the side of the placement table 22 may be equal to or substantially equal to the negative pressure on the side of the ceiling 21, and then the negative pressure on the ceiling 21 side may be gradually changed to a constant pressure.

Finally, as shown in Fig. 10 (e), by moving the ceiling portion 21 away from the placement table 22, the part-embedded sheet 67, the adhesive sheet 64, and the cooling plate 63 Release the insertion of the next overlapping. This completes the production of the component mounting plate 68 composed of the electronic component 60, the protective sheet 61, the adhesive sheet 64, and the cooling plate 63. The positive pressure generated in the ceiling portion 21 and the negative pressure generated in the placement table 22 can be released while the ceiling portion 21 is separated from the placement table 22.

That is, the ceiling portion 21, the pusher 23, and the placing table 22 constitute a driving portion for approaching the part-embedded sheet 67 and the cooling plate 63. The ceiling portion 21 and the placement table 22 are fixed to each other to sandwich the part-embedded sheet 67 and the cooling plate 63 and also to the pressing portion for pressing the frame 62 and the cooling plate 63 do. The air pressure supply hole 223 of the placing table 22 is a pressure reducing portion for reducing the airtight space 24b between the part-embedded sheet 67 and the cooling plate 63. [ The air hole 213 of the ceiling portion 21 is a depressurizing portion for depressurizing the enclosed space 24a between the flat surface 212 of the ceiling portion 21 and the part embedding complete sheet 67. [

The flat surface 212 of the ceiling portion 21 holds the part embedment finished sheet 67 by generating a negative pressure in advance of the depressurization between the part embedment finished sheet 67 and the cooling plate 63, The part-embedded sheet 67 is cooled by a static pressure as a static pressure portion in addition to the pulling by the negative pressure of the placing table 22 and the isolating means for preventing air bubbles from entering between the sheet 67 and the cooling plate 63 And is pressed against the plate 63. The placement stand 22 is a pulling-out means for urging the part-embedded sheet 67 against the cooling plate 63 by the positive pressure of the ceiling portion 21 and a negative pressure.

The plate mounting portion 2 adheres the protective sheet 61 in which the electrode 602 of the electronic component 60 is embedded to the cooling plate 63. [ The plate mounting portion 2 has a ceiling portion 21 as an urging portion for urging the outer peripheral portion such as the frame 62 of the protective sheet 61 against the cooling plate 63 and also has a component arrangement region 615, (63). The plate mounting portion 2 also presses the protective sheet 61 and the cooling plate 63 together through the adhesive sheet 64 under a reduced pressure by the pressure sensitive portion. As a result, bubbles can be brought into close contact with each other without entering the space between the protective sheet 61 and the cooling plate 63, and the heat transfer area to the cooling plate 63 can be sufficiently secured.

The plate mounting portion 2 sucks up the protective sheet 61 by a negative pressure on the side opposite to the cooling plate 63 with the flat surface 212 of the ceiling portion 21, that is, the protective sheet 61 interposed therebetween And an air hole 213 for separating the cooling plate 63 and the protective sheet 61 from each other. The flat surface 212 having the air holes 213 is a protective sheet holding portion which is provided at a position where the pressing portion is brought into contact with the cooling plate 63 at the outer peripheral portion of the protective sheet 61, 60 are arranged and the cooling plate 63 are spaced apart from each other. Then, the negative pressure is maintained until the reduced pressure between the parts-embedded sheet 67 and the cooling plate 63 due to the depressurizing portion is depressurized, and the depressurized state is released. This makes it possible to prevent the protective sheet 61 and the cooling plate 63 from adhering to each other in a state where the pressure reduction is incomplete and further reduce the possibility that the air bubbles enter between the protective sheet 61 and the cooling plate 63, The heat transfer area to the cooling plate 63 can be sufficiently secured.

The air hole 213 opened in the flat surface 212 of the ceiling portion 21 is formed in such a manner that the pusher 23 is lowered so that the ceiling portion 21 is inserted through the frame 62 of the part- Between the cooling plate 63 provided with the adhesive sheet 64 and the protective sheet 61 before or after the part-embedded sheet 67 and the cooling plate 63 come close to each other, The negative pressure was generated before the space was divided. This prevents the protective sheet 61 from adhering to the cooling plate 63 before the pusher 23 with the protective sheet 61 (partly embedded sheet 67) can do.

Further, the plate mounting portion 2 has a flat surface 212 of the ceiling portion 21. The flat surface 212 is located opposite to the cooling plate 63 with the protective sheet 61 interposed therebetween and faces the electronic component 60. The air hole 213 separating the cooling plate 63 from the protective sheet 61 until the end of the decompression between the parts-embedded sheet 67 and the cooling plate 63 is opened to the flat surface 212 did. As a result, the protective sheet 61 can be flattened without bending and deflected by the pressure difference between the front and back sides of the protective sheet 61 during the depressurization, and the electronic part 60 can be protected The sheet 61 can be prevented from being peeled off.

The air hole 213 on the side of the ceiling portion 21 is a static pressure portion which changes from a negative pressure to a positive pressure after the pressure between the parts-embedded sheet 67 and the cooling plate 63 reaches a predetermined set value, And the protective sheet 61 was pressed toward the cooling plate 63. That is, the air hole 213 is formed in the protective sheet 61 as a pressure-maintaining portion for isolating the protective sheet 61 from the cooling plate 63, a depressurizing portion for depressurizing the enclosed space 24a, And the cooling plate (63). However, the functions of the isolation, depressurization, and close-contact means may be accomplished by air holes formed in separate members.

For example, an air hole 632 is formed in the cooling plate 63 as in this embodiment. The plate mounting portion 2 has a placement table 22 for placing a cooling plate 63 and generating a negative pressure. The protective sheet 61 may be pulled to the cooling plate 63 through the arrangement base 22 in which the cooling plate 63 is disposed and the air hole 632 in the cooling plate 63. [

The operation mechanism of the ceiling portion 21 and the operation mechanism of the pusher may employ a well-known mechanism, and the present invention is not limited to the mechanism of the mechanism.

For example, a ball screw, which extends in the direction from the ceiling portion 21 toward the placement table 22, and a rail guide extending from the ceiling portion 21 in the direction toward the placement table 22 are connected to the ceiling portion 21 have. In this case, the ceiling portion 21 moves toward the placement table 22 along the rails along the rotational direction of the screw shaft. The ball screw and the rail guide are extended such that the ceiling portion 21 comes close to the placement table 22 up to the distance of the thickness H1 of the frame 62 of the component placement completed sheet 66. [

The rear end of the pusher 23 is a cam hole. The cam ball follows the circumferential surface of the oval cam. The cam is pivotally supported by the rotary motor and is rotatable in the circumferential direction. When the rotation motor is driven to rotate the cam, the cam ball rises up the bulge portion of the cam, and the pusher 23 is pushed up.

The method of dividing the closed space 24a and the closed space 24b is not limited to the one in which the part-embedded sheet 67 and the cooling plate 63 are formed as one element of the partitioning means, As shown in Fig. For example, one or both of the ceiling portion 21 and the placing table 22 may be formed into a cup shape, and the ceiling portion 21 and the placing table 22 may be divided into a compartment And the top and bottom of the part-embedded sheet 67 may be partitioned by the ceiling part 21 and the placement table 22. [ However, in this case, it is preferable that the ceiling portion 21 is provided with a side wall extended toward the placement table 22 so as to surround the flat surface 212 with the air hole 213 opened. The sidewalls are in close contact with the flat surface of the placement table 22 to define one closed space. The O-ring 215 is provided on the end face of the side wall.

(Film forming unit)

Next, the film forming section 3 responsible for the film forming process will be described. 11 is a schematic diagram showing the configuration of the film forming unit 3. The film forming unit 3 forms an electromagnetic wave shielding film 605 on individual electronic components 60 on the component mounting plate 68 by sputtering. As shown in Fig. 11, this film-forming unit 3 has a chamber 31 and a load lock chamber 32. [ The chamber 31 is a cylindrical vacuum chamber which is radially extended in the radial direction from the axial direction. The interior of the chamber 31 is partitioned into a plurality of fan-shaped compartments by short-circuiting portions 33 extending along the radial direction. A processing position 311 and a film formation position 312 are assigned to some of the sector-like sectors.

The shorting portion 33 extends from the ceiling surface of the chamber 31 toward the bottom surface, but is short of the bottom surface. A rotary table 34 is provided in the space on the bottom surface side where the shorting portion 33 is not provided. The rotary table 34 has a disc shape coaxial with the chamber 31 and rotates in the circumferential direction. The component placement plate 68 inserted into the chamber 31 from the load lock chamber 32 is disposed on the rotary table 34 and moves along the circumference trajectory to move the processing position 311 and the film formation position 312, .

In order to maintain the position of the component mounting plate 68 with respect to the rotary table 34, the rotary table 34 is provided with a component mounting plate (e.g., a groove, a hole, a projection, a jig, a holder, a mechanical chuck, 68 are provided on the left and right sides.

The processing position 311 is provided with a surface treatment section 35. This surface treatment section 35 introduces a process gas such as argon gas and converts the process gas into plasma by application of a high frequency voltage to generate electrons, ions, radicals and the like. For example, the surface treatment section 35 is a cylindrical electrode that is opened to the rotary table 34 side, and a high frequency voltage is applied by an RF power source.

A target 361 constituting the sputter source 36 is provided in the deposition position 312 and a sputter gas, which is an inert gas such as argon gas, is introduced. The sputter source 36 applies electric power to the target 361 to convert the sputter gas into plasma, and collide the generated ions with the target to strike the particles. The target 361 is made of the material of the electromagnetic wave shield film 605. That is, the particles of the electromagnetic shielding film 605 are bounced out from the target 361, and the particles of the electromagnetic shielding film 605, which are pounded out, are deposited on the electronic part 60 on the rotary table 34.

Two film forming positions 312 are provided, for example. The target material of each of the deposition positions 312 may be the same material or different materials may be used to form a laminated electromagnetic shielding film 605. [ As a power source for applying power to the sputter source 36 of each of the deposition positions 312, a well-known one such as a DC power source, a DC pulse power source, and an RF power source can be applied. The power source for applying power to the sputter source 36 may be provided for each sputter source 36, or a common power source may be used by switching the power source.

In this film formation processing section 3, the surface of the electronic component 60 is cleaned and roughened by etching or ashing in the processing position 311, so that the adhesion of the electromagnetic shielding film 605 to the electronic component 60 is improved The conductive shield film 605 is formed on the electronic component 60 by depositing particles of the target 361 on the electronic component 60 at the deposition position 312. [ The electrode 602 is buried in the protective sheet 61 and the electrode exposed surface 601 is in close contact with the protective sheet 61. This prevents adhesion of the particles of the electromagnetic shielding film 605 to the electrode 602, And the particles of the electromagnetic-shielding film 605 are prevented from entering between the electrode-exposed surface 601 and the protective sheet 61. Moreover, the heat of the electronic component 60 is transferred to the cooling plate 63, and the excessive heat storage of the electronic component 60 is suppressed.

The film forming unit 3 is formed on the electronic component 60 by the sputtering method, but the film forming method is not limited to this. For example, the film forming unit 3 may be formed by depositing the electromagnetic shielding film 605 on the electronic component 60 by vapor deposition, spray coating, coating, or the like.

(Plate release portion)

Next, the plate releasing portion 4 responsible for the plate releasing process will be described. Fig. 12 is a schematic diagram showing the configuration of the plate releasing section 4. Fig. After the electromagnetic shielding film 605 is formed on the plate releasing portion 4, the component mounting plate 68 is inserted. The plate releasing portion 4 is the first step for obtaining the individual electronic components 60, and the component buried sheet 67 is pulled off from the cooling plate 63.

As shown in Fig. 12, the plate releasing portion 4 includes a ceiling portion 41 and a placing stand 42. [0050] As shown in Fig. The ceiling portion 41 and the placement table 42 are disposed opposite to each other. The placement stand 42 is position immovable. On the other hand, the ceiling portion 41 is movable up and down with respect to the stage 42. The ceiling portion 41 comes close to the placement table 42 at least up to the distance of the thickness H1 of the frame 62 of the component placement plate 68. [

The ceiling portion 41 is a block having an internal space 411 and has a flat surface 412 on a surface facing the placement stand 42. The placement stand 42 has a cup shape having a bottom, and the opening 421 is directed to the ceiling portion 41. [ The flat surface 412 of the ceiling portion 41 is the same size as the component mounting plate 68 or wider than the component mounting plate 68. On the other hand, the opening 421 of the placement table 42 has a coverage area equal to or smaller than the component arrangement region 615 and the inner frame region 614. The edge 422 around the opening 421 of the placement table 42 has a width equal to or greater than the width of the frame 62. [

The edge 422 supports the component placement plate 68 and the opening 421 is closed by the component placement plate 68. In this case, And the side of the cooling plate 63 abuts the edge 422. An air pressure supply hole 423 is formed through the bottom of the placement stand 42. The air pressure supply hole 423 is connected to an air pressure circuit 75 including a compressor, a static pressure supply pipe and the like outside the drawing. For this reason, a positive pressure is generated in the air holes 632 of the component placement plate 68 arranged by closing the opening 421.

A pusher insertion hole 424 penetrating through the placement table 42 is formed at an edge 422 of the placement table 42. The through-hole forming position of the pusher inserting hole 424 coincides with the pusher inserting hole 631 of the cooling plate 63. On the other hand, when the component placing plate 68 is loaded, 621, and is closed by the frame 62. A pusher 43 is inserted through the pusher inserting hole 424. The pusher 43 moves in the axial direction so as to project the position roll end higher than the frame 62 of the component placement plate 68 placed on the placement stand 42. [

The pusher 43 peels the partly embedded sheet 67 from the cooling plate 63 against the adhesive force between the outer frame area 613 and the adhesive sheet 64 to cool the partly embedded sheet 67 Water, and positional enough to be able to support the part-embedded-sheet 67 in a parallel manner. For example, if the outer shape of the frame 62 is rectangular, it is arranged as a film substitute corresponding to each corner of the frame 62. The pusher insertion holes 424 are also provided corresponding to the number and positional relationship of the pushers 43.

Further, a pair of sandwiching blocks 44 are disposed on both sides of the stage 42. In the nip block 44, only the cooling plate 63 among the component mounting plates 68 placed on the placement table 42 is inserted. That is, the pair of nip blocks 44 are disposed at the same height as the cooling plate 63 disposed on the placement table 42, and have the same thickness as the cooling plate 63. [ Further, the nip block 44 is movable in contact with and separable from the cooling plate 63. However, the nip block 44 is floating in the direction in which the ceiling portion 41 and the placement table 42 are arranged.

Subsequently, a large number of air holes 413 communicating with the inner space 411 are formed through the flat surface 412 of the ceiling portion 41. [ The through-hole formation area of the air hole 413 is a shape having the same size as the inside of the frame 62 of the protective sheet 61 or a shape at least equal in size to the component arrangement area 615. The through hole formation position of the air hole 413 is a position where the component placement area 615 covers when the component placement plate 68 is placed on the placement table 42.

An air pressure supply hole 414 is formed in an inner space 411 of the ceiling portion 41 at a portion different from the flat surface 412. The air pressure supply hole 414 is connected to an air pressure circuit 75 including a compressor, a negative pressure supply pipe and the like outside the drawing. Therefore, a negative pressure is generated in the air hole 413 through the air pressure supply hole 414 and the inner space 411.

An O-ring (not shown) surrounding the through-forming range of the air hole 413 is formed on the flat surface 412 of the ceiling portion 41 along the frame 62 of the component placing plate 68 placed on the placing stand 42 415 are installed. The peripheral edge portion of the flat surface 412 of the ceiling portion 41 opposite to the frame 62 is pressed against a portion of the protective sheet 61 that deviates from the component arrangement region 615 in which the electronic component 60 is arranged It functions as a fixed part. This fixing portion presses the protective sheet 61 firmly in the entire circumference of the peripheral edge portion opposed to the frame 62. That is, the frame 62 is pressed firmly in the entire region. However, it is not necessarily pressed firmly in the whole region, There may be a portion which is not pressed firmly.

Fig. 13 shows the flow of the operation of such a plate releasing section 4. Fig. 13 is a transition diagram schematically showing the state of the plate releasing section 4 in each step. First, as shown in Fig. 13 (a), the ceiling portion 41 is separated from the placement table 42 and the pusher 43 is buried in the pusher insertion hole 424 of the placement table 42. Fig. Then, the component placement plate 68 is placed on the placement table 42. When the component mounting plate 68 is disposed, the cooling plate 63 is fixed to the holding block 44.

13 (b), the ceiling portion 41 is lowered toward the placement stand 42, and the flat surface 412 of the ceiling portion 41 is pressed against the frame 62 of the component placement plate 68, That is, the fixing portion. The height H1 from the surface of the component arrangement region 615 to the top surface of the frame 62 is equal to the height from the surface of the component arrangement region 615 to the top surface 603 of the electronic component 60 H2. The upper surface 603 of the electronic component 60 is below the flat surface 412 of the ceiling portion 41 when the frame 62 is sandwiched therebetween. Therefore, at least the part arrangement region 615 is confined in the closed space 45 partitioned by the ceiling portion 41, the protective sheet 61 and the frame 62 and sealed with the O-ring 415.

A negative pressure is generated in the ceiling portion 41 and a positive pressure is generated in the placement table 42 as shown in Fig. 13 (c) when the component arrangement region 615 is held in the closed space 45. [ The force to be pulled up by the flat surface 412 of the ceiling portion 41 and the force to be pulled out from the placement stand 42 and to the flat surface 412 of the ceiling portion 41 are formed in the component arrangement region 615 inside the frame 62 A force of pushing up in the direction of the action is applied. A sufficient force is exerted on the component arranging region 615 to exfoliate the component arranging region 615 from the cooling plate 63 by the sucking force and the pushing up force, 63). At this time, the negative pressure of the ceiling portion 41 and the positive pressure of the placement table 42 are set in advance in the control unit 74.

Since the protective sheet 61 is flat without distortion at the time when the component array region 615 is peeled off, the momentum of the component array region 615 toward the flat surface 412 of the ceiling portion 41 is small, 60 are peeled off from the protective sheet 61 or the electronic component 60 is protruded from the protective sheet 61 is prevented. The electronic component 60 is restrained by the flat surface 412 because the flat surface 412 of the ceiling portion 41 is standing by even if the component arrangement region 615 is strongly peeled off. The risk of peeling off the protective sheet 61 or coming off the protective sheet 61 is reduced.

In order to further improve the effect of reducing the possibility of peeling or peeling off of the electronic component 60 from the protective sheet 61, it is preferable that the electronic component 60 is removed from the cooling plate 63 before the protective sheet 61 is peeled, The distance between the upper surface 603 and the flat surface 412 is preferably as small as possible. The gap between the upper surface 603 and the flat surface 412 of the electronic component 60 may be set to the minimum necessary interval for peeling the protective sheet 61 from the cooling plate 63. [

A positive pressure is applied to the plurality of air holes 632 of the cooling plate 63 so as to gradually increase the air hole 632 to which the positive pressure acts, for example, from one end of the cooling plate 63 toward the other end The air hole 632 in which the working air holes 632 are increased or the range of the air holes 632 in which the positive pressure acts stepwise from the air hole 632 located on the center side to the outer side is enlarged, 421 may be divided into a plurality of spaces so that a plurality of systems generating static pressure may be provided. By doing so, it is possible to prevent the component arrangement region 615 from being peeled at once from the cooling plate 63, and to prevent the electronic component 60 from pounding smoothly on the flat surface 412 of the ceiling portion 41 .

When the component array region 615 is peeled off, the electronic component 60 abuts against the flat surface 412 of the ceiling portion 41 so that only the inner frame region 614 is bent, Area 615 maintains a flat shape. In other words, if the flat surface 412 of the ceiling portion 41 is not present, the protective sheet 61 is bent so as to curl with the air contained therein. Then, although the electronic component 60 may be peeled off from the protective sheet 61, peeling of the electronic component 60 is suppressed because the component arrangement region 615 maintains a flat shape.

13 (d), the pusher 43 is inserted into the pusher insertion hole 424 of the placement stand 42 and the cooling plate 63, as shown in Fig. 13 (d) Through the pusher insertion hole 631 of the adhesive sheet 64 and the pusher insertion hole 631 of the adhesive sheet 64 through the protective sheet 61. Further, the pusher 43 is further advanced, and at the same time, the ceiling portion 41 is released from the placement stand 42 at a constant speed with the pusher 43. The outer frame region 613 to which the frame 62 is adhered is also peeled off from the cooling plate 63 and the protective sheet 61 is peeled off from the cooling plate 63 because the cooling plate 63 is held by the pinching block 44, And the whole is peeled off from the cooling plate 63.

At this time, the static pressure of the placement table 42 and the negative pressure of the ceiling portion 41 are maintained. Therefore, the situation in which the component arrangement region 615 is drained downward and reattached to the cooling plate 63 due to its own weight is suppressed. Further, since the static pressure of the placement table 42 is maintained, the separation of the outer frame area 613 to which the frame 62 is adhered from the cooling plate 63 is also assisted.

Finally, as shown in Fig. 13 (e), the pusher 43 is stopped and the ceiling portion 41 is further moved away from the placement table 42, whereby the nipping with respect to the part-embedded- And the peeling of the protective sheet 61 from the cooling plate 63 is completed. In addition, the positive pressure of the placement stand 42 and the negative pressure of the ceiling portion 41 can be released therebetween.

That is, the ceiling portion 41 is a fixing portion that firmly presses the frame 62 located off the component arrangement region 615. The air pressure supply hole 423 of the placement stand 42 serves as a static pressure generating hole and presses the component arrangement region 615 through the air hole 632 of the cooling plate 63 to form the component arrangement region 615 Is peeled off from the cooling plate 63 before the frame 62. As shown in Fig. The air hole 413 of the ceiling portion 41 serves as a negative pressure generating hole and serves as a pulling-out means for pulling out the component arrangement region 615 and assisting the separation from the cooling plate 63.

The flat surface 412 of the ceiling portion 41 serves as a papermaking means for suppressing peeling or dropping of the electronic component 60 from the protective sheet 61 when the component arrangement region 615 is peeled off, And serves as a planarization means for preventing the protective sheet 61 from being flattened to prevent the electronic component 60 from being peeled off from the protective sheet 61. [ The pusher 43 serves as lifting means for peeling off the frame 62 from the cooling plate 63 after the component arrangement region 615 is peeled off.

As described above, the plate releasing section 4 removes the cooling plate 63 after the film forming process. The plate releasing portion 4 is provided with a mounting table 42 having a static pressure generating hole as an example of the air pressure supply hole 423 and a fixing portion as an example of the ceiling portion 41. The static pressure generating hole faces the cooling plate 63, and generates a static pressure. The fixing part presses the portion of the protective sheet 61 deviating from the component arrangement area 615 such as the frame 62 firmly while the positive pressure of the placement table 42 presses the component arrangement area 615, After the arrangement area 615 has moved away from the cooling plate 63, it is released from the firm pressing.

Thus, when the component array region 615 is peeled off, the protective sheet 61 remains flat, and therefore, the situation in which the component array region 615 is sprung up due to the reaction in which the protective sheet 61 returns to the flat state Can be avoided. Therefore, the electronic component 60 is prevented from being peeled off from the protective sheet 61 and is prevented from being dropped.

More specifically, when a positive pressure is supplied from a plurality of air holes 632 formed in a range corresponding to the inner mold area 614 and the component arrangement area 615 in the cooling plate 63, (61) starts to peel off from the cooling plate (63). The peeled portion of the protective sheet 61 thus formed is gradually expanded and widened outwardly from the portion where the peeled portion is started, by the constant pressure supplied continuously. Finally, the peeling portion reaches the boundary between the outer frame region 613 and the inner frame region 614, which is the inner peripheral edge of the frame 62 which is tightly pressed by the fixing portion, And the inner mold region 614 completely separate from the cooling plate 63. [ The boundary between the outer frame region 613 and the inner frame region 614 at which the peeling section of the protective sheet 61 finally reaches reaches the boundary between the outer frame region 613 and the inner frame region 614 through the frame 62 So that even if the parts array region 615 and the inner mold region 614 are peeled off, the protective sheet 61 is prevented from bouncing strongly.

Moreover, since the outer frame region 613 is pressed firmly through the frame 62 by the flat surface 412 as the fixing portion, it is possible to prevent the static pressure from leaking out between the protective sheet 61 and the cooling plate 63 The entire part array region 615 can be reliably and stably peeled off. As a result, the electronic component 60 can be prevented from falling off the protective sheet 61 and falling off.

The plate releasing portion 4 is provided on the flat surface 41 of the ceiling portion 41 spaced apart from the protective sheet 61 so as to be opposed to the cooling plate 63 with the protective sheet 61 therebetween, 412). This flat surface 412 pressed the bulge of the component array region 615 firmly while the component array region 615 was being pressed. As a result, the component array region 615 is planarized, and it is possible to more reliably prevent the electronic component 60 from being peeled off. The flat surface 412 also restrains the electronic component 60 from peeling off from the protective sheet 61 because the electronic component 60 is detached even if the component arrangement region 615 bounces .

The plate releasing portion 4 has a negative pressure generating hole in which a negative pressure is generated so as to face the protective sheet 61. As an example, an air hole 413 for generating a negative pressure is formed on the flat surface 412 of the ceiling portion 41. This air hole 413 sucks the protective sheet 61 together with the pressing of the component arrangement region 615 by the air hole 632. Therefore, the protective sheet 61 can be removed from the cooling plate 63 by urging against the pressing force against the component array region 615, making it difficult to cause a peeling mistake.

Further, the plate releasing portion 4 is provided with the pusher 43. The pusher 43 moves from the cooling plate 63 to the position where the component arrangement region 615 moves away from the cooling plate 63 and then advances inside the cooling plate 63 to press the firmly pressed portion such as the frame 62 from the cooling plate 63 Push up in the falling direction. Thus, after peeling off the component array region 615, the entire protective sheet 61 can be peeled off. The fixing portion, which is an example of the ceiling portion 41, may be spaced apart from the protective sheet 61 along with the advance of the pusher 43 when tightly releasing the pressing.

The operation mechanism of the ceiling portion 41, the operation mechanism of the nip block 44, and the operation mechanism of the pusher 43 may employ a well-known mechanism, and the present invention is not limited to the mechanism of the mechanism.

For example, a ball screw, which extends from the ceiling portion 41 in the direction toward the placement table 42, and a rail guide extending from the ceiling portion 41 in the direction toward the placement table 42 are connected to the ceiling portion 41 have. In this case, the ceiling portion 41 moves toward the placing table 42 along the rail along the rotating direction of the screw shaft. The ball screw and the rail guide are extended such that the ceiling portion 41 is close to the placement table 42 to the distance of the thickness H1 of the frame 62 of the component placement completed sheet 66. [

Further, on the outer side of the nip block 44, the peripheral surfaces of the ovoid cams are individually abutted against the pair of nip blocks 44. [ The cam is pivotally supported by the rotary motor and is rotatable in the circumferential direction. When the rotation motor is driven and the cam rotates to contact the bulging portion of the cam with the nip block 44, the nip block 44 is pushed toward the cooling plate 63 to sandwich the cooling plate 63 .

The rear end of the pusher 43 is a cam hole. The cam ball follows the circumferential surface of the oval cam. The cam is pivotally supported by the rotary motor and is rotatable in the circumferential direction. When the rotation motor is driven to rotate the cam, the cam ball rises up the bulge portion of the cam, and the pusher 43 is pushed up.

The plate releasing portion 4 also generates a static pressure on the placing table 42 to thereby peel the protective sheet 61 from the cooling plate 63. [ The flat surface 412 of the ceiling portion 41 is an additional function of flattening the peeled protective sheet 61 and the air hole 413 opened in the flat surface 412 of the ceiling portion 41 is also a function Is an additional function for assisting the pressurization by the pressurizing member (42). Therefore, as shown in Fig. 14, the ceiling portion 41 has an angular tubular shape in which the opening edge is brought into contact with the frame 62, and the flat surface 412 may be omitted. 15, the air hole 413 may be omitted from the flat surface 412 of the ceiling portion 41. [

(Peeling treatment section)

Finally, the peeling processor 5 responsible for the component peeling process will be described. Fig. 16 is a schematic diagram showing the configuration of the peeling treatment section 5. Fig. The partly embedded sheet 67 on which the cooling plate 63 has been removed via the plate releasing section 4 is inserted into the peeling treatment section 5 and the individual electronic parts 60 ). Here, when the peeling treatment section 5 is separated from the film forming apparatus 7, it may be called a peeling treatment apparatus.

16, the peeling processor 5 includes a stage 51 on which a part-embedded sheet 67 is placed, a chuck 52 that grips the protective sheet 61 and moves continuously, A guide portion 53 for hooking the end portion of the protective sheet 61 to create a starting point for grasping the protective sheet 61 by the chuck 52, a sheet stopper 54 for making the peeling starting point of the protective sheet, And a component stopper 55 for preventing the protrusion 60 from rising.

The placement table 51 has a flat surface 511 on which the part-embedded-sheet 67 is disposed. The part-embedded-in-sheet 67 is brought into contact with the upper surface 603 of the electronic component 60 by bringing the electronic component 60 toward the flat surface 511 and bringing the protective sheet 61 up Respectively. The flat surface 511 is made of a non-slip member having adhesive force, so that the stationary property of the electronic component 60 is improved. The outer peripheral region of the flat surface 511 has a height H1 from the surface of the component arrangement region 615 to the end surface of the frame 62 so that the frame 62 is inserted, The electronic component 60 is further lowered to a depth corresponding to a height obtained by subtracting the height H2 from the surface of the electronic component 60 to the top surface 603 of the electronic component 60. As the protective sheet 61 remains flat, And is disposed on the flat surface 511.

The placement stand 51 is a block having an internal space 512. [ On the flat surface 511 of the placement table 51, a plurality of air holes 513 are formed in a region facing the component arrangement region 615. The air hole 513 communicates with the internal space 512 of the placement table 51. An air pressure supply hole 514 is formed in the inner space 512 of the placement stand 51 at a portion different from the flat surface 511. The air pressure supply hole 514 is connected to an air pressure circuit 75 including a compressor, a negative pressure supply pipe and the like outside the drawing. Therefore, a negative pressure is generated in the air hole 513 through the air pressure supply hole 514 and the inner space 512.

The chuck 52 is a pair of blocks opposed to the holding surface. The pair of blocks are contactably separable. The chuck 52 is supported on a moving device capable of moving in the horizontal direction and the vertical direction and is supported on the flat surface 511 along the protective sheet 61 placed on the flat surface 511 of the placement table 51 And is continuously moved at an angle of attack of 45 degrees. That is, the chuck 52 moves away from the placement table 51 while moving the flat surface 511 of the placement table 51 end-to-end. Continuous movement does not include stopping on the way, preferably moving at a constant speed. The movement range of the chuck 52 is from the end of the protective sheet 61 at the beginning of the grip to the opposite end of the end.

The sheet stopper 54 has a cylindrical shape of a longitudinal axis transverse to one side of the protective sheet 61, and is a roller capable of pivoting. The seat stopper 54 can be formed of a metal such as stainless steel. The diameter of the sheet stopper 54 can be set to 5 mm to 10 mm when the length across the protective sheet 61 is about 200 mm to 300 mm. In this embodiment, a cylinder made of stainless steel having a diameter of 6 mm is used.

The seat stopper 54 maintains a constant height with reference to the flat surface 511 of the placement table 51 and maintains it directly below the chuck 52. In addition, Thereby moving the protective sheet 61 disposed at the end portion 51 in the longitudinal direction. The arrangement height of the seat stopper 54 coincides with the total height of the electronic component 60 excluding the electrode 602 and the protective sheet 61. [ That is, the sheet stopper 54 travels while pressing the non-sticking surface 612 of the protective sheet 61. The degree of pressing is such that the electrode 602 is not scratched, rubbed, or crushed. The movement range of the seat stopper 54 is up to the opposite end of the protective sheet 61, starting from the edge of the guide portion insertion hole 621 on the side of the guide portion 53, that is,

The component stopper 55 has a cylindrical shape of a major axis transverse to at least the entire component arrangement region 615 of the protective sheet 61 and is an axis rotatable roller. The component stopper 55 may be formed of a metal such as stainless steel. The diameter of the component stopper 55 may be determined in consideration of the diameter of the seat stopper 54 and the size of the electronic component 60. When the diameter is smaller than that of the seat stopper 54, So that it can be arranged. In the present embodiment, a cylinder made of stainless steel having the same diameter as the seat stopper 54 is used.

The component stopper 55 is arranged so as to be able to approach and separate from the seat stopper 54. [ While the chuck 52 and the sheet stopper 54 move end-to-end on the placement table 51, the component stopper 55 keeps a constant distance from the sheet stopper 54 and follows. The predetermined distance is less than the length of the electronic component 60 adhered to the protective sheet 61 (the length in the moving direction of the component stopper 55). When the chuck 52 and the sheet stopper 54 are positioned at the end of the placement table 51, the component stopper 55 is moved in the opposite direction to the sheet stopper 54 via the guide portion insertion hole 621 To the opposite side.

The guide portion 53 is disposed at a position in common with the guide portion insertion hole 621 of the frame 62. The leading end of the guide portion 53 is directed to the guide portion insertion hole 621 of the frame 62. The guide portion 53 is movable in the axial direction and protrudes toward the end of the protective sheet 61. The end of the protective sheet 61 is pushed up toward the chuck 52, And advances inside the guide portion insertion hole 621 of the frame 62 until it reaches the chuck 52. The guide portion 53 peels one side of the protective sheet 61 by pulling up. Therefore, the guide portion through-hole 621 has a pin shape and is formed in several places along one side of the protective sheet 61.

For example, as shown in Fig. 17, the through-hole formation positions of the guide portion insertion holes 621 are set at equal distances from each other with the center of one side of the frame 62 interposed therebetween. The guide portion 53 is provided corresponding to the guide portion insertion hole 621, and the guide portion 53 is formed into a round bar shape. The chuck 52 and the sheet stopper 54 are moved end-to-end in a direction orthogonal to one side of the frame 62 to peel the electronic component 60 from the protective sheet 61.

Fig. 18 shows the flow of the operation of the peeling treatment section 5. Fig. Fig. 18 is a transition diagram schematically showing the state of each step of the peeling treatment section 5. Fig. First, as shown in Fig. 18 (a), in a state in which the upper surface 603 of the electronic component 60 is in contact with the flat surface 511, the part-embedded- . That is, between the plate releasing portion 4 and the peeling treatment portion 5, there is provided a reversing device for inverting the parts-embedded sheet 67 separated from the cooling plate 63 in the plate releasing portion 4, The part-embedded-sheet 67 is placed on the placement stand 51 in an inverted state. A negative pressure is generated in the air hole 513 of the placement stand 51 so that the electronic component 60 is sucked into the flat surface 511 only. The seat stopper 54 is moved to the edge of the guide portion insertion hole 621 of the frame 62 and the chuck 52 is positioned just above the guide portion insertion hole 621 of the frame 62. [ The component stopper 55 is opened to the seat stopper 54 and is positioned outside the guide portion insertion hole 621 of the frame 62. [

The guide portion 53 is moved upward in the axial direction as shown in Fig. 18 (b). The guide portion 53 moves in the guide portion insertion hole 621 of the frame 62 and reaches the end of the protective sheet 61 adhered to the frame 62. [ The guide portion 53 further advances so as to project the end of the protective sheet 61 in a direction to leave the frame 62. [ As a result, the end of the protective sheet 61 begins to be peeled off by the guide portion 53. The end of the protective sheet 61 is guided toward the chuck 52 while being sandwiched between the guide portion 53 and the sheet stopper 54. [ The chuck 52 also moves toward the end of the protective sheet 61 to guide the end of the protective sheet 61 while the end of the protective sheet 61 is guided by the guide portion 53 good.

18 (c), when the end of the protective sheet 61 reaches the chuck 52, the pair of blocks are closed, and the end of the protective sheet 61 is held by the chuck 52. As shown in Fig. 18 (d), when the chuck 52 grasps the end of the protective sheet 61, the guide portion 53 is buried in the guide portion insertion hole 621 of the frame 62, The component stopper 55 is moved so that the component stopper 55 and the seat stopper 54 are brought close to each other by less than the length of the electronic component 60. [

The chuck 52 is pulled up while moving the chuck 52 and the sheet stopper 54 along the protective sheet 61 as shown in Fig. 18 (e). Since the end of the protective sheet 61 is gripped by the chuck 52 and the sheet stopper 54 runs on the protective sheet 61, And the electronic component 60 is peeled off the protective sheet 61 from the sheet stopper 54 as a starting point. In the case where the peeled protective sheet 61 is peeled while maintaining the vertical state, for example, the speed component of the horizontal movement and the vertical movement of the chuck 52 may be kept the same. If both speed components are the same, even if the moving speed is changed, it is possible to carry out the continuous operation without stopping as long as the operation is not stopped. However, both moving speeds may be maintained at a constant speed.

19, the separation of the electronic component 60 from the protective sheet 61 progresses so that only the end portion of the electronic component 60 contacts the sheet stopper 54 and the placement table 51 When the electronic component 60 is put in the flat surface 511, the electronic component 60 is about to rise to lift up the peeling start end 60a. However, the component stopper 55 follows the seat stopper 54. [ The part stopper 55 firmly presses the side of the peeling start end portion 60a to be lifted. As a result, the electronic component 60 is prevented from rising, and the gap 94 between the electrode 602 peeled from the protective sheet 61 and the protective sheet 61 continues to exist, And is held on the flat surface 511 of the placement table 51 without being attached. Further, since the seat stopper 54 is a roller capable of rotating the shaft, the sheet stopper 54 rotates when the electronic component 60 is pressed firmly, thereby suppressing spoilage with the electronic component 60. [

Further, the sheet stopper 54 travels while pressing the non-adhered surface 611 of the protective sheet 61. Until the peeling of the electronic component 60 starts and only the end of the electronic component 60 being peeled is in a state of being fitted to the flat surface 511 of the seat stopper 54 and the placement table 51, This sheet stopper 54 also prevents the electronic component 60 from following the peeled protective sheet 61. However, it is not essential that the seat stopper 54 travels while pressing the non-adhesive surface 611 of the protective sheet 61 from the viewpoint of exerting a function of creating a starting point of peeling by the sheet stopper 54 . That is, the seat stopper 54 may be moved at a position slightly away from the protective sheet 61.

18 (f), when the chuck 52 and the sheet stopper 54 completely terminate the component arrangement region 615 of the protective sheet 61, all the electronic components 60 are protected Peeled off from the sheet 61 and lined on the flat surface 511 of the placement table 51. [ By the recovery of the electronic component 60, the formation of the electromagnetic wave shield film 605 in the film forming apparatus 7 is completed. In addition, the chuck 52 terminates the flat surface 511 of the placement table 51, and the angle of attack away from the placement table 51 is not limited to 45 degrees. The position of the chuck 52 may be fixed and the placement table 51 may be continuously moved to peel off the protective sheet 61 or both the chuck 52 and the placement table 51 may be moved, . That is, the chuck 52 and the placement table 51 need to move relatively.

Here, FIG. 25 is a schematic diagram showing a configuration of a conventional pull-up device. This lifting device is a device for peeling the electronic component 60 from the adhesive film 9 having flexibility and tackiness in the same manner as the protective sheet 61 and has a pin body 8 movable in the axial direction. At the front end of the pin body 8, the adhesive film 9 to which the electronic component 60 is adhered is set. The pin body 8 picks up the adhesive film 9 on the surface opposite to the adhesive surface of the electronic component 60. The pin member 8 deforms the adhesive film 9 into a mountain shape with the electronic component 60 to be peeled as a vertex. As a result, the adhesive area between the electronic component 60 and the adhesive film 9 decreases, and the electronic component 60 thus peels from the adhesive film 9.

Fig. 26 is a schematic diagram showing a state in which the electronic component 60 is peeled off by the pull-up device. As shown in Fig. 26, a plurality of electronic components 60 are bonded to the adhesive film 9 with a gap therebetween. The spacing of the electronic components 60 adhered to the adhesive film 9 is narrow in view of production efficiency. Therefore, when one electronic component 60 is pulled up, the distortion of the adhesive film 9 spreads to the adhesive region of the neighboring electronic component 60 as well. Then, while the peeling object is being pulled up, a part of the adhesive film 9 is also peeled off to the neighboring electronic component 60, so that the peeling portion 91 is generated. However, when the peeling of the peeling object is completed, the pin body 8 retreats in the axial direction, so that the warp of the pressure-sensitive adhesive film 9 is eliminated. Then, the adhesive film 9 is reattached to the peeling portion 91, and the reattached portion 92 of the adhesive film 9 is formed on the electronic component 60. [

27 is a photograph showing the state of the electrode 602 after the adhesive film 9 is reattached to the electronic component 60. As shown in Fig. 27, when the adhesive film 9 is reattached , And the residue (93) of the adhesive film (9) may be generated on the electrode (602). The residue 93 of the adhesive film 9 may be burned and carbonized when the electronic component 60 is reflowed when the electronic component 60 is mounted thereon.

On the other hand, FIG. 20 is a photograph of the electrode 602 after the electronic component 60 is peeled from the protective sheet 61 by the peeling treatment section 5. FIG. According to the peeling treatment section 5, the protective sheet 61 is always kept flat by the sheet stopper 54, and once the protective sheet 61 is peeled off, 61 can be restored and reattached. The position of the electronic component 60 is fixed by the component stopper 55 and the air hole 513 of the placement table 51. It is also possible to prevent the electronic component 60 from rising have. As a result, no residue of the protective sheet 61 was seen on the electrode 602 of the electronic component 60, as shown in Fig.

Thus, the peeling treatment section 5 strips the electronic component 60 from the protective sheet 61 after film formation by the film forming section 3. The peeling treatment section 5 is provided with a fixing section for fixing the position of the placing table 51, the chuck 52 and the electronic component 60. The placement stand 51 supports the electronic component 60 adhered to the protective sheet 61. The chuck 52 grasps the end portion of the protective sheet 61 and moves relative to the placement table 51 to continuously peel it toward the opposite end of the end. The fixing portion fixes the position of the electronic component (60) when the electronic component (60) is peeled from the protective sheet (61). This prevents the electronic parts 60 and the protective sheet 61 from being reattached after being peeled off once and prevents the residue 93 of the protective sheet 61 from being generated in the electronic part 60 .

The fixing portion is, for example, the flat surface 511 of the placement stand 51 on which the component stopper 55 or the air hole 513 penetrates. The component stopper 55 keeps a distance less than the length of the electronic component 60 with respect to the seat stopper 54 and suppresses the electronic component 60 from rising. The placement stand 51 suppresses rising of the electronic component 60 by pulling it. However, the placement stand 51 may not employ suction by the air holes 513 as long as it has a function as a fixing unit. For example, the placement table 51 may be an adhesive chuck, an electrostatic chuck, or a mechanical chuck as long as the electronic component 60 can be fixed.

Further, the guide portion 53 is provided so as to protrude toward the end portion of the protective sheet 61. The chuck 52 is placed at a position where the guide portion 53 is projected before grasping the end portion of the protective sheet 61. [ The guide portion 53 guides the end portion of the protective sheet 61 toward the chuck 52. As a result, the chuck 52 can be grasped and the possibility of peeling-off of the electronic component 60 and the protective sheet 61 can be reduced.

In addition, it is provided with a sheet stopper 54 that moves together with the chuck 52 along the protective sheet 61 to make a starting point of peeling. The sheet stopper 54 is positioned in the vicinity of the position where the guide portion 53 is projected and the end portion of the protective sheet 61 peeled off the guide portion 53 is held with the guide portion 53, (52). Thus, the chuck 52 can grasp the end of the protective sheet 61 more reliably, and the possibility of peeling-off of the electronic component 60 and the protective sheet 61 can be reduced.

The sheet stopper 54 has been described by taking a cylindrical body having a shaft orthogonal to the movement direction of the seat stopper 54 as an example. However, it is sufficient that the sheet stopper 54 can be driven while pressing the protective sheet 61 firmly. It is also good. The component stopper 55 has been described by taking a cylindrical member having a shaft orthogonal to the moving direction of the component stopper 55 as an example. However, a plate member, a block member, or a brush may be used. In the case where the component stopper 55 is cylindrical, since it is the shaft rotatable roller, it rotates when the electronic component 60 is pressed firmly, thereby suppressing the sputtering with the electronic component 60. [

The operation mechanism of the chuck 52, the operation mechanism of the seat stopper 54, the operation mechanism of the component stopper 55, and the operation mechanism of the guide portion 53 may employ a well-known mechanism, But is not limited thereto.

For example, the chuck 52 may employ the following operating mechanism. That is, both of the blocks are supported on the base, and one of the blocks is positioned and floating relative to the base. The other block is movable with respect to one block. An oval cam is in contact with the outside of the block which is in operation. When this cam is rotated and the block reaches the long diameter range, the movable block is pushed by the cam to approach the floating block. In addition, a compression spring is provided between the pair of blocks, and the pair of blocks is pushed in a direction to widen the gap. When the cam is rotated and the block reaches the short diameter range, the movable block is separated from the floating block by the pushing force of the compression spring.

For example, a ball screw and a rail extending at an angle of 45 degrees to the flat surface 511 of the placement table 51 are provided, the base of the chuck 52 is fixed to the slider of the ball screw, It is holding. When the screw shaft of the ball screw is rotated by the motor, the chuck 52 moves along the rail from one end of the stage 51 to the other end.

The component stopper 55 is provided with a tension spring between the component stopper 55 and the base for supporting the seat stopper 54 so that the component stopper 55 and the seat stopper 54 are brought close to each other An elliptical cam is disposed between the component stopper 55 and the base for supporting the seat stopper 54 while pushing the component stopper 55. When the cam is in contact with the base of the long diameter range of the cam, 55 and the seat stopper 54 in a direction to separate them.

The rear end of the guide portion 53 is a cam hole. The cam ball follows the circumferential surface of the oval cam. The cam is pivotally supported by the rotary motor and is rotatable in the circumferential direction. When the rotation motor is driven to rotate the cam, the cam hole lifts the bulging portion of the cam, and the guide portion 53 is pushed up.

The through-hole formation positions of the guide portion insertion holes 621 were set at equal distances from each other with the center of one side of the frame 62 therebetween. As a result, it becomes easy to peel off the side surface of the protective sheet 61. [ The guide portion 53 is provided corresponding to the guide portion insertion hole 621, and the guide portion 53 is formed into a round bar shape. The chuck 52 and the sheet stopper 54 are terminated in a direction orthogonal to one side of the frame 62 so that the electronic part 60 is peeled off from the protective sheet 61. The peeling treatment section 5 is not limited to this, but a guide hole and guide part of various shapes may be employed, and the peeling direction may adopt various orientations.

For example, as shown in Fig. 21, it is possible to employ a guide portion 53 having a long rounded corner rectangle, ellipse, rectangle or the like at its tip end along one side of the frame 62. Fig. The protective sheet 61 can be easily lifted up and the end of the protective sheet 61 can easily reach the chuck 52 do. 22, a notch 622 including an arrangement region of the guide portion 53 may be formed in the frame 62 instead of the guide portion insertion hole 621. [ 23, the guiding portion insertion hole 621 is arranged at the corner of the frame 62 and the corner portion of the frame 62 is set as the peeling starting point so that the chuck 52 and the sheet The stopper 54 may be moved and peeled off along the diagonal line of the protective sheet 61. [

(Other Embodiments)

The present invention is not limited to the above-described embodiment, but includes the following aspects. In other words, as shown in Fig. 24, the film forming apparatus 7 may be provided with the conveyance arranging section 71 for further performing the component arranging step. The conveyance arranging section 71 carries out the component arranging process and transfers the electronic component 60 from the tray on which the electronic component 60 before the film forming process is disposed to the component not disposed sheet 65. For example, the tray and the component-unseated sheet 65 are arranged so as to be adjacent to each other, and the transfer arrangement section 71 is a robot that can move the tray and the component- good. A vacuum chuck is provided at the tip of the arm of the robot. The transfer arrangement section 71 holds the electronic component 60 by generating a negative pressure on the tray and releases the negative pressure on the component-unseated sheet 65 by vacuum breaking or atmospheric opening or the like, And arranged on the non-alignment sheet (65).

Although the film forming apparatus 7 is an apparatus including the embedding processing unit 1, the plate mounting unit 2, the film forming unit 3, the plate releasing unit 4 and the peeling process unit 5, May be constituted as an apparatus to form a system. That is, the embedding processing section 1 may be an independent embedding processing apparatus, the plate mounting section 2 may be an independent plate mounting apparatus, the film forming section 3 may be an independent film forming apparatus, Or the peeling treatment section 5 may be an independent peeling treatment apparatus.

The height H1 from the surface of the component arrangement region 615 to the top surface of the frame 62 in the above embodiment is the distance from the surface of the component arrangement region 615 to the top surface of the electronic component 60 The present invention is not limited to this, and may be lower than the height H2. In this case, a region facing the component arrangement region 615 on the flat surfaces 112, 212, and 412 of the ceiling portions 11, 21, and 41 is a region that allows a difference between the height H1 and the height H2 24a, and 45 can be formed in the concave portion as much as the concave portion.

Although the embodiments of the present invention and the modified examples of the respective parts have been described above, these embodiments and modified examples of the respective parts are presented as an example, and it is not intended to limit the scope of the invention. The above-described embodiments of the present invention can be practiced in various other forms, and various omissions, substitutions, and alterations can be made without departing from the gist of the invention. These embodiments and their modifications are included in the scope of the invention and the scope of the invention as defined in the claims.

The present invention relates to a method and apparatus for manufacturing a semiconductor device and a method of manufacturing the same and a method of manufacturing the same. Wherein the pusher is provided with an air vent hole and an air vent hole in the air inlet hole, The air pressure supply hole of the air pressure supply hole and the air pressure supply hole of the O-ring are arranged in parallel to each other. 3: film forming unit 31: chamber 311: processing position 312: film forming position 32: load lock chamber 33: short circuit 34: rotary table 35: surface treatment unit 36: sputtering circle 361: target 4: The air pressure supply hole 415 and the air supply opening 415 are formed in the same manner as in the first embodiment. Hole, 424: Fu The airbag apparatus according to any one of claims 1 to 3, wherein the airbag is provided in the airbag. The present invention relates to an electronic component and a method of manufacturing the same and a method of manufacturing the same. The electromagnetic wave shielding film 61 is provided with a protective sheet 611 and an adhesive surface 612. The non-adhesive surface 613 is an outer frame region 614 is an inner frame region 615 is a component arrangement region 62 is a frame 621 is a guide- The present invention relates to an image forming apparatus and a method of manufacturing the same, and more particularly, to an image forming apparatus and a method of manufacturing the same. Plate, 7: film forming apparatus, 71: conveying arrangement unit, 73: conveying unit, 74: control unit, 75:

Claims (4)

As a film forming apparatus for an electronic component arranged on a protective sheet in close contact with a cooling plate,
A film forming section for depositing a film forming material by sputtering on the electronic part on the protective sheet adhered to the cooling plate,
And a plate releasing section for releasing the cooling plate after passing through the film forming section,
Wherein the cooling plate has an air hole penetrating through the front and back in a range including a region where the electronic component is arranged,
The plate-
A placement stand having a static pressure generating hole facing the air hole of the cooling plate and generating a static pressure,
A portion of the protective sheet which is out of the region in which the electronic component is arranged is pressed firmly while the positioning member presses the region where the electronic component is arranged through the positive pressure generating hole, And a fixing unit for releasing the pressing force after the cooling plate is separated from the cooling plate. The apparatus according to claim 1,
A cooling plate disposed opposite to the cooling plate with the protective sheet therebetween and having a flat surface spaced apart from the protective sheet,
Wherein the flat surface presses the projection of the protective sheet firmly in a region where the electronic component is arranged while the region where the electronic component is arranged is pressed. [3] The apparatus according to claim 2, wherein the plate releasing portion has a negative pressure generating hole opened on the flat surface and generating a negative pressure,
Wherein the negative pressure generating hole sucks the protective sheet together with the pressing of the region where the electronic component is arranged through the positive pressure generating hole. The electronic component according to any one of claims 1 to 3, wherein the cooling plate has a hole which is located outside the region where the electronic component is arranged, and has a through hole at a portion pressed firmly by the fixing portion,
The plate-
A region of the protective sheet which is firmly pressed by the fixing portion is moved in a direction away from the cooling plate after the area where the electronic parts are arranged is moved away from the cooling plate and then advances inside the insertion hole of the cooling plate With pusher pusher,
Wherein the fixing portion is spaced apart from the cooling plate along with advancement of the pusher when the firmly pressing is released.

Images