KR20190029057A - Physical Vapor Deposition Device and Method - Google Patents

Abstract

The present invention provides a dry plating apparatus which can perform continuous plating by continued smooth supply of solid raw materials. An embodiment provides a dry plating apparatus comprising: a vapor chamber configured such that vapor is sprayed onto a material to be plated within the vapor chamber; an evaporation heating unit disposed outside an evaporation region, in which molten raw materials are placed, within the vapor chamber; a solid raw material supply pipe extending from a solid raw material supply unit to the evaporation region and extending through at least a part of the vapor chamber, so as to supply raw materials to the evaporation region; the solid raw material supply unit connected to the solid raw material supply pipe; and a solid raw material heating unit for heating such solid raw materials that are located outside the evaporation region in the solid raw material supply pipe.

Description

Technical Field [0001] The present invention relates to a dry plating method and a dry plating method,

The present invention relates to a dry-type plating apparatus and a dry-type plating method for performing dry-type plating by supplying and melting / evaporating a solid raw material.

Dry plating technology is widely used in many industries because it can obtain a good plating layer characteristic even in a thin plating thickness as compared with wet plating. 1 is a schematic view of a conventional dry plating apparatus. The plating material 1 and the evaporation source crucible 2 are disposed in the vacuum chamber 10 and the vapor 3 generated in the evaporation source crucible 2 is adhered to the plating material to perform dry plating. In the case of such a plating apparatus, there is a limitation in that continuous production and mass production are difficult due to the characteristic that the inside of the vacuum chamber 10 must maintain a vacuum. Especially, in order to form a plating layer on a high-speed product, a large amount of evaporation source must be evaporated within a unit time, and the evaporation source must be continuously supplied to the evaporator because the evaporation source must be plated continuously for mass production.

In order to attain the above-mentioned continuous supply of raw materials, conventionally, there has been proposed a method of supplying a raw material in a wire form or supplying a raw material in a liquid form. However, when raw materials of wire form are used, processing costs for processing the shape of raw material into wire form are added, which causes a burden of cost increase.

When a liquid raw material is used as in Patent Document 1, all of the materials exposed to the liquid have to be kept at a high temperature, and the use of the valve for controlling the supply amount of the high temperature liquid is limited, so that the operation cost and the equipment cost are greatly increased. Therefore, the conventional method has not been widely used for stability, economical efficiency, technical problems, and the like of equipment.

(Patent Document 1) KR10-2009-0074064 A

It is an object of the present invention to provide a dry plating apparatus and method capable of continuously supplying a solid raw material continuously and continuously.

In order to achieve the above object, the present invention provides a dry plating apparatus and a dry plating method as described below.

According to an embodiment of the present invention, there is provided a steam generator comprising: a steam chamber configured to inject steam into an object to be plated; An evaporation heating unit disposed outside the evaporation area where the molten raw material in the vapor chamber is located; A solid feed pipe extending from the solid feedstock supply to the evaporation zone to feed the feed to the vaporization zone and passing through at least a portion of the vapor chamber; A solid raw material supply unit connected to the solid raw material supply pipe; And a solid raw material heating unit heating the outer solid raw material based on an evaporation area of the solid raw material in the solid raw material supply pipe.

In one embodiment, the solid raw material heating section may be disposed on an extension line extending upward from the evaporation area side end of the solid raw material supply pipe.

Further, in one embodiment, the solid raw material supply pipe may be surrounded by the vapor chamber for a certain period from the evaporation area side end.

In one embodiment of the present invention, the solid raw material heating unit may be an electron beam.

In the present invention, the evaporation zone is located below the vapor chamber, and the solid material heating unit is located vertically above the evaporation zone. In the solid material supply pipe, the solid material may be moved to the evaporation zone by its own weight have.

In one embodiment, the solid feedstock comprises a hopper in which the solid feedstock is stored; And a supply valve arranged at a lower portion of the hopper and configured to sequentially supply the solid raw material, wherein when the solid raw material is supplied to the solid raw material supply pipe, the inside of the hopper is maintained at a pressure lower than the atmospheric pressure .

Further, in one embodiment of the present invention, the solid raw material supply pipe between the solid raw material heating unit and the evaporation area may be provided with a vapor prevention valve configured to open and close the solid raw material supply pipe. In the solid raw material supply pipe, And an additional heating unit disposed outside the supply pipe to supply energy to the molten raw material.

Alternatively, the present invention provides a dry plating method for plating an object to be plated with a vapor obtained by melting a solid material after evaporation, the method comprising: a supply step of supplying a solid material through a supply pipe extended to an evaporation area; A melting step of melting the solid raw material; And a vaporizing and plating step of vaporizing the molten raw material to form a vapor, and plating the material to be plated, wherein the melting step is carried out by heating the raw material in the solid raw material through the heating source, Provided is a dry plating method for melting a solid raw material by heating an outer solid raw material on the basis of an evaporation area.

In one embodiment of the present invention, the supplying step may be performed at a constant cycle, and the energy applied to the melting step may be 10 to 30% of the energy required for the solid raw material supplied at the supplying step to reach the melting temperature.

Further, in one embodiment, the solid material heating section may be an electron beam disposed on an extension line of the supply pipe, and after the melting step is performed, the vapor of the supply pipe may be supplied to the solid raw material supply section for supplying the solid raw material in the supply step, A steam shutoff step is performed to shut off the supply pipe through a steam shutoff valve installed in the supply pipe to prevent the solid raw material heating unit from heating in the melting step to heat the solid raw material and the steam shutoff valve may open the supply pipe have.

The dry plating apparatus and the dry plating method of the present invention can smoothly and continuously supply the solid raw material, so that the dry plating apparatus can continuously perform dry plating.

Further, in the dry plating apparatus and method of the present invention, it is possible to smoothly supply a raw material and perform a large amount of dry plating.

1 is a schematic view of a conventional dry plating apparatus.
2 is a schematic view of a dry plating apparatus according to the present invention, Fig. 2 is a schematic view of a dry plating apparatus in a supply step, Fig. 3 is a schematic view of a dry plating apparatus in a melting step, Fig. 2 is a schematic view of a dry-type plating apparatus. Fig.

In the present invention, the dry plating apparatus is an apparatus for plating a plated material by melting / evaporating a solid raw material, and the evaporation region inside the chamber refers to a portion for evaporating the raw material. In the evaporation region, an evaporation heating portion is disposed to perform heating, and various heating means including electromagnetic induction heating can be used as the evaporation heating portion.

In the present invention, the solid raw material is supplied from the solid raw material supply portion to the evaporation region through the solid raw material supply pipe, and the solid raw material in the supply pipe is heated by the solid raw material heating portion.

At this time, it is preferable that the solid raw material heating section is configured to be able to heat linearly, for example, an electron beam. The solid raw material heating section is disposed on the extension line of the solid raw material supply pipe when the solid raw material heating section is operated to melt the solid raw material so that the solid raw material that can be caught in the supply pipe is also melted and the inside of the supply pipe is clogged by the solid raw material And it is also possible to prevent the case where the solid raw material is caught in the supply pipe at the upper portion of the molten raw material.

In the present invention, since the solid raw material supply pipe extends to the evaporation region, the molten raw material in the evaporation region and the solid raw material undergo heat exchange and melt the heat energy of the solid raw material heating portion and the heat energy solid raw material of the molten raw material, And then supplied to the plated material in the vapor chamber.

In the present invention, the solid raw materials are continuously supplied at regular intervals, and the solid raw materials are continuously supplied through the solid raw material heating portion at each supply, without the solid raw materials stagnating in the solid raw material supply pipe. The solid raw material may have various shapes such as a bead shape, a shape obtained by cutting the wire material at regular intervals, or an irregular shape. Even if the solid raw material is caught in the supply pipe due to a specific shape, it can be released from the solid raw material heating portion. Can be used to broaden the choice of solid raw materials.

In the present invention, a steam supply valve is disposed in the solid raw material supply pipe. The steam supply valve closes the supply pipe at a time when the solid raw material heating unit, which operates at regular intervals, does not operate, thereby preventing steam from the evaporation area side end of the solid material supply pipe . The steam may adhere the solid raw material to the solid raw material supply pipe or block the solid raw material supply portion, but in the present invention, the anti-vapor valve is attached to solve this problem.

In the present invention, one end of the solid raw material supply pipe is located in the evaporation area and the other end is connected to the solid raw material supply part. The solid material feed pipe is configured to be able to move from the solid material supply part to the evaporation area by the self weight of the solid material. Thus, when the supply amount of the solid material supply part is controlled, the solid material can be moved to the evaporation area by its own weight.

Since the solid raw material supply portion is in communication with the vapor chamber maintained in a vacuum state during the supply of the solid raw material, a structure capable of achieving a vacuum in the solid raw material supply portion is also suitable.

The supply period of the solid raw material may be performed at intervals of a predetermined time, and the frequency of the evaporation heating section (for example, electromagnetic induction) for heating the molten raw material may be observed to determine the supply period of the solid raw material . Particularly, when the amount of the molten raw material is not increased after the supply of the solid raw material, the solid raw material is caught in the supply pipe. Therefore, it is also possible to melt the solid raw material of the solid raw material supply pipe through the solid raw material heating portion to go down to the evaporation region .

Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings.

Figure 2 shows a schematic diagram of a dry-type plating apparatus in the feeding step, and Figure 3 shows a schematic view of the dry-type plating apparatus in the melting step, and Figure 4 shows a schematic view of the dry- have.

In the embodiment of Figures 2 to 4, the dry-type plating apparatus comprises a vapor chamber 10 configured to inject the internal vapor 3 into the plated material 1; An evaporation heating unit (20) disposed outside the evaporation zone (25) in which the molten raw material is located in the vapor chamber (10); A solid feed pipe (80, 85) extending from the solid feedstock supply (60) to the evaporation zone (25) to feed the feed to the vaporization zone (25) and passing through at least a portion of the vapor chamber (10); A solid raw material supply unit 60 connected to the solid raw material supply pipes 80 and 85; And a solid raw material heating unit 50 for heating the outer solid raw material based on the evaporation area 25 among the solid raw materials 90 in the solid raw material supply pipes 80 and 85.

The solid raw material supply part 60 employs a hopper for storing a raw material and a supply valve 65 for supplying a predetermined amount of raw material to the upper part of the solid raw material supply part 60. However, if a certain amount of raw material can be supplied, In the example, a screw type supply device and a gate valve were applied to control the feed rate of the raw material.

 An inter-lock valve 70 may be applied to the upper portion of the solid raw material supply portion 60 and the interlock valve 70 may be positioned between the raw material chamber at an atmospheric pressure (not shown) and the solid raw material supply portion 60 do. The solid raw material supply portion 60 may have a structure capable of vacuum evacuation.

The interlock valve 70 is closed and the solid raw material supply unit 60 is closed after filling the solid raw material to the target value. It evacuates to vacuum. When the solid raw material supply portion 60 reaches the target vacuum, for example, 2 x 10 ^-2 Torr, the valve 65 under the solid raw material supply portion 60 is opened to supply the solid raw material to the evaporation region 25.

The supply valve 65 is connected to the evaporation heating unit 20 so as to feedback control the inductance of the power supply unit to an input so that the inductance can be maintained at a target value, It is also possible to make the amount thereof remain constant.

The solid raw material supply pipes 80 and 85 are connected to the vertical supply pipe 85 extending from the evaporation area 25 to the vertical upper part and the vertical supply pipe 85, And a supply pipe (80). On the other hand, the solid raw material heating section 50 is disposed on the extension line of the vertical supply pipe 85 of the solid raw material supply rods 80, 85. Accordingly, the solid material heating section 50 is disposed at a vertically upper portion of the evaporation region 25 with the vertical supply pipe 85 interposed therebetween.

It is important in the present invention that at least a part of the solid raw material supply pipes 80 and 85 are surrounded by the evaporation crucible 30 so that it is difficult to transfer sufficient heat into the solid raw material supply pipes 80 and 85, 80, 85), it is necessary to supply a heat source which can dissolve the solid raw material. If the heat source is not transferred into the supply pipe, the solid raw material 90 is accumulated in the solid raw material supply pipes 80 and 85 and the inlet of the solid raw material supply pipes 80 and 85 becomes clogged.

The solid material heating unit 50 is preferably configured to heat the solid fuel in the evaporation zone 25 through the vertical supply pipe 85, And it is also possible to melt the hanging portion even if the solid raw material 90 is caught in the middle of the vertical supply pipe 85. Particularly, in the case of electron beam, it is preferable in that the raw material vapor can be easily melted even if the raw material vapor is condensed in the beam irradiation part 51. It is preferable that the beam irradiation unit 51 is disposed at the center of the solid material feed pipes 80 and 85.

It is not easy to add a heating device to the inside of the steam chamber 10 because it is controlled by the vacuum. Particularly, heating the inside of the solid raw material supply pipes 80 and 85 outside the evaporation crucible 30 is effective in terms of efficiency However, it is advantageous in terms of heating efficiency when heating is performed through the internal space of the solid raw material supply pipes 80 and 85.

Particularly, the portion where the vertical supply pipe 85 and the inclined supply pipe 80 join together can be a portion where the solid raw material can be easily caught, or can be heated by the solid raw material heating portion 50 to melt the solid raw material, have. .

The solid raw material 90 is supplied to the evaporation region 25 through the solid raw material supply pipes 80 and 85 and exchanges heat with the raw material in the evaporation region 25. At this time, the solid raw material heating unit 50 also transmits heat energy to the solid raw material 90.

When the power of the electron beam which is the heating source 50 is excessively strong, the solid raw material 90 in the solid material feed pipes 80 and 85 evaporates beyond the melting thereof to form an excessive vapor, The steam may be condensed at the inlet of the steam generator.

The energy E _c conducted from the molten raw material in the solid material feed pipes 80 and 85 to the solid raw material and the energy E _e applied to the solid raw material by the solid raw material heating unit 50 are combined to melt the solid raw material The energy of the solid raw material heating section 50 should be adjusted as shown in the following formula (1).

Energy (E _e ) of the heating source of the solid material = Energy (E _m ) of the melting of the solid material - Energy (E _c ) conducted to the solid material (1)

Since the energy (E _m ) for melting the solid raw material 90 is determined by the kind of the solid raw material 90, the energy of the electron beam can be easily estimated by knowing only the energy E _c conducted to the solid raw material. In the embodiment of the present invention, the power (energy) of the solid raw material heating section 50 is controlled to contribute about 10 to 30% to the melting temperature of the supplied raw material, and the remaining 70 to 90% It is preferable that the solid raw material is melted by the energy to be conducted.

Similarly to the control of the supply valve 65 of the solid raw material supply part 60, the energy of the solid raw material heating part 50 is also measured by measuring the amount of the molten raw material in the evaporation area and keeping the amount of the molten raw material in the crucible constant The energy of the solid raw material heating unit 50 can be adjusted.

In this embodiment, only one solid material heating section 50 at the upper part of the evaporation area 25 is shown. However, if the efficiency of the solid material heating section 50 is slightly lowered, the solid material heating section 50, And an additional heating unit disposed outside.

The vertical supply pipe 85 of the solid raw material supply pipes 80 and 85 may be provided with a steam prevention valve 40 for opening and closing the vertical supply pipe 85. The steam prevention valve 40 is closed by the solid raw material supply pipe 85 except for the operation of the solid raw material heating unit 50 or the supply of the solid raw material, Preventing the steam from rising to the solid raw material heating section 50 or the solid raw material supply section 60. The steam in the supply pipes 80 and 85 is condensed when it goes out of the steam chamber and this may cause congestion of the solid raw material 90 so that it is preferable that the steam is raised to the solid raw material supply pipes 80 and 85 It is preferable to prevent the user from coming.

The solid raw material supply pipes 80 and 85 extend to the evaporation region 25 of the evaporation crucible 30 and the molten raw material is converted into the vapor 3 by the evaporation heating unit 20, (1).

In the present invention, since the solid raw material 90 can be continuously supplied, it is possible to stably dry-coat the material to be plated.

The dry plating method through the dry plating apparatus according to the present invention is as follows.

As shown in the drawings of FIGS. 2 to 4, the evaporation heating part 20 is performed without stopping the evaporation and plating step of evaporating and continuously plating the molten raw material among the dry plating methods.

On the other hand, the supply step for supplying the solid raw materials required for the evaporation and plating steps may be supplied at regular intervals through the solid raw material supply pipes (80, 85). A fusing step is performed in which the solid raw material is melted inside the feed pipes (80, 85) immediately after the feeding step. The melting step includes heating the outer solid material with respect to the evaporation area of the solid material in the supply pipe (80, 85) through the solid material heating part (50) together with the heat transfer from the molten material in the evaporation area (25) The raw material is melted.

The steam shutoff valve 40 opens the supply pipes 80 and 85 before the supplying step and after the melting step is completed the steam shutoff valve 40 blocks the supply pipes 80 and 85 again.

In one embodiment, a supply step of supplying the solid raw material is performed every 30 seconds. When the solid raw material is supplied, the solid raw material heating part 50 is operated for a predetermined time, for example, 15 seconds, . When the solid raw material heating unit 50 is operated for a predetermined time, the steam shutoff valve 40 cuts off the supply pipes 80 and 85. Thereafter, the step of supplying the solid raw material again is carried out again and a series of steps are repeated again.

Therefore, in the dry plating method of the present invention, the supply of the raw material is smooth and the evaporation and plating steps can be performed without interruption.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: steam chamber 20: evaporation heating section
30: Evaporation crucible 40: Steam cutoff valve
50; Solid raw material heating unit 60: Solid raw material supply unit
80, 85: supply pipe

Claims (13)

A vapor chamber configured to discharge the vapor inside the plating material;
An evaporation heating unit disposed outside the evaporation area where the molten raw material in the vapor chamber is located;
A solid feed pipe extending from the solid feedstock supply to the evaporation zone to feed the feed to the vaporization zone and passing through at least a portion of the vapor chamber;
A solid raw material supply unit connected to the solid raw material supply pipe; And
And a solid raw material heating unit for heating the outer solid raw material based on an evaporation area of the solid raw material in the solid raw material supply pipe.
The method according to claim 1,
Wherein the solid raw material heating portion is disposed on an extension line extending upward from the evaporation area side end of the solid raw material supply pipe.
The method according to claim 1,
Wherein the solid raw material supply pipe is surrounded by the vapor chamber for a certain period from the evaporation area side end.
The method according to claim 1,
Wherein the solid raw material heating unit is an electron beam.
5. The method of claim 4,
An evaporation zone is located below the vapor chamber, the solid material heating zone is located vertically above the evaporation zone,
Wherein the solid raw material is moved to the evaporation area by its own weight in the solid material feed pipe.
6. The method according to any one of claims 1 to 5,
The solid raw material supply portion
A hopper in which a solid raw material is stored; And
And a supply valve disposed at a lower portion of the hopper and configured to sequentially supply the solid raw material,
And the inside of the hopper is kept at a pressure lower than the atmospheric pressure when the solid raw material is supplied to the solid raw material supply pipe.
6. The method according to any one of claims 2 to 5,
Wherein the solid raw material supply pipe between the solid raw material heating unit and the evaporation area is provided with a vapor prevention valve configured to open and close the solid raw material supply pipe.
6. The method according to any one of claims 1 to 5,
Further comprising an additional heating unit disposed outside the supply pipe to supply energy to the molten raw material in the solid raw material supply pipe.
A dry plating method for plating a plated material with steam obtained by melting a solid raw material and evaporating it,
A supply step of supplying the solid raw material through a supply pipe extended to an evaporation area;
A melting step of melting the solid raw material; And
A vaporizing and plating step of vaporizing the molten raw material to form a vapor, and plating the material to be plated;
Wherein the melting step comprises melting the solid raw material by heating the outer solid raw material with respect to the evaporation area of the solid raw material in the supply pipe through the solid raw material heating part together with the heat transfer from the molten raw material.
10. The method of claim 9,
Wherein the supplying step is performed at a constant cycle.
11. The method of claim 10,
Wherein the energy applied to the melting step is 10 to 30% of the energy required for the solid raw material fed in the feeding step to reach the melting temperature.
12. The method of claim 11,
Wherein the solid material heating portion is an electron beam disposed on an extension of the supply pipe.
12. The method of claim 11,
After the melting step is carried out, the vapor of the feed pipe is fed through the steam shutoff valve provided in the feed pipe to prevent the feedstock from going to the solid feedstock feeder supplying the solid feedstock or the solid feedstock heating the solid feedstock in the melting step A steam cutoff step for cutting off the supply pipe is performed,
Wherein the steam shutoff valve opens the supply line before performing the supply step.

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