KR102377504B1 - Fabrication System for Semiconductor Wafer and Control Method Thereof - Google Patents

Abstract

The semiconductor wafer manufacturing system according to an embodiment of the present technology is connected to a storage device in which a wafer carrier is mounted, and supplies a purge gas provided from a supply tank through a supply pipe to the inside of the wafer carrier, and reduces the pressure inside the wafer carrier. A discharge pipe connected to the discharge nozzle and the supply unit having a measuring pressure sensor is directly connected to the recovery tank, and may be configured to include a discharge unit configured to discharge the purge gas inside the wafer carrier to the recovery tank.

Description

Semiconductor Wafer Manufacturing System and Control Method Thereof

The present invention relates to a semiconductor manufacturing facility, and more particularly, to a wafer manufacturing system and control method.

In the semiconductor manufacturing process, a wafer is produced, and the produced wafer is transferred to the next process facility to manufacture a semiconductor package. At this time, the produced wafers are sequentially transferred to the next process facility as needed after waiting for a certain amount of time in a designated space.

When the wafer is transferred through each process step, it must be able to maintain the cleanliness of the wafer from gases, chemicals, and other environments that come into contact with the wafer. A standardized wafer carrier may be used to ensure the cleanliness level of the wafer and to improve the convenience of transporting the wafer.

An example of a wafer carrier is a Front Opening Unified POD (FOUP). The wafers stored in the FOUP are transferred to each process device through the STB (Side Track Buffer) during transfer.

Since the STB is installed on the rail for guiding the STB on the ceiling of the factory, space utilization can be improved and the moving distance between processes can be shortened.

In order to remove contamination on the wafer in the wafer carrier stored in the STB, a process of forcibly exhausting the purge gas inside the wafer carrier after injecting the purge gas into the wafer carrier is required.

The wafer carrier purge device may be provided in the STB, a supply unit for supplying a purge gas provided from the purge gas supply tank into the wafer carrier through a valve, a filter, and a nozzle, and a nozzle and a filter for the purge gas injected into the wafer carrier , it may include a discharge unit for discharging to the purge gas recovery tank through a flow meter.

However, during the purge process of the wafer in the wafer carrier seated in the STB, clogging occurs in the exhaust filter by fume, and periodic maintenance is required to solve this, and methods such as multiplexing filters can think of

However, even when a plurality of filters are installed, the filter clogging phenomenon cannot be fundamentally solved, and as a plurality of filters and flow meters are provided on the discharge side, the investment cost for the purge device is inevitably increased.

In addition, external air may be introduced into the wafer carrier due to a defect in the wafer carrier itself, and accordingly, temperature and humidity control inside the wafer carrier may be difficult, and errors may occur during the purge process due to excessive discharge of the purge gas.

Embodiments of the present technology may provide a semiconductor wafer manufacturing system and control method capable of detecting a defect in a wafer carrier.

Embodiments of the present technology may provide a semiconductor wafer manufacturing system and control method capable of purging a wafer carrier with a simple configuration that omits a configuration that may cause errors or defects in the purging device.

The semiconductor wafer manufacturing system according to an embodiment of the present technology is connected to a storage device in which a wafer carrier is mounted, and supplies a purge gas provided from a supply tank through a supply pipe to the inside of the wafer carrier, a supply unit having a pressure sensor for measuring the pressure; and a discharge part having a discharge pipe connected to the discharge nozzle directly connected to the recovery tank, and configured to discharge the purge gas inside the wafer carrier to the recovery tank.

The semiconductor wafer manufacturing system control method according to an embodiment of the present technology is connected to a storage device in which a wafer carrier is mounted, and supplies a purge gas provided from a supply tank through a supply pipe into the wafer carrier, and the wafer carrier A semiconductor configured to include a supply unit having a pressure sensor for measuring internal pressure, and a discharge unit connected to the discharge nozzle and directly connected to the recovery tank, and configured to discharge the purge gas inside the wafer carrier to the recovery tank As a control method for a wafer manufacturing system, it may be configured to include the step of determining whether the wafer carrier is defective according to a pressure measurement result inside the wafer carrier provided from the pressure sensor.

According to the present technology, it is possible to immediately check whether there is a defect in the wafer carrier seated in the storage device and to deal with it.

In addition, it is possible to purge the wafer carrier with a simple configuration by estimating the exhaust amount of the purge gas only by using a pressure measuring device provided on the side of the input terminal that supplies the purge gas to the inside of the wafer carrier.

1 is a block diagram of a semiconductor wafer manufacturing system according to an embodiment.
2 is a block diagram of a purge device according to an embodiment.
3 is a flowchart illustrating a control method of a semiconductor wafer manufacturing system according to an exemplary embodiment.
4 is a flowchart illustrating a control method of a semiconductor wafer manufacturing system according to an exemplary embodiment.
5 is a block diagram of a storage device according to an embodiment.
6 is a block diagram of a wireless transceiver according to an embodiment.

Hereinafter, embodiments of the present technology will be described in more detail with reference to the accompanying drawings.

1 is a block diagram of a semiconductor wafer manufacturing system according to an embodiment.

Referring to FIG. 1 , a semiconductor wafer manufacturing system 10 according to an embodiment may include a storage device 110 , a purge device 120 , and a controller 130 , and further includes an input/output device 140 . can do.

The storage device 110 may include at least one seating part 111 on which the wafer carrier 113 is mounted.

In one embodiment, the storage device 110 may be a buffer that temporarily stores the wafer carrier while the transport vehicle transports the wafer carrier 113 .

In one embodiment, the storage device 110 may be a ceiling-mounted buffer, for example, may be a STB (Side Track Buffer).

The wafer carrier 113 may be a container capable of accommodating and transporting a wafer therein. The wafer carrier 113 may be, for example, a FOUP, but is not limited thereto.

The purge device 120 may be a device for removing impurities from a wafer in the wafer carrier 113 seated on the seating portion 111 of the storage device 110 . In an embodiment, the purge device 120 may supply a purge gas into the wafer carrier 113 through a supply unit and discharge the purge gas in the wafer carrier 113 through a discharge unit.

In one embodiment, the purge gas may be an inert gas and may be selected from the group comprising nitrogen, argon, and the like.

The controller 130 controls the overall operation of the semiconductor wafer manufacturing system 10 .

The input/output device 140 receives control commands and parameters for the semiconductor wafer manufacturing system 10 , and provides them to the controller 130 , so that the operation status of the semiconductor wafer manufacturing system 10 , processing results, etc. can be output. can be configured.

In an embodiment, the semiconductor wafer manufacturing system 10 performs a purging process by the purge device 120 after the wafer carrier 113 is seated on the seating part 111 of the storage device 110 before performing a purging process on the wafer carrier. It is possible to detect a defect for (113). To this end, the purge device 120 may include a pressure sensor on the supply side, and operate the discharge unit before supplying the purge gas. The pressure inside the wafer carrier 113 as the exhaust is made to the outside by the discharge unit may be measured by a pressure sensor. The pressure inside the wafer carrier 113 may be measured differently depending on whether a device defect exists in the wafer carrier 113 , and the controller 130 detects the defect of the wafer carrier 113 itself according to the pressure measurement result. can be detected.

In an embodiment, the semiconductor wafer manufacturing system 10 may measure the pressure inside the wafer carrier 113 through a pressure sensor that may be provided on the supply side when performing a purge process on the wafer carrier 113 . there is. In addition, the controller 130 may predict the amount of purge gas discharged through the discharge unit according to the pressure measurement result.

2 is a block diagram of a purge device according to an embodiment.

Referring to FIG. 2 , the purge device 120 according to an embodiment may include a supply unit 121 and a discharge unit 123 .

First, the supply unit 121 may include a supply valve 1211 , a supply flow meter 1213 , a filter 1215 , a supply nozzle 1217 , and a pressure sensor 1219 .

The supply valve 1211 may be installed in the supply pipe 1210 extending from the supply tank to open and close the flow path of the purge gas.

The supply flow meter 1213 may be configured to measure a flow rate of the purge gas flowing through the supply pipe 1210 through the supply valve 1211 .

The filter 1215 may be configured to filter foreign matter from the purge gas flowing through the supply conduit 1210 through the supply flow meter 1213 .

The supply nozzle 1217 may be configured to provide a purge gas that passes through the filter 1215 and flows through the supply pipe 1210 into the wafer carrier 113 seated on the seating part 111 .

The pressure sensor 1219 may be installed between the filter 1215 and the supply nozzle 1217 , and may be configured to measure the supply pressure of the purge gas flowing through the supply pipe 1210 . The supply pressure of the gas supplied through the supply nozzle 1217 may represent the pressure inside the wafer carrier 113 , and thus the internal pressure of the wafer carrier 113 may be substantially measured through the pressure sensor 1219 . there is.

The discharge part 123 includes a discharge pipe 1230 connected to the discharge nozzle 1231, and the discharge pipe 1230 may be configured to be directly connected to the recovery tank.

That is, in the present technology, the discharge unit 123 includes only the discharge nozzle 1231 and does not include other components such as a filter or a discharge flow meter. Accordingly, the clogging of the filter can be fundamentally prevented when discharging the purge gas, and maintenance/repair of the discharge-side filter is not required at all.

In addition, in the present technology, the pressure in the wafer carrier 113 is measured through a pressure sensor 1219 that may be provided on the supply unit 121 side, and based on this, the wafer carrier 113 not only detects a defect, The purge gas emissions can be predicted. Accordingly, it is possible to predict and control the purge gas discharge amount without installing an exhaust flow meter.

By simplifying the configuration of the discharge unit 123, the maintenance/repair process is greatly reduced, and various advantages such as reduction of equipment cost and downsizing of manufacturing facilities can be obtained.

Meanwhile, although not shown in FIG. 2 , a supply pump and a discharge pump are provided in each of the supply unit 121 and the discharge unit 123 to enable supply and discharge of the purge gas.

After the wafer carrier 113 is seated on the seating part 111 of the storage device 110 , the controller 130 controls the purge device 120 to control only the discharge part 123 side before the supply of the purge gas starts. can make it work

When there is no physical defect in the wafer carrier 113, the pressure inside the wafer carrier 113 measured by the pressure sensor 1219 may be a preset first pressure, and if there is a defect, the inside of the wafer carrier 113 The pressure of may be a second pressure that is out of a preset value. Accordingly, the controller 130 may determine whether a defect has occurred in the wafer carrier 113 based on the pressure sensing result provided from the pressure sensor 1219 .

When the controller 130 determines that a defect has occurred in the wafer carrier 113 , the controller 130 may output the fact that a defect has occurred through the input/output device 140 . The fact of occurrence of a defect may be output in a manner such as, for example, an alarm or lighting, but is not limited thereto.

Meanwhile, as the purge process of the wafer carrier 113 is started, the controller 130 may receive the sensing result of the pressure sensor 1219 of the purge device 120 to estimate the amount of discharge. The pressure sensor 1218 may provide a pressure sensing result to the controller 130 continuously or at preset intervals.

The purge gas supplied through the supply unit 121 should be completely discharged through the discharge unit 123 . To this end, the pumping unit installed in the discharge unit 123 forcibly discharges the purge gas inside the wafer carrier 113 to the recovery tank at a preset flow rate. Accordingly, the pressure inside the wafer carrier 113 may be maintained within a predetermined range. If the discharge unit 123 side discharge is excessive or insufficient, the pressure inside the wafer carrier 113 will be out of a reliable range.

Accordingly, the controller 130 may predict the discharge amount of the purge gas based on the sensing result provided from the pressure sensor 1219 and, when the discharge amount is excessive or insufficient, control the purge device 120 to decrease or increase the discharge amount. .

The purge process may be performed when it is confirmed that the wafer carrier 113 has no defects. By determining whether or not the wafer carrier 113 is defective based on the pressure inside the wafer carrier 113 measured by the pressure sensor 1219, a factor that may cause an error before performing the purge process can be removed in advance. .

In addition, since the discharge of the purge gas is predicted only by the pressure sensor 1219 , there is no need to install a filter or a flow meter on the discharge unit 123 side, so that the purge device can be implemented with a simple configuration.

3 is a flowchart illustrating a method of controlling a semiconductor wafer manufacturing system according to an exemplary embodiment.

Referring to FIG. 3 , the wafer carrier 113 transferred by the transfer device may be seated on the seating unit 111 in the storage device 110 .

When the controller 130 detects that the wafer carrier 113 is seated on the seating unit 111 , the controller 130 controls the purge device 120 to operate the discharge unit 123 ( S103 ).

That is, in a state in which the purge gas is not supplied, the pump on the side of the discharge unit 123 is driven so that the gas inside the wafer carrier 113 is discharged toward the recovery tank through the discharge nozzle 1231 and the discharge pipe 1230 .

Accordingly, the pressure inside the wafer carrier 113 is changed, and the pressure sensor 1219 may provide a result of sensing the pressure inside the wafer carrier 113 to the controller 130 ( S105 ).

The controller 130 may determine whether leakage occurs in the wafer carrier 113 based on the pressure sensing result provided from the pressure sensor 1219 ( S107 ).

As a result of the determination, if there is no leakage, the purge process (S109) may be performed, and if it is confirmed as a defect due to the leakage, an alarm may be output (S111).

When there is no physical defect in the wafer carrier 113, the pressure inside the wafer carrier 113 measured by the pressure sensor 1219 may be a preset first pressure, and if there is a defect, the inside of the wafer carrier 113 The pressure of may be a second pressure that is out of a preset value. Accordingly, the controller 130 may determine whether a defect has occurred in the wafer carrier 113 based on the pressure sensing result provided from the pressure sensor 1219 .

4 is a flowchart illustrating a control method of a semiconductor wafer manufacturing system according to an exemplary embodiment.

Referring to FIG. 4 , the controller 130 controls the purge device 120 to supply a purge gas into the wafer carrier 113 through the supply unit 121 ( S201 ). In addition, the controller 130 controls the purge device 120 to discharge the purge gas in the wafer carrier 113 through the discharge unit 123 ( S203 ).

The supply unit 121 supplies a predetermined amount of purge gas to the wafer carrier 113 side, and the amount of the supplied purge gas may be measured using a supply flow meter 1213 . On the other hand, the purge gas in the wafer carrier 113 must be completely discharged from the discharge unit 123 side, and the purge gas inside the wafer carrier 113 is discharged at a preset flow rate through a pumping unit installed on the discharge unit 123 side. It is forcibly discharged to the recovery tank. Accordingly, the pressure inside the wafer carrier 113 may be maintained within a predetermined range.

If the discharge unit 123 side discharge is excessive or insufficient, the pressure inside the wafer carrier 113 will be out of a reliable range.

Therefore, in the present technology, the pressure inside the wafer carrier 113 may be sensed through the pressure sensor 1219 while the purge gas is supplied and the pump is forcibly discharged (S205). Then, the controller 130 may predict the amount of purge gas emission based on the sensing result provided from the pressure sensor 1219 ( S207 ).

If the discharge amount of the purge gas is excessive or insufficient, the controller 130 may control the purge device 120 to decrease or increase the discharge amount (S209).

The purge process shown in FIG. 4 may be performed after the wafer carrier 113 is seated in the storage device 110 .

In another embodiment, the purge process may be performed after the wafer carrier 113 is seated in the storage device 110 and after checking whether a defect has occurred in the wafer carrier 113 . For example, a defect in the wafer carrier 113 is checked by the process of FIG. 3 , and when no defect occurs, a purge process as shown in FIG. 4 may be performed. In this case, since the discharging process through the discharging unit 123 has already been started when checking whether the wafer carrier 113 is defective, the discharging process ( S203 ) of the purge gas in the purge process may be omitted.

Meanwhile, the semiconductor wafer manufacturing system 10 may support a more efficient process by managing information on each of the wafer carriers 113 stored in the storage device 110 .

To this end, a system capable of collecting and managing information on each of the wafer carriers 113 may be considered.

5 is a block diagram of a storage device according to an embodiment.

In this embodiment, the wafer carrier 115 may include the first wireless transceiver 210 , and the storage device 110 - 1 may include the second wireless transceiver 220 .

The second wireless transceiver 220 may be installed at a designated location of the storage device 110 - 1 , and wirelessly transmits and receives control signals and data to and from the first wireless transceiver 210 attached to the wafer carrier 115 . configured to do so.

In an embodiment, the first wireless transceiver 210 may be an RFID tag, and the second wireless transceiver 220 may be an RFID reader, but is not limited thereto.

In an embodiment, the first wireless transceiver 210 may communicate with the second wireless transceiver 220 through a wireless transceiver module, and information about the wafer carrier 115, for example, a current location of the wafer carrier , the number of received wafers, the process status of the received wafers, etc. can be received and stored through the wireless transmission/reception module.

The second wireless transceiver 220 may communicate with the first wireless transceiver 210 through a wireless transceiver module, and may be configured to communicate with the controller 130 . In addition, information on the wafer carrier 115 may be received and stored from the first wireless transceiver 210 , and data to be stored in the first wireless transceiver 210 may be transmitted to the first wireless transceiver 210 . can

As the wireless transceivers 210 and 220 are respectively attached to the wafer carrier 115 and the storage device 110 - 1 , management of the wafer carrier 115 in which a defect is detected may be easier. For example, when a defect is detected, the controller 130 may transmit and store defect occurrence-related data to the first wireless transceiver 210 through the second wireless transceiver 220 .

In addition, information on various matters occurring during the process may be stored in a database for each wafer carrier 115 and referred to in a subsequent process.

6 is a block diagram of a wireless transceiver according to an embodiment.

Referring to FIG. 6 , the first wireless transceiver 210 may include a transceiver 213 that wirelessly transmits and receives a signal through an antenna 211 , a signal processing unit 215 , and a storage unit 217 .

The signal processing unit 215 may convert an analog signal received by the transceiver 213 into a digital signal or convert digital data to be transmitted through the transceiver 213 into an analog signal.

The storage unit 217 may store data provided through the signal processing unit 215 , and may provide data corresponding to a request of the signal processing unit 215 to the signal processing unit 215 .

The second wireless transceiver 220 may include a transceiver 223 for wirelessly transmitting and receiving a signal through the antenna 221 , a signal processing unit 225 , and a storage unit 227 .

The signal processing unit 225 may convert an analog signal received by the transceiver 223 into a digital signal or convert digital data to be transmitted through the transceiver 223 into an analog signal. In addition, the signal processing unit 225 is configured to communicate with the controller 130 , and may access the first wireless transceiver 210 under the control of the controller 130 .

The storage unit 227 may store data provided through the signal processing unit 225 , and may provide data corresponding to a request of the signal processing unit 225 to the signal processing unit 225 .

It goes without saying that the first and second wireless transmission/reception devices 210 and 220 shown in FIG. 6 are merely exemplary and may be appropriately selected from devices capable of wirelessly transmitting and receiving signals in a short distance.

As such, those skilled in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential characteristics thereof. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

10: semiconductor wafer manufacturing system
110, 110-1: storage device
111: seating part
113, 115: wafer carrier
120: purge device
121: supply
123: discharge part
210: first wireless transceiver
220: second radio transceiver

Claims (14)

It is connected to the storage device in which the wafer carrier is seated,
a supply unit supplying a purge gas provided from a supply tank through a supply pipe to the inside of the wafer carrier and having a pressure sensor for measuring a pressure inside the wafer carrier; and
a discharge unit including a discharge nozzle provided inside the wafer carrier and a discharge pipe directly connecting the discharge nozzle and the recovery tank, the discharge unit configured to discharge the purge gas inside the wafer carrier to the recovery tank;
A semiconductor wafer manufacturing system configured to include a. ◈Claim 2 was abandoned when paying the registration fee.◈ The method of claim 1,
The supply unit may include: a supply valve installed in the supply pipe extending from the supply tank and configured to open and close a flow path of the purge gas;
a supply flow meter configured to measure a flow rate of a purge gas flowing through the supply pipe through the supply valve;
a filter configured to filter foreign matter from the purge gas passing through the supply flow meter and flowing through the supply conduit;
a supply nozzle configured to provide the purge gas flowing through the supply tube through the filter into the wafer carrier; and
a pressure sensor installed between the filter and the supply nozzle and configured to measure a pressure inside the wafer carrier from a supply pressure of the purge gas flowing through the supply pipe;
A semiconductor wafer manufacturing system configured to include a. ◈Claim 3 was abandoned when paying the registration fee.◈ The method of claim 1,
The semiconductor wafer manufacturing system configured to further include a controller for determining whether the wafer carrier is defective according to a result of measuring the pressure inside the wafer carrier provided from the pressure sensor. ◈Claim 4 was abandoned when paying the registration fee.◈ 4. The method of claim 3,
The controller is configured to determine whether the wafer carrier is defective based on a measurement result of the pressure sensor in a state in which the discharge unit is driven before the purge gas is supplied into the wafer carrier through the supply unit. system. ◈Claim 5 was abandoned when paying the registration fee.◈ The method of claim 1,
The semiconductor wafer manufacturing system configured to further include a controller for estimating the discharge amount of the purge gas through the discharge unit according to a pressure measurement result inside the wafer carrier provided from the pressure sensor. ◈Claim 6 was abandoned when paying the registration fee.◈ 6. The method of claim 5,
The controller is configured to predict an amount of the purge gas to be discharged based on a pressure measurement result provided from the pressure sensor as the purge gas is supplied through the supply unit and the purge gas is discharged through the discharge unit, and the purge gas A semiconductor wafer manufacturing system, configured to control the discharge unit according to a prediction result of the discharge amount. ◈Claim 7 was abandoned at the time of payment of the registration fee.◈ The method of claim 1,
The storage device is a semiconductor wafer manufacturing system consisting of a ceiling-mounted buffer. ◈Claim 8 was abandoned when paying the registration fee.◈ The method of claim 1,
The wafer carrier is a semiconductor wafer manufacturing system consisting of a FOUP (Front Opening Unified POD; FOUP). ◈Claim 9 was abandoned at the time of payment of the registration fee.◈ The method of claim 1,
and wherein the wafer carrier includes a first wireless transceiver and the storage device includes a second wireless transceiver in communication with the first wireless transceiver. ◈Claim 10 was abandoned when paying the registration fee.◈ 10. The method of claim 9,
The first wireless transceiver is an RFID reader, and the second wireless transceiver is an RFID tag. A supply unit connected to a storage device in which the wafer carrier is seated, and supplying a purge gas provided from a supply tank through a supply pipe to the inside of the wafer carrier, and having a pressure sensor for measuring the pressure inside the wafer carrier, and the A semiconductor wafer comprising: a discharge nozzle provided inside the wafer carrier; and a discharge pipe directly connecting the discharge nozzle and the recovery tank; A control method for a manufacturing system, comprising:
and determining whether the wafer carrier is defective according to a result of measuring the pressure inside the wafer carrier provided from the pressure sensor. ◈Claim 12 was abandoned when paying the registration fee.◈ 12. The method of claim 11,
Determining whether the defect may include: driving the discharge unit before the purge gas is supplied into the wafer carrier through the supply unit;
receiving a pressure measurement result in the wafer carrier from the pressure sensor; and
determining whether the wafer carrier is defective according to whether the pressure measurement result is included within a preset range;
A control method of a semiconductor wafer manufacturing system configured to include a. ◈Claim 13 was abandoned when paying the registration fee.◈ 12. The method of claim 11,
The control method of the semiconductor wafer manufacturing system configured to further include the step of estimating the discharge amount of the purge gas through the discharge unit according to a pressure measurement result inside the wafer carrier provided from the pressure sensor. ◈Claim 14 was abandoned at the time of payment of the registration fee.◈ 14. The method of claim 13,
The predicting of the discharge amount may include: supplying the purge gas through the supply unit;
discharging the purge gas through the discharge unit;
estimating the discharge amount of the purge gas based on the pressure measurement result provided from the pressure sensor; and
controlling the discharge unit according to a result of predicting the discharge amount of the purge gas;
A control method of a semiconductor wafer manufacturing system configured to include a.

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