KR102618825B1 - Air lock device and control system for prevent gas leaking in bays - Google Patents

Abstract

An airlock control system is provided to prevent gas leakage within the bay. The airlock control system includes a transporter that transports a carrier containing wafers between the first bay and the second bay, a travel path that connects the first bay and the second bay and along which the transporter travels, and the first bay and the second bay. an airlock unit arranged along the travel route and surrounding the travel route, an exhaust unit that exhausts the air in the airlock unit, a first door that opens and closes the first entrance connecting the airlock unit and the first bay, the airlock unit and the first bay. A second door that opens and closes the second entrance connecting the two bays, a first pressure sensor located in the first bay, a second pressure sensor located in the second bay, a third pressure sensor located in the airlock, and the first bay By detecting pressure and motion through a first motion detection sensor, and a first pressure detection sensor, a second pressure detection sensor, a third pressure detection sensor, and a first motion detection sensor, the first door, the second door, and the exhaust It includes an airlock control device that controls the unit.

Description

Air lock device and control system for prevent gas leaking in bays}

The present invention relates to an airlock device and control system for preventing gas leakage in a bay.

The process of manufacturing semiconductors, for example, flash memory, includes a process using arsenic (As), so complete blocking of airflow is necessary to prevent safety accidents.

The existing technology to prevent gas leaks is to use a shield to make the bay a closed space. However, when a rail along which a transfer body containing wafers moves is installed, the transfer body can move between bays through the rail. Since the rail and conveyor pass through the bay, an open area is bound to be created, and the bay cannot be made into an enclosed space.

Therefore, there is a need for a technology that can prevent gas leakage while the rails and conveyors connecting the bays exist.

The technical problem to be solved by the present invention is to provide an airlock control system that prevents gas leakage in the bay.

Another technical problem to be solved by the present invention is to provide an airlock device that prevents gas leakage in the bay.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

An airlock control system according to some embodiments of the present invention for achieving the above technical problem includes a transporter for transporting a carrier containing a wafer between the first bay and the second bay, and connecting the first bay and the second bay. It connects the travel path along which the transport vehicle travels, the first bay and the second bay, and surrounds the travel path and is arranged along the travel path. An exhaust part that exhausts the air in the airlock portion connects the airlock portion and the first bay. A first door that opens and closes the first entrance, a second door that opens and closes the second entrance connecting the airlock and the second bay, a first pressure sensor located in the first bay, and a second pressure sensor located in the second bay. pressure through a sensor, a third pressure sensor located in the airlock unit, a first motion sensor located in the first bay, and a first pressure sensor, a second pressure sensor, a third pressure sensor, and a first motion sensor. and an airlock control device that detects motion and controls the first door, the second door, and the exhaust unit.

An airlock device according to some embodiments of the present invention for achieving the above technical problem includes a transporter for transporting a carrier containing a wafer between the first bay and the second bay, and connecting the first bay and the second bay. It includes a travel path along which the transport body travels, an airlock portion connecting the first bay and the second bay, surrounding the travel path, and disposed along the travel path, and an exhaust portion that exhausts air in the airlock portion, and the exhaust portion pressures the airlock portion in the airlock portion. It is configured to be lower than the pressure of the first bay and the second bay.

Specific details of other embodiments are included in the detailed description and drawings.

1 is a block diagram of an airlock control system.
Figure 2 is a side view of an airlock device according to some embodiments.
3 is a perspective view of an airlock device according to some embodiments.
4 is a flow diagram of an airlock control system according to some embodiments.
Figure 5 is a side view of an airlock device according to some embodiments.
Figure 6 is a perspective view of an airlock device according to some embodiments.
7 is a side view of an airlock device according to some embodiments.
Figure 8 is a side view of an airlock device according to some embodiments.

Hereinafter, with reference to the attached drawings, embodiments according to the technical idea of the present invention will be described.

1 is a block diagram of an airlock control system. Figure 2 is a side view of an airlock device according to some embodiments. 3 is a perspective view of an airlock device according to some embodiments. 4 is a flow diagram of an airlock control system according to some embodiments.

1 to 4, an airlock control system 102 according to some embodiments may include an airlock device 100 and an airlock control device 101.

For example, the airlock control device 101 detects the first bay through the first pressure sensor 152, the second pressure sensor 154, and the third pressure sensor 156 of the airlock device 100. The pressure of 192, the pressure of the second bay 194, and the pressure within the airlock unit 156 can be sensed. For example, the airlock control device 101 may detect the motion of the transport body 110 through the first motion detection sensor 170 of the airlock device 100.

The airlock control device 101 can control the airlock device 100. For example, the airlock control device 101 may control the first door 162, the second door 164, and the first exhaust unit 140.

Referring to FIG. 2, the airlock device 100 includes a transport body 110, a travel path 120, an airlock unit 130, a first exhaust unit 140, a first pressure sensor 152, and a second It may include a pressure sensor 154, a third pressure sensor 156, a first door 162, a second door 164, and a first motion sensor 170.

The first bay 192 may be, for example, a separate bay area located within a Fab. The second bay 194 may be, for example, a separate bay area located within a Fab. The first bay 192 and the second bay 194 may be distinguished from each other by a shielding film 190, but the embodiment of the present invention is not limited thereto, and the first bay 192 and the second bay 194 are They may be spaced apart from each other. The shielding film 190 may be located between the first bay 192 and the second bay 194 to block airflow.

The travel path 120 may connect the first bay 192 and the second bay 194 to each other. For example, the travel path 120 may be attached to the ceilings of the first bay 192 and the second bay 194. The travel path 120 may be arranged to pass through the first bay 192 and the second bay 194. That is, the travel path 120 may be disposed to pass through the shielding film 190. The travel path 120 may be, for example, an Overhead Hoist Transfer (OHT) rail, but embodiments of the present invention are not limited thereto.

The transport body 110 may travel along the travel path 120 . The transport body 110 can move between the first bay 192 and the second bay 194 through the travel path 120. The transport body 110 can move between the first bay 192 and the second bay 194. For example, the transfer member 110 may transfer a carrier containing a wafer, but embodiments of the present invention are not limited thereto.

The airlock unit 130 may connect the first bay 192 and the second bay 194 to each other. The airlock unit 130 may be arranged along the travel path 120 while surrounding the travel path 120 . For example, the airlock unit 130 may be in the form of a rectangular parallelepiped with an empty interior as shown in FIG. 3, but the embodiment of the present invention is not limited thereto. The airlock portion 130 may be disposed through the shielding film 190. The airlock unit 130 may have a first entrance 132 in the direction of the first bay 192. The airlock unit 130 may have a second entrance 134 in the direction of the second bay 194. The airlock unit 130 can allow the transport body 110 to pass through only the first inlet 132 and the second inlet 134. The airlock unit 130 can pass airflow only through the first inlet 132 and the second inlet 134.

The first exhaust unit 140 may be connected to the airlock unit 130. Referring to FIG. 3 , the first exhaust unit 140 may include an exhaust port 141, an exhaust passage 143, and an exhaust pump 145. The exhaust port 141 may be located within the airlock portion 130. That is, the exhaust port 141 may be located on the wall inside the airlock portion 130 between the first inlet 132 and the second inlet 134. The exhaust passage 143 may connect the exhaust port 141 and the exhaust pump 145. The exhaust pump 145 can exhaust air introduced through the exhaust passage 143. That is, the air within the airlock unit 130 can be exhausted. Unlike what was described above, the first exhaust port 140 can exhaust air within the airlock unit 130 using a fan.

The first pressure sensor 152 may be located in the first bay 192. In FIG. 2, it is shown as being located near the first inlet 132, but the embodiment of the present invention is not limited thereto. The first pressure sensor 152 may detect the pressure of the first bay 192.

The second pressure sensor 154 may be located in the second bay 194. In FIG. 2, it is shown as being located near the second inlet 134, but the embodiment of the present invention is not limited thereto. The second pressure sensor 154 may detect the pressure of the second bay 194.

The third pressure sensor 156 may be located within the airlock unit 130. In FIG. 2, it is shown as being located at the bottom inside the airlock unit 130, but the embodiment of the present invention is not limited thereto. The third pressure detection sensor 156 can detect the pressure within the airlock unit 130.

The first motion detection sensor 170 may be located in the first bay 192. For example, the first motion detection sensor 170 may be located above the first entrance 132. The first motion detection sensor 170 may detect that the transport body 110 approaches the first entrance 132. 2 and 3, the first motion detection sensor 170 is shown as being located only at the first inlet 132, but the embodiment is not limited thereto, and is also located at the second inlet 134 to detect the transporter ( 110) can be detected.

The first door 162 may be located at the first entrance 132 connecting the first bay 192 and the airlock unit 130. The first door 162 can open and close the first entrance 132. When the first door 162 is opened, the transport body 110 or airflow may enter the airlock unit 130. When the first door 162 is closed, the transport body 110 or airflow cannot enter the airlock unit 130. That is, when the first door 162 is closed, the airflow in the first bay 192 cannot move to the second bay 194.

The second door 164 may be located at the second entrance 134 connecting the second bay 194 and the airlock unit 130. The second door 164 can open and close the second entrance 134. When the second door 164 is opened, the transport body 110 or airflow may enter or exit the airlock unit 130. When the second door 164 is closed, the transport body 110 or airflow cannot enter the airlock unit 130. That is, when the second door 164 is closed, the airflow in the second bay 194 cannot move to the first bay 192.

The first door 162 and the second door 164 may not be opened at the same time. For example, when only the first door 162 is open and the second door 164 is closed, airflows between the first bay 192 and the second bay 194 cannot move to each other. When only the second door 164 is open and the first door 162 is closed, airflows between the first bay 192 and the second bay 194 cannot move to each other. When the first door 162 and the second door 164 are closed, airflows between the first bay 192 and the second bay 194 cannot move to each other.

With reference to FIGS. 2 to 4 , the airlock control system 102 in which the airlock control device 101 controls the airlock device 100 will be described.

The first motion detection sensor 170 is located in the first bay 192 and can detect the transport body 110 approaching the airlock unit 130 along the travel path 120. The airlock control device 101 may determine whether the transport body 110 is located at the first entrance 132 through the first motion detection sensor 170 (S181). If the transport body 110 is not located at the first entrance 132 (No), the airlock control device 101 again sends the transport body (110) to the first entrance 132 through the first motion detection sensor 170. 110) can be determined whether it is located (S181).

When the transport body 110 is located at the first entrance 132 (Yes), the airlock control device 101 determines the pressure within the airlock unit 130 measured using the third pressure detection sensor 156, It can be determined whether the pressure in the first bay 192 measured using the first pressure sensor 152 is higher (S182).

If the pressure within the airlock unit 130 is higher than the pressure of the first bay 192 (Yes) (S182), the airlock control device 101 operates the first exhaust unit 140 to increase the pressure within the airlock unit 130. It can be made lower than the pressure of the first bay 192 (S183). As a result, when the pressure within the airlock unit 130 becomes less than the pressure of the first bay 192, the first door 162 is opened, and the first door 162 can be closed after entering the transport body 110 ( S184).

If the pressure within the air lock unit 130 is less than the pressure of the first bay 192 (No) (S182), the first door 162 may be opened, and the first door 162 may be closed after entering the transport body 110. There is (S184).

When the transport body 110 enters the airlock unit 130, the airlock control device 101 detects the second pressure as the pressure inside the airlock unit 130 measured using the third pressure detection sensor 156. It can be determined whether the pressure of the second bay 194 measured using the sensor 154 is higher (S185).

If the pressure within the airlock unit 130 is higher than the pressure of the second bay 194 (Yes) (S185), the airlock control device 101 operates the first exhaust unit 140 to increase the pressure within the airlock unit 130. It can be lowered than the pressure of the second bay 194 (S186). As a result, when the pressure within the airlock unit 130 becomes less than the pressure of the second bay 194, the second door 164 may be opened, and after the transport body 110 exits, the second door 164 may be closed. There is (S187).

If the pressure within the air lock unit 130 is less than the pressure of the second bay 194 (No) (S185), the second door 164 is opened, and after the transport body 110 exits, the second door 164 is opened. Can be closed (S187).

Since the first inlet 132 and the second inlet 134 are not opened at the same time, at least one inlet of the airlock portion 130 connecting the first bay 192 and the second bay 194 is always closed to prevent airflow. You can block it.

When the transporter 110 enters, the airlock control device 101 uses the first pressure detection sensor 152, the third pressure detection sensor 156, and the first exhaust unit 140 to form the airlock unit 130. ) can be maintained lower than the pressure in the first bay 192. Accordingly, the airflow within the airlock unit 130 may not flow out into the first bay 192. Additionally, the airflow in the first bay 192 may be exhausted through the first exhaust unit 140.

When the transport body 110 leaves the airlock unit 130, the airlock control device 101 uses the second pressure detection sensor 154, the third pressure detection sensor 156, and the first exhaust unit 140. Thus, the pressure within the airlock unit 130 can be maintained lower than the pressure of the second bay 194. Accordingly, the airflow within the airlock unit 130 may not leak into the second bay 194. Additionally, the airflow in the second bay 194 may be exhausted through the first exhaust unit 140.

Hereinafter, an airlock device according to some embodiments will be described with reference to FIGS. 5 and 6. Descriptions overlapping with FIGS. 2 to 4 will be omitted and description will focus on differences.

Figure 5 is a side view of an airlock device according to some embodiments. Figure 6 is a perspective view of an airlock device according to some embodiments.

Referring to FIGS. 5 and 6, the airlock device 200 includes a transport body 210, a travel path 220, an airlock unit 230, a first exhaust unit 240, and a first pressure detection sensor 252. , may include a second pressure sensor 254 and a third pressure sensor 256.

Unlike the airlock device 100 in the embodiments of FIGS. 2 to 4 , the first door 162 and the second door 164 may not be disposed in the airlock device 200.

The transport body 210 may move by traveling on the travel path 220 between the first bay 292 and the second bay 294. The transport body 210 may travel between the first bay 292 and the second bay 294 through the airlock unit 230.

The first exhaust unit 240 may be connected to the airlock unit 230. The exhaust port 241 of the first exhaust unit 240 may be located within the airlock unit 230. That is, the exhaust port 241 may be located on the wall inside the airlock portion 230 between the first inlet 232 and the second inlet 234.

The first exhaust unit 240 may maintain the pressure within the airlock unit 230 lower than the pressure of the first bay 292 and the second bay 294. That is, the first exhaust unit 240 can always maintain the pressure within the airlock unit 230 at negative pressure.

The first exhaust unit 240 lowers the pressure in the airlock unit 230 measured by the third pressure detection sensor 256 to a lower level than the pressure in the first bay 292 measured by the first pressure detection sensor 252. It can be maintained. The first exhaust unit 240 lowers the pressure in the airlock unit 230 measured by the third pressure detection sensor 256 to a lower level than the pressure in the second bay 294 measured by the second pressure detection sensor 254. It can be maintained.

Due to the operation of the first exhaust unit 240, the airflow in the first bay 292 may not move to the second bay 294. Due to the operation of the first exhaust unit 240, the airflow in the second bay 294 may not move to the first bay 292. That is, airflows between the first bay 292 and the second bay 294 may not move toward each other.

Hereinafter, an airlock device according to some embodiments will be described with reference to FIG. 7. Descriptions that overlap with those of FIGS. 5 and 6 will be omitted and the description will focus on the differences.

Figure 7 is a side view of an airlock device according to some embodiments.

Referring to FIG. 7, the airlock device 200 includes a first exhaust unit 240, a second exhaust unit 240a, a third exhaust unit 240b, and a fourth exhaust unit disposed along the airlock unit 230. It may include (240c), a fifth exhaust unit (240d), a sixth exhaust unit (240e), a seventh exhaust unit (240f), and an eighth exhaust unit (240g). First exhaust unit 240, second exhaust unit 240a, third exhaust unit 240b, fourth exhaust unit 240c, fifth exhaust unit 240d, sixth exhaust unit 240e, seventh exhaust unit 240 The exhaust unit 240f and the eighth exhaust unit 240g may be disposed attached to the airlock unit 230 along the airlock unit 230 from the first inlet 232 to the second inlet 234. Although eight exhaust units are shown in FIG. 7, the embodiment of the present invention is not limited thereto and may include a plurality of exhaust units.

If a plurality of exhaust units are disposed along the airlock unit 230, airflow from the first bay 292 may not leak into the second bay 294. Additionally, airflow from the second bay 294 may not leak into the first bay 292.

If a plurality of exhaust units are disposed along the airlock unit 230, there may be no delay in the transfer body 210 passing through the airlock unit 230. In other words, the transport body 210 can smoothly pass through the airlock unit 230 to prevent a productivity bottleneck.

Hereinafter, an airlock device according to some embodiments will be described with reference to FIG. 8. Descriptions that overlap with those of FIGS. 5 and 6 will be omitted and the description will focus on the differences.

Figure 8 is a side view of an airlock device according to some embodiments.

Referring to FIG. 8, the airlock device 200 may include a first exhaust unit 240 and a ninth exhaust unit 240h disposed in the airlock unit 230.

The ninth exhaust unit 240h may be disposed in the first upper part 236 of the airlock unit 230. However, the embodiment of the present invention is not limited to this, and a plurality of ninth exhaust units 240h may be arranged surrounding the airlock unit 230.

If a plurality of exhaust units are disposed surrounding the airlock unit 230, there may not be a delay time for the transport body 210 to pass through the airlock unit 230. In other words, the transport body 210 can smoothly pass through the airlock unit 230 to prevent a productivity bottleneck. Additionally, the airlock portion 230 does not need to be extended, thereby saving space.

Although embodiments of the present invention have been described above with reference to the attached drawings, the present invention is not limited to the above embodiments and can be manufactured in various different forms, and can be manufactured in various different forms by those skilled in the art. It will be understood by those who understand that the present invention can be implemented in other specific forms without changing its technical spirit or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

100: airlock device 101: airlock control device
102: Airlock control system 130: Airlock unit
140: first exhaust unit 192: first bay
194: second bay 200: airlock device

Claims (10)

A transfer member that transfers a carrier containing a wafer between the first bay and the second bay;
a travel path connecting the first bay and the second bay, along which the transport vehicle travels;
an airlock unit connecting the first bay and the second bay, surrounding the travel path, and disposed along the travel path;
an exhaust unit that exhausts air within the airlock unit;
a first door that opens and closes a first entrance connecting the airlock unit and the first bay;
a second door opening and closing a second entrance connecting the airlock unit and the second bay;
a first pressure sensor located in the first bay;
a second pressure sensor located in the second bay;
A third pressure sensor located within the airlock unit;
a first motion detection sensor located in the first bay; and
Detect pressure and motion through the first pressure sensor, the second pressure sensor, the third pressure sensor, and the first motion sensor to control the first door, the second door, and the exhaust unit. An air lock control system including an air lock control device that operates. According to clause 1,
An airlock control system in which the first door and the second door are not opened at the same time. According to clause 1,
When the transport object is detected by the first motion detection sensor,
When the pressure measured by the third pressure sensor is lower than the pressure measured by the first pressure sensor, the first door is opened,
When the pressure measured by the third pressure sensor is greater than the pressure measured by the first pressure sensor, the first exhaust unit operates so that the pressure measured by the third pressure sensor increases with the pressure measured by the first pressure sensor. An airlock control system in which the first door opens after the pressure measured by . According to clause 3,
When the pressure measured by the third pressure sensor is lower than the pressure measured by the second pressure sensor, the second door is opened,
When the pressure measured by the third pressure sensor is greater than the pressure measured by the second pressure sensor, the first exhaust unit operates so that the pressure measured by the third pressure sensor is increased by the second pressure sensor. An airlock control system in which the second door opens after the pressure measured by . A transfer member that transfers a carrier containing a wafer between the first bay and the second bay;
a travel path connecting the first bay and the second bay, along which the transport vehicle travels;
an airlock unit connecting the first bay and the second bay, surrounding the travel path, and disposed along the travel path; and
It includes an exhaust unit that exhausts air within the airlock unit,
The exhaust unit is configured to lower the pressure within the airlock unit than the pressure of the first bay and the second bay. According to clause 5,
An airlock device wherein the exhaust unit includes an exhaust port, an exhaust passage, and an exhaust pump, and the exhaust port is located within the airlock unit. According to clause 6,
An airlock device in which a plurality of exhaust ports are located in the airlock unit along the travel path. According to clause 6,
An airlock device in which a plurality of exhaust ports are located in the airlock portion while surrounding the travel path. According to clause 5,
An airlock device further comprising a first pressure sensor located in the first bay, a second pressure sensor located in the second bay, and a third pressure sensor located in the airlock unit. According to clause 9,
The exhaust unit is configured to lower the pressure measured by the third pressure sensor than the pressure measured by the first pressure sensor and the second pressure sensor.