KR102593445B1 - Apparatus for supplying material source and gas supply control method - Google Patents

Abstract

The present invention relates to a gas supply device, and more specifically, to a gas supply device that vaporizes a liquid raw material, converts it into gaseous raw material gas, and supplies it to a process chamber.
The present invention is a gas supply device that supplies process gas to a process chamber 10 where substrate processing is performed, and includes a first supply passage 110 through which process gas is supplied, and a second supply communicating with the process chamber 10. A piping unit 100 including a flow passage 120 and a plurality of branch supply passages 130 branched between the first and second supply passages 110 and 120; A plurality of flow control valves 200 each installed to form part of a plurality of branch supply passages 130 and controlling the flow rate of the process gas by controlling the opening and closing of the branch supply passage 130 using the elongation of the piezoelectric element. ) and; In order to measure the flow rate of the process gas supplied to the process chamber 10, at least one measurement sensor installed between the plurality of flow control valves 200 and the process chamber 10 and the measurement value of the measurement sensor are used. a flow rate measurement unit including a flow rate calculation unit that calculates the flow rate of the process gas; A gas supply device including a control unit that controls a plurality of flow control valves 200 to supply the flow rate of the process gas supplied to the process chamber 10 within a preset range according to the flow rate of the process gas measured through the flow measurement unit. Begin.

Description

Gas supply device and gas supply control method {Apparatus for supplying material source and gas supply control method}

The present invention relates to a gas supply device and a gas supply control method, and more specifically, to a gas supply device and a gas supply control method for vaporizing liquid raw materials, converting them into gaseous process gas, and supplying it to a process chamber.

In general, PECVD (Plasma enhanced chemical vapor deposition) requires the formation of plasma to deposit different types of thin films. In particular, in the case of some raw materials, the liquid raw material is vaporized and converted into gaseous raw material gas to be transported to the process chamber. must be supplied.

For this purpose, the substrate processing device includes a chamber in which substrate processing is performed, and a gas supply device that supplies process gas for substrate processing inside the chamber, where the gas supply device includes a vaporizer that vaporizes a liquid raw material, It includes a conduit connecting each component and a plurality of valves and sensors that control the flow of fluid.

Meanwhile, in the conventional case, in order to control the flow of gas supplied to the process chamber, a flow control valve was installed between the vaporizer and the process chamber to regulate the flow of fluid. However, in this case, the flow rate control for high-temperature, large-flow gas was required. There is an impossible problem.

First, there is a problem in that it is difficult for the flow control valve to operate stably in a high temperature environment of 150 to 200 degrees and its durability is poor.

To overcome this, a flow control valve using a conventional piezo actuator was used. However, when high-temperature, large-flow gas for supply to a multi-chamber, etc. is supplied through a conventional single flow control valve, the length of the piezo actuator becomes longer. Since the degree of opening of the flow path must be increased, the longer piezo actuator has the problem of lower durability.

In addition, as the length of the piezo actuator increases, the volume of the gas supply device or the flow control portion for gas supply increases, causing a problem in that the device becomes larger.

Meanwhile, as another method, when controlling a large flow rate of gas by widening the cross-sectional area of the flow path within the valve, the opening/closing cross-section becomes wider, so the opening/closing performance of the valve deteriorates, making stable flow control difficult.

The purpose of the present invention is to provide a gas supply device and a gas supply control method that can smoothly control high-temperature, large-flow gas through a plurality of flow control valves in order to solve the above problems.

The present invention was created to achieve the object of the present invention as described above, and the present invention is a gas supply device for supplying a process gas to a process chamber 10 where substrate processing is performed, and the process gas is supplied to the process chamber 10. 1 supply passage 110, a second supply passage 120 in communication with the process chamber 10, and a plurality of branch supply passages branched between the first and second supply passages 110 and 120 ( A piping unit 100 including 130); A plurality of flow rate controls that are each installed to form a part of the plurality of branch supply passages 130 and control the flow rate of the process gas by controlling the opening and closing of the branch supply passages 130 using the elongation of the piezoelectric element. valves 200; At least one measurement sensor installed between the plurality of flow control valves 200 and the process chamber 10 to measure the flow rate of the process gas supplied to the process chamber 10, and the measurement sensor a flow rate measurement unit including a flow rate calculation unit that calculates the flow rate of the process gas through the measured value; It includes a control unit that controls the plurality of flow control valves 200 to supply the flow rate of the process gas supplied to the process chamber 10 within a preset range according to the flow rate of the process gas measured through the flow rate measurement unit. A gas supply device is launched.

The measurement sensor is a pressure sensor (P1) that measures the pressure of the process gas, and the flow rate calculation unit calculates the flow rate of the process gas based on the pressure value of the process gas measured by the pressure sensor (P1). can do.

It may include a vaporizer 20 that vaporizes the liquid raw material in front of the plurality of flow control valves 200 to change the phase into the process gas in a gaseous state, and supplies the process gas in a gaseous state.

The control unit may individually control the plurality of flow control valves 200.

It may further include a blocking valve 400 installed in the second supply passage 120 to allow or block the supplied process gas into the process chamber 10.

The process gas may have a temperature of 50 degrees Celsius or higher.

The maximum passing flow rate of the process gas per unit time of the flow control valve 200 with the largest capacity among the plurality of flow control valves 200 is the amount per unit time of the process gas required for the substrate processing process of the process chamber 10. It may be smaller than the required flow rate.

The maximum passing flow rate of the process gas per unit time of the flow control valve 200 with the largest capacity among the plurality of flow control valves 200 is supplied to the first supply passage 110. It may be smaller than the flow rate.

In addition, the present invention is a gas supply control method using a gas supply device, comprising: a valve opening step (S110) of opening at least one of the plurality of flow control valves (200); A flow measurement step (S120) of measuring the flow rate of the process gas supplied through the flow measurement unit; A gas supply control method including a flow rate control step (S130) of controlling at least one flow control valve 200 through the flow rate of the process gas measured through the flow rate measurement unit is disclosed.

In the flow rate control step (S130), the flow rate of the process gas can be adjusted by controlling the plurality of flow control valves 200 to sink.

In the flow rate control step (S130), the flow rate of the process gas can be adjusted by controlling the operation of the remaining flow control valves 200 while some of the plurality of flow control valves 200 are opened or closed and fixed. there is.

In addition, the present invention is a gas supply control method using a gas supply device, comprising: a flow control valve closing step (S300) of blocking the movement of the process gas by closing the plurality of flow control valves (200); After the flow control valve closing step (S300), the blocking valve 400 installed in the second supply passage 120 to introduce or block the process gas supplied to the process chamber 10 is closed, A gas supply control method including a supply blocking step (S400) of blocking the supply of process gas to the process chamber 10 is disclosed.

The supply blocking step (S400) includes an exhausting step (S410) of exhausting the process gas between the plurality of flow control valves 200 and the process chamber 10, and the blocking after the exhausting step (S410). It may include a blocking valve closing step (S420) of blocking the supply of the process gas to the process chamber 10 by closing the valve 400.

The blocking valve closing step (S420) may be performed when the measured value of the flow measurement unit is below a preset value.

The gas supply device and gas supply control method according to the present invention have the advantage of vaporizing liquid raw materials into a gaseous state optimized for the process in a high-temperature process environment and supplying the vaporized process gas in a fixed amount to the process chamber.

The gas supply device and gas supply control method according to the present invention have the advantage of enabling precise process gas flow rate control by controlling the gas flow rate supplied through a flow control valve that can be stably operated even in a high temperature environment of 150 to 200 degrees Celsius.

In addition, the gas supply device and gas supply control method according to the present invention have the advantage of controlling and stably supplying a high volume of supply gas for use in a plurality of process chambers through a plurality of flow control valves.

In addition, the gas supply device and gas supply control method according to the present invention have a long length or a large opening/closing cross-sectional area when controlling the flow rate through a single flow control valve through a plurality of flow control valves, thereby ensuring complete durability and functionality. It overcomes the problems of not being able to do this and has the advantage of excellent durability and performance.

Figure 1 is a conceptual diagram showing a gas supply device according to the present invention.
FIG. 2 is a perspective view showing flow control valves provided in the piping section of the gas supply device of FIG. 1.
Figure 3 is a cross-sectional view taken in the III-III direction showing the piping part of the gas supply device of Figure 2.
FIG. 4 is a cross-sectional view taken in the direction IV-IV showing the flow control valve in the gas supply device of FIG. 2.
FIGS. 5A and 5B are flowcharts explaining a gas supply control method performed to supply process gas in the gas supply device of FIG. 1.
FIGS. 6A and 6B are flowcharts explaining a gas supply control method performed to cut off the supply of process gas in the gas supply device of FIG. 1.

Hereinafter, the gas supply device and gas supply control method according to the present invention will be described with reference to the attached drawings.

As shown in FIG. 1, the gas supply device according to the present invention is a gas supply device that supplies process gas to the process chamber 10 where substrate processing is performed, and vaporizes the liquid raw material into the process gas in a gaseous state. A phase change vaporizer (20); Branched between the first supply passage 110 in communication with the vaporizer 20, the second supply passage 120 in communication with the process chamber 10, and the first and second supply passages 110 and 120. A piping unit 100 including a plurality of branch supply passages 130 provided with; A plurality of flow rate controls that are each installed to form a part of the plurality of branch supply passages 130 and control the flow rate of the process gas by controlling the opening and closing of the branch supply passages 130 using the elongation of the piezoelectric element. valves 200; At least one pressure sensor (P1) installed between the plurality of flow control valves 200 and the process chamber 10 to measure the pressure of the process gas supplied to the process chamber 10; Controlling the plurality of flow control valves 200 to supply the flow rate of the process gas supplied to the process chamber 10 within a preset range according to the pressure of the process gas measured through the pressure sensor P1. Includes a control unit.

In addition, as shown in FIG. 1, the gas supply device according to the present invention may further include a liquid raw material preheating unit 30 that preheats the liquid raw material to a preset temperature and supplies it to the vaporizer 20.

In addition, the gas supply device according to the present invention is installed in the liquid raw material supply pipe 40 that supplies liquid raw material to the vaporizer 20, and includes a liquid raw material control valve that controls the amount of liquid raw material supplied to the vaporizer 20. It may include (300) and a pressure measurement sensor (P0) that measures the pressure between the liquid raw material control valve 300 and the flow control valve 200.

In addition, the gas supply device according to the present invention is installed in the second supply passage 120 and additionally includes a blocking valve 400 that flows in or blocks the process gas supplied from the vaporizer 20 into the process chamber 10. It can be included.

The process gas has a temperature of 50 degrees Celsius or more, more preferably 150 degrees Celsius or more and 200 degrees Celsius or less, and may be a gas used in a high temperature environment.

In addition, the gas supply device according to the present invention is such that the maximum passing flow rate of process gas per unit time of the flow control valve 200 with the largest capacity among the plurality of flow control valves 200 is determined by the substrate processing process of the process chamber 10. It may be smaller than the required flow rate per unit time of process gas required for .

Furthermore, the gas supply device according to the present invention has the maximum passing flow rate of process gas per unit time of the flow control valve 200 with the largest capacity among the plurality of flow control valves 200 in the first supply passage 110. It may be smaller than the supply flow rate per unit time of the supplied process gas.

That is, since a single flow control valve 200 cannot sufficiently supply process gas for the process, multiple flow control valves 200 can be used, and more specifically, the limited number of piezo valves usable in a high-temperature process environment is limited. In order to solve the problem of capacity, an invention in which a plurality of piezo valves are used is disclosed.

The process chamber 10 is configured to form an enclosed processing space for substrate processing, and various configurations are possible.

For example, the process chamber 10 performs substrate processing using process gas, and is in communication with the vaporizer 20 through the piping unit 100 to receive vaporized process gas from the vaporizer 20. .

The process chamber 10 can be any type of process chamber 10 previously disclosed that performs substrate processing using process gas.

The vaporizer 20 is a configuration that vaporizes a liquid raw material and changes its phase into a gaseous process gas, and can have various configurations.

That is, the vaporizer 20 can use any method, such as injection or baking, as long as it vaporizes the liquid material. More preferably, a baking method can be used to vaporize the liquid material by creating a high temperature environment.

For example, the vaporizer 20 may include a vaporization body in which the supplied liquid raw material is vaporized, and a heater that heats the vaporization body.

The vaporization body is in communication with an external liquid raw material storage unit and a liquid raw material preheating unit to be described later, and is configured to temporarily store and vaporize the supplied liquid raw material, and various configurations are possible.

The heater is provided outside the vaporization body containing the liquid raw material and heats the vaporization body to create a vaporization environment, and various configurations are possible.

For example, the heater is installed outside the vaporization body to surround the vaporization body, and can heat the vaporization body by supplying power to a heating coil or heating jacket.

In this case, the heating temperature can vary depending on the vaporization point of the liquid raw material, and an environment between 150 and 200 degrees can be created.

The liquid raw material is a liquid source material of process gas, which is used for substrate processing, and any raw material that exists in a liquid state at room temperature can be used.

For example, the liquid raw material is a liquid organic compound and may include TEOS, Ta20(C2H5)5, organic silane precursor, etc.

The piping unit 100 communicates with the vaporizer 20 and the process chamber 10, and is configured to transmit the gaseous process gas vaporized through the vaporizer 20. Various configurations are possible.

For example, the piping unit 100 includes a first supply passage 110 in communication with the vaporizer 20, a second supply passage 120 in communication with the process chamber 10, and first and second supply passages. It may include a plurality of branch supply passages 130 branched between the passages 110 and 120.

That is, the piping unit 100 includes a first supply passage 110 connected to the vaporizer 20, a plurality of branch supply passages 130 branching from the first supply passage 110, and a plurality of branches. It may include a second supply passage 120 formed by combining the supply passages 130 again.

Meanwhile, in this case, it goes without saying that a plurality of the first supply passage 110 and the second supply passage 120 may be formed to communicate with the plurality of branch supply passages 130, respectively.

In addition, the piping unit 100 is a pipe in which a first supply passage 110, a second supply passage 120, and a plurality of branch supply passages 130 are formed, as shown in FIGS. 2 and 3. It may include block 140.

The piping block 140 has a first supply passage 110, a second supply passage 120, and a plurality of branch supply passages 130 formed therein for supply of process gas, and various configurations are possible. do.

For example, the piping block 140 is a block made of SUS material, and a first supply passage 110, a second supply passage 120, and a plurality of branch supply passages 130 may be formed therein.

The first supply passage 110 has one end connected to the vaporizer 20 and the other end connected to a plurality of branch supply passages 130 to branchly supply the gaseous process gas vaporized from the vaporizer 20. It can be supplied to each euro (130).

The second supply passage 120 has one end connected to the process chamber 10 and the other end connected to a plurality of branch supply passages 130, so that it receives the process gas from the branch supply passage 130 and supplies it to the process chamber. It can be supplied as (10).

The plurality of branch supply passages 130 are configured so that a plurality of flow control valves 200 can be installed on each in order to smoothly control the flow rate of a large volume of process gas, and various configurations are possible.

For example, the plurality of branch supply passages 130 include a first branch supply passage 130a and a second supply passage connected to the first supply passage 110, respectively, based on the flow control valve 200. It may include a first branch supply passage (130b) connected to (120).

The plurality of flow control valves 200 are installed to control the flow rate of the supplied process gas, and various configurations are possible.

The plurality of flow control valves 200 require precise flow control for high temperature process gas of 150 to 200 degrees, and may be piezoelectric element driven valves that can be stably operated in a high temperature process environment, More specifically, a piezo valve may be applied.

In this case, the plurality of flow control valves 200 are each installed to form part of a plurality of branch supply passages 130, and by controlling the opening and closing of the branch supply passage 130 using the elongation of the piezoelectric element, The flow rate of process gas can be adjusted.

More specifically, the plurality of flow control valves 200 may be installed to form a part of the branch supply passage 130 between the first branch supply passage 130a and the second branch supply passage 130b. .

As shown in FIG. 4, the plurality of flow control valves 200 operate the metal diaphragm 220 and the valve seat 230 using a piezoelectric actuator 210 that expands and drives the piezoelectric element when voltage is applied. The branch supply passage 130 can be opened and closed by contacting or separating.

More specifically, the plurality of flow control valves 200 include a support cylinder 250 that rises by extension in accordance with the application of voltage of the piezoelectric actuator 210, and a metal diaphragm 220 as the support cylinder 250 rises. It may include a pressurizing portion 240 that opens the supply passage by being spaced apart from and rising.

On the other hand, when no voltage is applied, the support body 250 and the pressurizing part 240 are lowered by elastic force, and the metal diaphragm 220 is pressed by the pressurizing part 240, so that the metal diaphragm 220 is moved to the valve seat 230. The supply channel can be closed by contacting .

Meanwhile, the plurality of flow control valves 200 can be any type of conventionally disclosed piezoelectric element driven valve as long as it is configured to open and close the branch supply passage 130 using a piezoelectric element driving method.

Additionally, the plurality of flow control valves 200 are respectively installed in the plurality of branch supply passages 130 and may be installed to form a part of the branch supply passages 130.

More specifically, the plurality of flow control valves 200 are installed at the top of the piping block 140, and a plurality of branch supply passages 130 are formed at the top of the piping block 140, and the flow control valve ( 200) may each form part of a plurality of branch supply passages 130.

Through this, the plurality of flow control valves 200 space the separation distance between the valve seat 230 and the metal diaphragm 220 to a maximum of 50㎛ through a conventional single flow control valve 200 to control the process gas. Compared to the fact that only the process gas level of 1000cc to 1200cc can be controlled by adjusting the flow rate, there is an advantage that the process gas flow rate of 2000cc or more can be adjusted simultaneously through the plurality of flow control valves 200.

The flow rate measurement unit includes at least one measurement sensor installed between the plurality of flow control valves 200 and the process chamber 10 to measure the flow rate of the process gas supplied to the process chamber 10, and a measurement sensor It is a configuration that includes a flow rate calculation unit that calculates the flow rate of the process gas through the measured value, and various configurations are possible.

For example, the measurement sensor may be a variety of sensors, such as a temperature sensor or a pressure sensor. More preferably, it may be a pressure sensor (P1) capable of stable sensing in a high temperature environment.

The pressure sensor (P1) is installed between the plurality of flow control valves 200 and the process chamber 10 to measure the pressure of the process gas supplied to the process chamber 10, and can be configured in various ways. do.

That is, the pressure sensor P1 is installed between the plurality of flow control valves 200 and the process chamber 10 and can measure the flow rate of the process gas by measuring the pressure of the process gas.

At this time, the pressure sensor (P1) is plural and is installed in each of the plurality of branch supply passages 130 to measure the flow rate of the process gas present in each of the branch supply passages 130.

As another example, the pressure sensor P1 precisely measures the flow rate of the process gas supplied to the process chamber 10 and is formed by combining a plurality of branch supply passages 130 at the rear end to reduce raw material costs. One can be installed in the second supply passage 120.

In this case, the pressure sensor (P1) is installed in the second supply passage 120 and measures the flow rate of the process gas present in the second supply passage 120 to determine the process gas supplied to the process chamber 10. You can check the amount.

The liquid raw material preheating unit 30 is a component that preheats the liquid raw material to a preset temperature and supplies it to the vaporizer 20, and various configurations are possible.

For example, the liquid raw material preheating unit 30 includes a liquid raw material preheating body that preheats the liquid raw material supplied from the outside to a preset temperature, and a liquid raw material preheating body that heats the liquid raw material preheating body to a certain temperature to store the liquid stored in the liquid raw material preheating body. It may include a preheater that preheats the raw materials.

Meanwhile, in this case, the liquid raw material preheating unit 30 can serve as a storage space for storing liquid raw materials, and allows the phase change from the vaporizer 20 to the process gas to occur within a short time, thereby supplying gas. The overall process time can be reduced.

The liquid raw material control valve 300 is installed on the liquid raw material supply pipe 40 that supplies liquid raw materials to the vaporizer 20, and is a component that controls the amount of liquid raw materials supplied to the vaporizer 20, and has various configurations. This is possible.

For example, the liquid raw material control valve 300 can control the amount of liquid raw material supplied to the vaporizer 20 according to the control of the control unit described later, and more preferably, the liquid raw material preheating unit 30 and It is installed between the vaporizers 20, and the supply amount of the liquid raw material preheated from the liquid raw material preheating unit 30 can be adjusted according to the control of the control unit.

Meanwhile, the liquid raw material control valve 300 can be any type of valve as long as it is configured to control the supply amount of the liquid raw material, and more preferably, it can be a valve that can be stably operated in a high temperature environment.

The pressure measurement sensor (P0) is a component that measures the pressure between the liquid raw material control valve 300 and the flow control valve 200, and various configurations are possible.

In this case, the pressure measurement sensor (P0) is installed between the liquid raw material control valve 300 and the vaporizer 20, and measures the flow rate of the liquid raw material supplied to the vaporizer 20 by measuring the flow rate of the liquid raw material supplied to the vaporizer 20. The amount can be measured.

As another example, the pressure measurement sensor (P0) is installed between the vaporizer 20 and the flow control valve 200, more preferably in the first supply passage 110, to measure the gaseous state supplied from the vaporizer 20. By measuring the pressure of the process gas, the amount of liquid raw material in the vaporizer 20 can be measured.

That is, the pressure measurement sensor (P0) is installed in the first supply passage 110, measures the pressure of the gaseous process gas supplied from the vaporizer 20, and uses the measured value to determine the pressure of the gaseous process gas inside the vaporizer 20. The amount of liquid raw material can be estimated, and based on this, the amount of liquid raw material supplied into the vaporizer 20 can be adjusted through the liquid raw material control valve 300.

Meanwhile, in this case, it goes without saying that a plurality of pressure measurement sensors (P0) may be provided and installed in each of the plurality of branch passages 130.

As another example, of course, the pressure measurement sensor P0 can be installed in the vaporizer 20 to directly measure the remaining amount of liquid raw material.

The blocking valve 400 is installed in the second supply passage 120 and is configured to flow in or block the process gas supplied from the vaporizer 20 into the process chamber 10, and various configurations are possible.

For example, the blocking valve 400 is installed at the front of the process chamber 10 in the second supply passage 120 and can block the process gas from flowing into the process chamber 10 by opening and closing.

In this case, the blocking valve 400 can completely close the second supply passage 120 by applying an elastic material to the blocking surface of the passage.

The control unit controls a plurality of flow control valves 200, and various configurations are possible.

For example, the control unit operates a plurality of flow control valves 200 to supply the flow rate of the process gas supplied to the process chamber 10 within a preset range according to the pressure of the process gas measured through the pressure sensor P1. You can control them.

In this case, the control unit can control the flow rate of the supplied process gas by controlling the plurality of flow control valves 200 to be synchronized and operated in the same manner at the same time.

That is, the control unit can control the plurality of flow control valves 200 to operate while maintaining the opening degree of the supply passage of the plurality of flow control valves 200 the same.

More specifically, the supply flow rate of the process gas per one flow control valve 200 can be controlled by dividing the supply amount by the number of flow control valves 200 so that each flow control valve 200 supplies it.

Meanwhile, as another example, the control unit may individually control a plurality of flow control valves 200.

More specifically, the control unit can control the supply flow rate of the process gas by individually controlling each of the plurality of flow control valves 200, and fixes some of the plurality of flow control valves 200 by opening or closing them. In this state, the supply flow rate of the process gas may be adjusted by adjusting the remaining flow control valves 200.

Meanwhile, the control unit may control the liquid raw material control valve 300 to adjust the flow rate of the liquid raw material supplied to the vaporizer 20 through the pressure value measured through the pressure measurement sensor P0.

More specifically, when the pressure value measured through the pressure measurement sensor (P0) installed in the first supply passage 110 is lower than the standard, the control unit determines that the remaining amount of liquid raw material in the vaporizer 20 is insufficient. , the liquid raw material control valve 300 can be opened to additionally supply liquid raw materials to the vaporizer 20.

Additionally, the control unit may control the opening and closing of the blocking valve 400 to allow process gas to flow into or be blocked from the hollow chamber 10 .

Hereinafter, a gas supply control method for controlling gas supply using the gas supply device according to the present invention will be described in detail with reference to the attached drawings.

In the gas supply control method according to the present invention, as shown in FIGS. 5A and 5B, at least one of the plurality of flow control valves 200 is opened and the pressure sensor P1 is measured through the measured value. A flow control valve opening step (S100) of controlling the flow rate of the process gas by controlling at least one flow control valve (200); By opening the blocking valve 400, which is installed in the second supply passage 120 and allows the process gas supplied from the vaporizer 20 to flow into or block the process chamber 10, the process gas flows into the process chamber. It includes a blocking valve opening step (S200) supplied to (10).

In addition, the gas supply control method according to the present invention includes a flow control valve closing step of blocking the movement of the process gas by closing the plurality of flow control valves 200, as shown in FIGS. 6A and 6B. S300) and; By closing the blocking valve 400, which is installed in the second supply passage 120 and allows the process gas supplied from the vaporizer 20 to flow into or block the process chamber 10, the process gas flows into the process chamber 10. It includes a supply blocking step (S400) that blocks the supply to (10).

The flow control valve opening step (S100) opens at least one of the plurality of flow control valves 200 and controls at least one flow control valve 200 through the measured value of the flow measurement unit, thereby controlling the flow rate of the process gas. Flow rate can be controlled.

The flow control valve opening step (S100) may be performed to supply process gas from the vaporizer 20 to the process chamber 10 before starting the process for processing the substrate in the process chamber 10.

In addition, the flow control valve opening step (S100) includes a valve opening step (S110) of opening at least one of the plurality of flow control valves 200, and the valve opening step (S110) supplied through the flow measurement unit. It may include a flow measurement step (S120) in which the flow rate of the process gas is measured, and a flow rate control step (S130) in which the control unit controls at least one flow control valve 200 through the flow rate of the process gas measured through the flow measurement unit. You can.

The valve opening step (S110) is a step of opening at least one of the plurality of flow control valves 200, and can be performed using various methods.

More specifically, in the valve opening step (S110), before the start of the process, the plurality of flow control valves 200 are closed, so that the process gas delivered from the vaporizer 20 flows through the vaporizer 20 and the plurality of flow control valves 200. ) In a state where the first supply passage 110 and the first branch supply passage 130a are filled, at least one flow control valve 200 is opened to allow the process gas to flow into the second branch supply passage 130b and the first branch supply passage 130b. It can be delivered to 2 supply channel 120.

Meanwhile, the flow rate measurement step (S120) is a step of measuring the pressure of the process gas supplied through the pressure sensor (P1) after the valve opening step (S110), and can be performed using various methods.

In the flow rate measurement step (S120), the pressure of the process gas can be measured through the pressure sensor (P1) installed in the second supply passage 120 to determine the flow rate of the process gas.

The flow rate control step (S130) is a step in which the controller controls at least one flow control valve 200 using the measured value measured through the pressure sensor (P1), and can be performed using various methods.

In the flow rate control step (S130), the control unit controls the degree of opening of at least one flow control valve 200 using the measured value measured through the pressure sensor (P1), thereby controlling the flow rate of the process gas.

In this case, the flow rate control step (S130) may control the flow rate by simultaneously controlling a plurality of flow control valves 200. As another example, the flow rate may be adjusted by controlling some of the plurality of flow control valves 200. there is.

The blocking valve opening step (S200) opens the blocking valve 400, which is installed in the second supply passage 120 and allows the process gas supplied from the vaporizer 20 to flow into or blocks the process chamber 10, to process the process. This is the step of supplying gas to the process chamber 10, and can be done by various methods.

In the blocking valve opening step (S200), the blocking valve 400 is opened to supply process gas to the process chamber 10, thereby allowing substrate processing to be performed through the process chamber 10.

The flow control valve closing step (S300) is a step of blocking the movement of process gas by closing the plurality of flow control valves 200, and can be performed in various ways.

For example, in the flow control valve closing step (S300), the process for substrate processing in the process chamber 10 is completed, and a plurality of flow control valves 200 are used to block the supply of process gas to the process chamber 10. ) can be closed.

The supply blocking step (S400) closes the blocking valve 400, which is installed in the second supply passage 120 and allows the process gas supplied from the vaporizer 20 to flow into or blocks the process chamber 10, thereby This is a step of blocking the supply to the process chamber 10, and can be done by various methods.

That is, in the supply blocking step (S400), the blocking valve 400 may be closed at a certain time lag after closing the plurality of flow control valves 200.

Meanwhile, the supply blocking step (S400) includes an exhausting step (S410) for exhausting the process gas between the plurality of flow control valves 200 and the process chamber 10, and a blocking valve (S410) after the exhausting step (S410). It may include a blocking valve closing step (S420) of blocking the supply of process gas to the process chamber 10 by closing 400).

The exhaust step (S410) is a step of exhausting the process gas between the plurality of flow control valves 200 and the process chamber 10, and more specifically, the second branch supply passages 130b and the second supply The process gas remaining in the flow path 120 can be exhausted through a separate exhaust unit.

In the blocking valve closing step (S420), by closing the blocking valve 400, the second branch supply passages 130b and the second supply passage 120 are exhausted and the process chamber 10 in a state in which the process gas is removed. ) can block the supply of process gas to .

Meanwhile, in the blocking valve closing step (S420), in order to make the remaining amount of process gas remaining in the second branch supply passages 130b and the second supply passage 120 below the standard value, the pressure sensor P1 is operated. When the measured value is below a preset value, the blocking valve 400 can be blocked.

At this time, in the blocking valve closing step (S420), when the blocking valve 400 is blocked before the flow control valve 200, residual gas may exist between the blocking valve 400 and the flow control valve 200. Bar, more preferably, the flow control valve 200 and the blocking valve 400 can be sequentially blocked while exhaust is being performed.

Since the above is only a description of some of the preferred embodiments that can be implemented by the present invention, as is well known, the scope of the present invention should not be construed as limited to the above embodiments, and the scope of the present invention described above Both the technical idea and the technical idea underlying it will be said to be included in the scope of the present invention.

10: Process chamber 20: Vaporizer
100: Piping part 200: Flow control valve
300: Liquid raw material control valve 400: Blocking valve

Claims (14)

A gas supply device that supplies process gas to the process chamber 10 where substrate processing is performed,
It is provided as a branch between a first supply passage 110 through which the process gas is supplied, a second supply passage 120 in communication with the process chamber 10, and the first and second supply passages 110 and 120. A piping unit 100 including a plurality of branch supply passages 130;
A plurality of flow rate controls that are each installed to form a part of the plurality of branch supply passages 130 and control the flow rate of the process gas by controlling the opening and closing of the branch supply passages 130 using the elongation of the piezoelectric element. valves 200;
At least one measurement sensor installed between the plurality of flow control valves 200 and the process chamber 10 to measure the flow rate of the process gas supplied to the process chamber 10, and the measurement sensor a flow rate measurement unit including a flow rate calculation unit that calculates the flow rate of the process gas through the measured value;
It includes a control unit that controls the plurality of flow control valves 200 to supply the flow rate of the process gas supplied to the process chamber 10 within a preset range according to the flow rate of the process gas measured through the flow rate measurement unit. And
The capacity of each of the plurality of flow control valves 200 having the same capacity is determined by the maximum passing flow rate of the process gas per unit time of the flow control valve 200 required for the substrate processing process of the process chamber 10. It is smaller than the required flow rate per unit time of process gas,
The measurement sensor is,
A pressure sensor (P1) installed in the second supply passage 120 formed by combining a plurality of branch supply passages 130 at the rear end to measure the pressure of the process gas,
The control unit,
A gas supply device characterized in that the plurality of flow control valves (200) are synchronized and controlled according to the process gas pressure measured through the pressure sensor (P1). In claim 1,
The flow rate calculation unit,
A gas supply device characterized in that the flow rate of the process gas is calculated based on the pressure value of the process gas measured by the pressure sensor (P1). In claim 1,
A gas supply device comprising a vaporizer (20) that vaporizes the liquid raw material in front of the plurality of flow control valves (200) to change the phase into the process gas in a gaseous state, and supplies the process gas in a gaseous state. . In claim 1,
The control unit,
A gas supply device characterized in that the plurality of flow control valves (200) are individually controlled. In claim 1,
A gas supply device further comprising a shutoff valve 400 installed in the second supply passage 120 to allow the supplied process gas to flow into or block the process chamber 10. In claim 1,
The process gas is,
A gas supply device characterized in that the temperature is 50 degrees Celsius or higher. delete In claim 1,
A gas supply device, wherein the maximum passing flow rate of the process gas per unit time of the flow control valve (200) is smaller than the supply flow rate per unit time of the process gas supplied to the first supply passage (110). A gas supply control method using the gas supply device according to any one of claims 1 to 6 and claim 8,
A valve opening step (S110) of opening at least one of the plurality of flow control valves 200;
A flow measurement step (S120) of measuring the flow rate of the process gas supplied through the flow measurement unit;
A gas supply control method comprising a flow rate control step (S130) of controlling at least one flow control valve 200 through the flow rate of the process gas measured through the flow rate measurement unit. In claim 9,
The flow rate control step (S130),
A gas supply control method, characterized in that the flow rate of the process gas is adjusted by controlling the plurality of flow control valves (200) to be driven to sink. In claim 9,
The flow rate control step (S130),
A gas supply control method, characterized in that the flow rate of the process gas is adjusted by controlling the operation of the remaining flow control valves (200) while some of the plurality of flow control valves (200) are opened or closed and fixed. A gas supply control method using the gas supply device according to any one of claims 1 to 6 and claim 8,
A flow control valve closing step (S300) of blocking the movement of the process gas by closing the plurality of flow control valves 200;
After the flow control valve closing step (S300), the blocking valve 400 installed in the second supply passage 120 to introduce or block the process gas supplied to the process chamber 10 is closed, A gas supply control method comprising a supply blocking step (S400) of blocking the supply of process gas to the process chamber (10). In claim 12,
In the supply blocking step (S400),
An exhaust step (S410) for exhausting the process gas between the plurality of flow control valves 200 and the process chamber 10, and a block installed in the second supply passage 120 after the exhaust step (S410) A gas supply control method comprising a blocking valve closing step (S420) of blocking the supply of the process gas to the process chamber (10) by closing the valve (400). In claim 13,
In the blocking valve closing step (S420),
A gas supply control method characterized in that it is performed when the measured value of the flow measurement unit is less than a preset value.

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