KR200397524Y1 - Apparatus for trapping semiconductor residual product - Google Patents

Abstract

The present invention is to provide a semiconductor by-product trap device suitable for preventing failure of the vacuum pump by trapping the reaction by-products generated in the process chamber during the deposition and etching of the thin film, the semiconductor by-product trap device of the present invention is a process chamber A semiconductor by-product trap device for trapping reaction by-products generated during deposition or etching of a thin film in the apparatus, comprising: a hollow trap chamber having a cooling line along an inner wall surface, and an inner wall surface of the trap chamber at a hollow portion of the trap chamber; It is installed and spaced apart from the process chamber characterized in that it comprises a heating chamber for introducing the reaction by-products.

Description

Semiconductor by-product trap device {APPARATUS FOR TRAPPING SEMICONDUCTOR RESIDUAL PRODUCT}

The present invention relates to a semiconductor device, and more particularly, to a semiconductor by-product trap device suitable for more efficiently trapping reaction by-products such as unreacted gas and toxic gas generated inside a process chamber during semiconductor device manufacturing.

In general, a semiconductor manufacturing process is mainly composed of a pre-process (Fabrication process) and a post-process (Assembly process), the pre-process is to deposit a thin film on a wafer (wafer) in various process chambers (Chamber), the deposition It is a process of manufacturing a so-called semiconductor chip by repeatedly performing a process of selectively etching the prepared thin film, and processing a specific pattern, and the post process refers to the chips manufactured in the previous process individually. After separating, refers to the process of assembling the finished product by combining with the lead frame.

At this time, the process of depositing a thin film on the wafer or etching the thin film deposited on the wafer is a process gas such as hydrogen and toxic gases such as silane (Silane), arsine (Arsine) and boron chloride and a process gas such as hydrogen It is carried out at a high temperature by using, a large amount of harmful gases such as various ignitable gases, corrosive foreign substances and toxic components are generated in the process chamber during the process.

Therefore, in the semiconductor manufacturing equipment, a scrubber is installed at the rear end of the vacuum pump that makes the process chamber vacuum and purifies the exhaust gas discharged from the process chamber and discharges it to the atmosphere.

However, when the exhaust gas discharged from the process chamber contacts the atmosphere or the ambient temperature is low, the exhaust gas becomes solid and becomes powder. The powder adheres to the exhaust line to increase the exhaust pressure and at the same time the vacuum is introduced into the vacuum pump. There has been a problem of causing a failure of the pump and a backflow of the exhaust gas to contaminate the wafer in the process chamber.

Accordingly, in order to solve the above problems, as shown in FIG. 1, a powder trap device is installed between the process chamber and the vacuum pump to adhere the exhaust gas discharged from the process chamber in a powder state.

That is, as shown in FIG. 1, the process chamber 1 and the vacuum pump 3 are connected to a pumping line 5, and the pumping line 5 includes reaction by-products generated in the process chamber 1. A trap tube 7 for trapping and accumulating in powder form is installed branched from the pumping line 5.

In the conventional powder trap device, unreacted gas generated during deposition or etching of a thin film in the process chamber 1 flows into the pumping line 5 having a relatively lower temperature atmosphere than the process chamber 1. While solidified into a powder of the powder state, it is accumulated in the trap pipe 7 installed branched from the pumping line (5).

In this case, the reason why the trap pipe 7 is installed by branching from the pumping line 5 is to prevent the powder from flowing into the vacuum pump 3 as mentioned above. For reference, reference numeral “9” in FIG. 1 indicates powder.

However, the powder trap apparatus of the prior art as described above had the following problems.

First, since the reaction by-product generated in the process chamber takes a long time to be converted into a powder state and accumulated in the trap tube, the entire process time is long.

Second, since the space of the trap tube in which the powder is accumulated is very narrow, there is an inconvenience of frequently removing the powder accumulated in the trap tube.

An object of the present invention is to provide a semiconductor byproduct trap device suitable for trapping semiconductor byproducts efficiently.

The semiconductor by-product trap device of the present invention for achieving the above object is a semiconductor by-product trap device for trapping the reaction by-products generated during the deposition or etching of a thin film in the process chamber, the hollow cooling line is installed along the inner wall And a heating chamber spaced apart from an inner wall of the cooling chamber at a hollow portion of the cooling chamber, and a heating chamber through which reaction by-products are introduced from the process chamber.

The cooling chamber may include a first housing having a first connector for connecting with the process chamber and a second connector for connecting with a vacuum pump, and a plurality of layers inside the first housing. It is characterized in that it comprises a first plate having a through hole enough to fit the heating chamber and a plurality of supporting bars installed through the first plates to support the first plates.

In addition, the heating chamber is a hollow second housing fitted to the through-holes formed in the first plate, the reaction by-product inlet pipe communicating with the first connector and extending into the second housing, and the second It is installed in a plurality of layers inside the housing, the central portion of the through-hole formed so that the reaction by-product inlet pipe can be formed, and comprises a plurality of heaters installed around the reaction by-product inlet pipe It is characterized by.

The second housing may be installed in two layers, and a third plate of a plurality of layers may be installed at a lower end of the second housing.

In addition, the plurality of perforations are formed in the first, second plates and third plates of the plurality of layers, respectively, characterized in that the perforations are formed asymmetrically.

In addition, the diameter of the perforations formed in the first plate gradually decreases from the uppermost layer to the lower layer, and the diameter of the perforations formed in the second plates is gradually increased from the uppermost layer to the lower layer.

In addition, the heater has a bar (Bar) shape and is characterized in that it extends into the heating chamber through the upper end of the cooling chamber.

Hereinafter, the semiconductor by-product trap device of the present invention will be described with reference to the accompanying drawings.

FIG. 2 is an external perspective view of the semiconductor by-product trap device of the present invention, and FIG. 3 is a cutaway perspective view taken along line II ′ of FIG. 2. 4 is a cutaway perspective view illustrating a cooling chamber according to a semiconductor byproduct trap device of the present invention, and FIG. 5 is a cutaway perspective view illustrating a heating chamber according to a semiconductor byproduct trap device of the present invention.

First, as illustrated in FIGS. 2 and 3, the semiconductor by-product trap device of the present invention has a structure in which a heating chamber is installed inside a cooling chamber, and more specifically, the cooling chamber. The second housing 200 constituting the heating chamber is installed in the first housing 100 to be configured.

The cooling chamber has a cylindrical first housing 100 having a first connector 110 for connection with a process chamber (not shown) and a second connector 112 for connection with a vacuum pump (not shown), and Cooling line 114 is installed along the inner wall surface of the first housing 100 and a plurality of layers in the interior of the first housing 100, the center of the through-hole is enough to fit the heating chamber First plate 118 of a disc shape having a (116) and a plurality of supporting bar (120) installed to penetrate the first plate 118 to support the first plate (118) It is configured to include.

Here, the first housing 100 includes a top plate 100a serving as a cover, and the first connector 110 for connecting to the process chamber is preferably formed in the top plate 100a, and the vacuum pump The second connector 112 for connection with the is preferably formed at the bottom of the first housing (100).

The cooling line 114 is to make the inside of the cooling chamber in a low temperature atmosphere to trap the reaction by-products such as unreacted gas flowing out of the heating chamber, and as shown in the drawing, the first housing It is formed along the inner wall surface of the (100), the unreacted gas is converted into a powder state by the temperature of the inside of the cooling chamber cooled by the cooling line 114, in which the powder is the first plate ( When it comes into contact with the surface of 118) it is solidified and stacked.

As shown in FIGS. 4 and 6, the first plates 118 have a disk shape, and a through hole 116 is formed at the center thereof so that the heating chamber can be fitted thereto. For reference, FIG. 6 is a perspective view illustrating main parts for explaining an installation state of the first plate 118 installed inside the first housing 100.

As shown in the figure, the first plates 118 are installed in a plurality of layers inside the hollow first housing 100, and each of the plurality of perforations 122 is formed. In this case, the diameter of the perforation 122 is preferably formed to be the largest formed on the first plate 118 of the uppermost layer, gradually smaller toward the first plate 118 of the lowermost layer.

In addition, the perforations 122 formed in the first plates 118 are preferably formed asymmetrically, while some powder is deposited on the first plate 118 of the corresponding layer while the powder is lowered down through the perforations 122. , Some of the through-holes 122 formed in the layer to be lowered down again.

As such, the diameters of the perforations 122 formed in the first plates 118 are different from each other, and the reason for forming the perforations 122 formed in the first plates 118 of each layer asymmetrically is composed of a plurality of layers. This is to allow the powder to be laminated in a uniform amount on the first plate 118.

In other words, the reaction by-products, such as unreacted gas flowing out of the heating chamber, are changed into a powder by a cold temperature atmosphere inside the cooling chamber, and if the perforations 122 formed on the first plate 118 of the uppermost layer If the diameter is small, only a small amount of powder will flow down to it, and most of the powder will be deposited on the surface of the first plate 118 on the top layer. In this case, a large amount of powder is deposited only on the surface of the first plate 118 on the uppermost layer, and gradually solidifies, thus blocking the perforations 122 and thus causing the powder to no longer fall to the lower layer.

Therefore, the first plate 118 in the uppermost layer forms a large diameter hole 122 (so that a large amount of powder can be lowered down through the large diameter hole), and the hole having a smaller diameter gradually goes down to the lower layer. Forming 122 allows a large amount of powder to be uniformly deposited over the first plate 118 of the uppermost layer and the first plate 118 of the lowermost layer.

In addition, as shown in FIG. 6, the plurality of first plates 118 are fixedly supported inside the first housing 100 while maintaining a predetermined distance by the supporting bars 120 penetrating them. One end of the supporting bar 120 is fixed to the inner bottom surface of the first housing 100 and the other end is fixed to the bottom surface of the upper plate 100a. In this case, the other end of the supporting bar 120 may be fixed to the bottom surface of the upper plate 100a by welding or the like, and the supporting bar 120 and the first plate 118 may also use welding or a strong adhesive. It is desirable to be fixed without shaking.

Meanwhile, as shown in FIG. 3, the heating chamber is installed inside the first housing 100 to induce a chemical change of the reaction byproduct introduced into the process chamber.

As shown in FIGS. 3 and 5, the heating chamber has a cylindrical second housing 200 inserted into a through hole 116 formed in the first plate 118, with the top open. The reaction by-product inlet pipe 212 extending into the second housing 200 in communication with the first connector 110, and is installed in a plurality of layers inside the second housing 200, through the center Along the reaction by-product inlet pipe 212 while penetrating the second plate 216 of the disc shape through which the reaction by-product inlet pipe 212 passes, and the second plate 216 installed in a plurality of layers. It is comprised including the some heater 218 installed in the periphery.

Here, the second housing 200 is fixed and supported in the interior of the first housing 100 by a fixing piece 220, one end of which is fixed to the bottom surface of the upper plate 100a by screws or welding.

The reaction byproduct inlet pipe 212 is installed in communication with the first connector 110 formed in the upper plate (100a) to extend near the inner bottom surface of the second housing 200, the interior of the second housing 200 There is provided a plurality of layers of disc-shaped second plate 216 formed with a through hole 222 in the center so that the reaction by-product inlet pipe 212 can be fitted.

In addition, each of the second plates 216 is formed with a plurality of perforations 224, like the first plate 118, and flows out from the end of the reaction byproduct inlet pipe 212 through the perforations 224. Reaction by-products, such as unreacted gas, rise upwards.

At this time, the reaction by-products, such as unreacted gas flowing out from the end of the reaction by-product inlet tube 212, since the end of the reaction by-product inlet tube 212 extends to near the inner bottom surface of the second housing 200. Is moved upwards (because the vacuum pump is operating), so that it can be moved upwards without being disturbed by a large amount of reaction byproduct second plates 216. It is preferable to form a perforated 224 having a large diameter in the second plate 216 which is present, and to form a perforated having a diameter that gradually decreases as it goes up the upper layer.

In addition, the second plate 216 may have a wide hole in the circumferential direction instead of the perforation 224. When forming a wide hole in the circumferential direction as described above, most of the reaction by-product flowing out from the end of the reaction by-product inlet pipe 212 will rise upward through the hole.

Meanwhile, the heater 218 installed in the second housing 200 maintains the inside of the second housing 200 in a high temperature atmosphere, thereby chemically reacting the reaction byproducts introduced through the reaction byproduct inlet pipe 212. In order to induce a change in phosphorus, a plurality of bars are formed around the reaction byproduct inlet pipe 212 in a bar shape, one end of which is connected to the outside through the top plate 100a, and the other end is made of 2 extends to the inner bottom surface of the housing 200, it is installed while penetrating the second plate (216).

In addition, the second housing 200 is preferably formed in two layers, as shown in Figure 7 to minimize the effect of the temperature difference between the heating chamber and the cooling chamber. In addition, the bottom surface is formed to be concave in the shape of a funnel so that the unreacted gas introduced through the reaction by-product inlet pipe 212 can be raised to the bottom surface formed concave naturally to rise upwards. At this time, it is preferable that the heater 218 and the second plate 216 are also fixed to each other using welding or a strong adhesive.

Meanwhile, a predetermined space communicating with the second connector 112 is secured between the second housing 200 and the inner bottom surface of the first housing 100, and each of the plurality of perforations 226 is provided in the space. A plurality of third plates 228 are formed. At this time, the third plate 228 is formed in a disc shape like the first and second plates 118 and 216, but unlike the first and second plates 118 and 216, the third plate 228 has a through hole. It does not have.

In general, when the reaction by-product flowing out of the heating chamber in a high temperature atmosphere flows into the cooling chamber which generates a sudden temperature difference, the reaction by-product is converted into a powder form, and part of the reaction by-product is in contact with the surface of the first plate 118 on the top layer When solidified, most of the powder flows down to the lower layer through the plurality of perforations 122 formed in the first plate 118. In this way, a predetermined amount of powder is accumulated in each of the first plates 118 of each layer, and the third plate 228 traps the powder that has not accumulated on the first plate 118 in the above process. In addition, the first plate 228 serves as a filter to prevent powder from being sucked into the vacuum pump. For reference, the third plate 228 is fixed and supported by the supporting bar 120 together with the first plate 118.

Hereinafter will be described the operation of the semiconductor by-product trap device of the present invention configured as described above.

When the deposition or etching process of the thin film is completed, a large amount of reaction by-products such as unreacted gas generated in the deposition and etching process of the thin film are generated in the process chamber (not shown).

As the reaction by-product is driven through the reaction by-product inlet pipe 212 into the second housing 200 constituting the heating chamber as the vacuum pump (not shown) is driven. At this time, since the inside of the second housing 200 by the heater 218 maintains a high temperature atmosphere, the unreacted gas introduced through the reaction byproduct inlet pipe 212 is supplied with the energy required for ionization. Due to the chemical change, in this state is introduced into the cooling chamber via the second plate 216 installed inside the second housing 200.

In this case, since the inside of the first housing 100 is maintained at a low temperature by the cooling line 114 installed on the inner wall surface of the first housing 100 constituting the cooling chamber, the introduced reaction byproducts are formed of solid components. A substance, for example, changes to a powder state, and as soon as the powder comes into contact with the surface of the first plate 118 on the uppermost layer, the solidification progresses and accumulates on the surface of the first plate 118. 118, the powder exited to the lower layer through the perforations 122 is solidified while being in contact with the surface of the first plate 118 of the layer and the rest to the first plate 118 of the layer again It exits through the perforations 122 formed below.

Through such a process, a uniform amount of powder solids are accumulated from the first plate 118 on the uppermost layer to the first plate 118 on the lowermost layer. If there is powder that escapes through the perforations 122 formed in the first plate 118 of the lowest layer, they are accumulated on the third plate 228.

As a result, the reaction by-product generated in the process chamber is introduced into the cooling chamber via the heating chamber, and the reaction by-product introduced into the cooling chamber is changed into a powder-like powder state by the internal cold temperature atmosphere, and thus the changed powder Is uniformly stacked on the surfaces of the first plates 118 installed in a plurality of layers and solidified, and powders not trapped in the first plates 118 are again accumulated on the surfaces of the third plates 228 to the vacuum pump. Prevent powder from entering

Although the preferred embodiments of the present invention have been described above, it is clear that the present invention can use various changes, modifications, and equivalents, and that the above embodiments can be appropriately modified in the same manner. Therefore, the above description does not limit the scope of the present invention defined by the limitations of the following utility model claims.

As described above, the semiconductor by-product trap device of the present invention has the following effects.

A heating chamber is maintained inside the cooling chamber that maintains a high temperature where the phase change of the reaction by-products, such as unreacted gas, which flows from the process chamber. The reaction by-products are rapidly introduced into the cooling chamber in a powder state. Therefore, the reaction chamber in a powder state can be trapped more quickly in the cooling chamber.

In addition, a plurality of perforations are formed asymmetrically in a disk-shaped plate installed in a plurality of layers inside the cooling chamber, and by varying the diameter of the perforations along the height direction, the powder is uniformly accumulated on the plates of the plurality of layers. More powder can be trapped, preventing powder from entering the vacuum pump.

1 is a conceptual diagram of a powder trap apparatus according to the prior art

2 is an external perspective view of a semiconductor by-product trap device of the present invention

3 is a perspective view taken along the line II ′ of FIG. 2;

Figure 4 is a perspective view of the main incision for explaining the trap chamber according to the semiconductor by-product trap device of the present invention

5 is a perspective view of a main portion cutaway for explaining the heating chamber according to the semiconductor by-product trap device of the present invention

Figure 6 is a perspective view of the main portion for explaining the installation state of the first plate installed in the trap chamber according to the semiconductor by-product trap device of the present invention

Figure 7 is a perspective view of the main portion of the heating chamber according to the semiconductor by-product trap device of the present invention

* Description of the symbols for the main parts of the drawings *

100: first housing 200: second housing

110, 112: first and second connectors 114: cooling line

116: through-hole 118: the first plate

120: support bars 122, 224, 226: perforated

212: reaction byproduct inlet pipe 216: second plate

218: heater 220: fixed piece

228: third plate

Claims (10)

In the semiconductor by-product trap device for trapping the reaction by-products generated during deposition or etching of the thin film in the process chamber, A hollow cooling chamber in which a cooling line is installed along the inner wall; And a heating chamber spaced apart from an inner wall of the cooling chamber at a hollow portion of the cooling chamber, and configured to introduce a reaction by-product from the process chamber. The method of claim 1, wherein the cooling chamber, A first housing having a first connector for connection with the process chamber and a second connector for connection with a vacuum pump; It is installed in a plurality of layers inside the first housing, the central portion of the first plate having a through hole enough to fit the heating chamber, And a plurality of supporting bars installed through the first plates to support the first plates. The method of claim 2, wherein the heating chamber, A hollow second housing fitted to a through hole formed in the first plates; A reaction byproduct inlet pipe communicating with the first connector and extending into the second housing; Second plates are installed in a plurality of layers inside the second housing, the through-holes are formed so that the reaction by-product inlet pipe can pass through the center of the second housing, And a plurality of heaters installed around the reaction byproduct inlet pipe. The semiconductor by-product trap apparatus of claim 3, wherein the heater has a bar shape and extends into the heating chamber through an upper end of the cooling chamber. 5. The semiconductor by-product trap apparatus according to claim 3 or 4, wherein the second housing comprises two layers. 6. The semiconductor by-product trap apparatus according to claim 5, wherein the bottom surface of the second housing includes a concave inclined surface. The semiconductor by-product trap device according to claim 3, wherein a plurality of third plates are provided at a lower end of the second housing. 8. The semiconductor by-product trap device according to claim 7, wherein a plurality of perforations are formed in the first, second plates and third plates of the plurality of layers, respectively. 9. The semiconductor by-product trap device according to claim 8, wherein the perforations formed in the plates are formed asymmetrically. 10. The method of claim 8 or 9, wherein the diameter of the perforations formed in the first plate gradually decreases from the uppermost layer to the lower layer, and the diameter of the perforations formed in the second plates gradually increases from the uppermost layer to the lower layer. Semiconductor by-product collection device comprising a.