JP2015202462A - exhaust gas treatment system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an exhaust gas treatment system which continuously draws exhaust gas into a detoxification device and detoxifies the exhaust gas while maintaining the inside of a pipe line at a negative pressure even upon emergency without disposing a preliminary an exhaust fan or an uninterruptible power supply.SOLUTION: An exhaust gas treatment system includes: an automatic opening/closing valve 26 which is disposed on a sub exhaust line L12 connected with a main exhaust line L11 located on a subsequent stage of a dry detoxification device 12 and gets to an open state in such a period that exhaust capacity of the exhaust fan 13 falls below a second exhaust capacity B; an ejector 18 disposed on the sub exhaust line L12 located on a subsequent stage of the automatic opening/closing valve 26; an inactive gas supply line L13 which supplies inactive gas to the ejector 18 in such a period that exhaust capacity of the exhaust fan 13 falls below the second exhaust capacity; and a control part 28 which controls the exhaust fan 13, the automatic opening/closing valve 26 and the inactive gas supply line L13.

Description

  The present invention relates to an exhaust gas processing system for processing exhaust gas.

In general, in an electronic device manufacturing apparatus used for forming a thin film constituting an electronic device such as a semiconductor, a liquid crystal, a solar cell, and an LED, a flammable gas, a pyrophoric gas, a toxic gas, a corrosive gas is used as a raw material gas. Gases that adversely affect organisms and the environment, such as global warming gases, are used.
As for the source gas, not all of the supplied source gas is consumed in the electronic device manufacturing apparatus, but most of the source gas is exhausted from the electronic device manufacturing apparatus as exhaust gas.

Exhaust gas containing gases that adversely affect organisms and the environment, such as combustible gas, pyrophoric gas, toxic gas, corrosive gas, and global warming gas, cannot be released into the atmosphere as it is.
For this reason, in general, the exhaust gas is detoxified by various detoxifying devices that can be rendered harmless, and then released into the atmosphere.

 In Patent Document 1, as an example of a detoxifying device, a detoxifying agent that has a physical or chemical adsorption reaction with a gas that adversely affects a living organism or the environment is used to adsorb the gas that adversely affects the living organism or the environment and is harmless. A dry abatement device is disclosed.

Usually, an exhaust gas treatment line that removes gas components that are exhausted from an electronic device manufacturing apparatus and that adversely affects organisms and the environment contained in the exhaust gas is maintained at a negative pressure rather than an atmospheric pressure. Many.
As a method for maintaining the exhaust gas treatment line at a negative pressure, it is common to install an exhaust fan in the exhaust gas treatment line.

FIG. 3 is a diagram (system diagram) schematically showing a schematic configuration of a conventional exhaust gas treatment system.
Referring to FIG. 3, a conventional exhaust gas processing system 200 is connected to an electronic device manufacturing apparatus 201, and includes a main exhaust line L201, a dry abatement apparatus 202, an exhaust fan 203, and an inert gas supply source. 206, an inert gas supply line L 203, a pressure reducing valve 207, a flow rate regulator 208, an automatic opening / closing valve 209, and a control unit 210.

One end of the main exhaust line L201 is connected to the electronic device manufacturing apparatus 201, and the other end is a gas outlet. Exhaust gas discharged from the electronic device manufacturing apparatus 201 flows through the main exhaust line L201.
The dry-type abatement apparatus 202 is provided in a main exhaust line L201 located between the electronic device manufacturing apparatus 201 and the exhaust fan 203.
The exhaust fan 203 is provided in the main exhaust line L201 located at the rear stage of the dry abatement apparatus 202.

The inert gas supply source 206 is connected to one end of the inert gas supply line L203. The other end of the inert gas supply line L203 is connected to a portion of the main exhaust line L201 located between the electronic device manufacturing apparatus 201 and the dry abatement apparatus 202 that is located near the dry abatement apparatus 202. Yes.
The pressure reducing valve 207 is provided in an inert gas supply line L203 located between the inert gas supply source 206 and the flow rate regulator 208.

The flow rate regulator 208 is provided in an inert gas supply line L203 located at the subsequent stage of the pressure reducing valve 207.
The automatic opening / closing valve 209 is provided in the inert gas supply line L203 located between the flow regulator 208 and the other end of the inert gas supply line L203.
The control unit 210 is electrically connected to the exhaust fan 203 and the automatic opening / closing valve 209. Specifically, the control unit 210 is electrically connected to the exhaust fan 203 via the signal line C201 and electrically connected to the automatic opening / closing valve 209 via the signal line C203.
The control unit 210 controls the exhaust fan 203 and the automatic opening / closing valve 209.

The exhaust gas treatment system 200 configured as described above performs detoxification by supplying exhaust gas to the main exhaust line L201 during normal operation.
On the other hand, in an emergency, the exhaust gas treatment system 200 automatically supplies an inert gas for dilution to the main exhaust line L201, and dilutes the exhaust gas with the inert gas while diluting to the dry abatement apparatus 202. Detoxification is continued by swept away the exhaust gas.
The term “emergency” here refers to a time when the amount of exhaust gas suddenly increases or a failure occurs in the exhaust fan 203 and the exhaust capability of the exhaust fan 203 decreases.

 Generally, the dry abatement device 202 does not lose its abatement capability even during a power failure. However, in the exhaust gas treatment system 200, the amount of gas supplied to the dry-type abatement apparatus 202 in an emergency increases to an amount including not only exhaust gas but also inert gas for dilution, and therefore, in the main exhaust line L201. The in-cylinder speed at becomes high, and the abatement ability decreases.

  By the way, generally, the pressure of the exhaust gas discharged from the reduced-pressure electronic device manufacturing apparatus 201 is lower than the atmospheric pressure, and the exhaust gas is dry-dried by an exhaust fan 203 provided at the subsequent stage of the dry-type abatement apparatus 202 in normal times. Detoxification is performed while being drawn into the detoxification apparatus 202.

Next, with reference to FIG. 3, a conventional method for removing the exhaust gas treatment system 200 will be described.
At normal times, the exhaust gas discharged from the electronic device manufacturing apparatus 201 is drawn into the dry-type abatement apparatus 202 by the exhaust fan 203 and subjected to the abatement process. At this time, the exhaust fan 203 operates with a steady exhaust capability preset in the control unit 210.
On the other hand, the inert gas for dilution is ready to be supplied. Specifically, the inert gas supply source 206 is in an open state, the pressure reducing valve 207 is adjusted to a predetermined pressure, the flow regulator 208 is adjusted to have a predetermined gas flow rate, and the automatic opening / closing valve 209 is closed. State.

  Here, when the exhaust capacity of the exhaust fan 203 decreases and an emergency occurs, the control unit 210 automatically detects an abnormality of the exhaust fan 203 and transmits an open signal to the automatic opening / closing valve 209. Then, the automatic opening / closing valve 209 is opened, and an inert gas for dilution is supplied into the main exhaust line L201 at a predetermined flow rate.

In this case, the concentration of the combustible gas in the exhaust gas is diluted below the lower limit of explosion by the inert gas for dilution, and the exhaust gas can be pushed to the dry abatement device 202 to remove the exhaust gas. Harm can continue.
However, in this case, the inside of the main exhaust line L201 cannot be maintained at a negative pressure, and the exhaust gas may flow back to the upstream electronic device manufacturing apparatus 201 side.

 FIG. 4 is a diagram (system diagram) schematically showing a schematic configuration of another conventional exhaust gas treatment system. In FIG. 4, the same components as those of the conventional exhaust gas processing system 200 shown in FIG.

 Referring to FIG. 4, the exhaust gas treatment system 240 includes a main exhaust line L201, a dry-type abatement device 202, an exhaust fan 203, a check valve 211, a sub exhaust line L202, an automatic on-off valve 204, Exhaust fans 203 and 214 and an exhaust control unit 210 are included.

One end of the main exhaust line L201 is connected to the electronic device manufacturing apparatus 201, and the other end is a gas outlet. Exhaust gas discharged from the electronic device manufacturing apparatus 201 flows through the main exhaust line L201.
The dry-type abatement apparatus 202 is provided in a main exhaust line L201 located between the electronic device manufacturing apparatus 201 and the exhaust fan 203.
The exhaust fan 203 is provided in the main exhaust line L201 located at the rear stage of the dry abatement apparatus 202.

The check valve 211 is provided in the main exhaust line L201 located at the rear stage of the exhaust fan 203. One end of the exhaust line L202 is connected to the main exhaust line L201 located between the dry removal apparatus 202 and the exhaust fan 203, and the other end is a gas outlet.
The automatic opening / closing valve 204 is provided in the auxiliary exhaust line L202. The exhaust fan 214 is provided in an exhaust line L202 located at the subsequent stage of the automatic opening / closing valve 204.

The control unit 210 is electrically connected to the exhaust fans 203 and 214 and the automatic opening / closing valve 204. Specifically, the control unit 210 is electrically connected to the exhaust fan 203 via the signal line C201, electrically connected to the automatic opening / closing valve 204 via the signal line C202, and via the signal line C204. The exhaust fan 214 is electrically connected.
The control unit 210 controls the exhaust fans 203 and 214 and the automatic opening / closing valve 204.

 In normal times, exhaust gas is supplied to the main exhaust line L201 to be removed. On the other hand, in an emergency, the automatic opening / closing valve 204 is opened and the spare exhaust fan 214 is activated to continue the detoxification.

Next, with reference to FIG. 4, a method for removing the exhaust gas treatment system 240 will be described.
Normally, the exhaust gas discharged from the electronic device manufacturing 201 is drawn into the dry-type abatement apparatus 202 by the exhaust fan 203 and subjected to the abatement process. At this time, the exhaust fan 203 operates with a steady exhaust capability preset in the control unit 210.
On the other hand, the spare exhaust fan 214 is in a standby state. Specifically, the exhaust fan 214 is in a stopped state, and the automatic opening / closing valve 204 is in a closed state.

When the exhaust capacity of the exhaust fan 203 decreases and an emergency occurs, the control unit 210 detects an abnormality of the exhaust fan 203, automatically opens the automatic opening / closing valve 204, and activates the exhaust fan 214 to exhaust gas. Is supplied to the auxiliary exhaust line L202. At this time, the exhaust fan 214 operates at a steady exhaust capacity preset in the control unit 210. The exhaust fan 203 is stopped at substantially the same timing.
This makes it possible to continue exhaust gas removal even in an emergency. Further, the pressure in the main exhaust line L201 can be maintained at a negative pressure.

 Furthermore, as another conventional gas processing system, the exhaust gas processing systems 200 and 240 shown in FIGS. 3 and 4 are used as a power failure countermeasure, and the exhaust fan 203 and / or the exhaust fan 214 are connected to an uninterruptible power supply (see FIG. Some are not shown).

By the way, a method using an ejector is known as a method for keeping the pressure in the pipe at a negative pressure.
Patent Document 2 discloses an ejector that generates a negative pressure upstream by supplying compressed gas or the like without requiring electric power.

JP-A-6-047269 JP 2011-117349 A

By the way, in the exhaust gas treatment system 200 shown in FIG. 3, in an emergency, the exhaust gas can be pushed away to the dry abatement device 202 while being diluted with an inert gas. The in-cylinder speed in the cylinder increased, and the abatement ability might be reduced.
Further, in the exhaust gas treatment system 200 shown in FIG. 3, since the pressure in the main exhaust line L201 cannot be maintained at a negative pressure, exhaust gas that has not been sufficiently detoxified may leak to the outside.

On the other hand, in the exhaust gas treatment system 240 shown in FIG. 4, it is necessary to prepare an extra exhaust fan 214.
Moreover, when using an uninterruptible power supply, it was necessary to provide an uninterruptible power supply separately.
In addition, although a spare exhaust fan and uninterruptible power supply were installed for emergency situations, failure and deterioration occurred due to failure to become emergency for a long period of time. There was concern.

Therefore, the present invention can eliminate exhaust gas continuously by removing exhaust gas into the abatement device while maintaining a negative pressure in the piping even in an emergency without providing a spare exhaust fan or uninterruptible power supply. It is an object to provide an exhaust gas treatment system.
In particular, since the in-cylinder speed can be suppressed even in an emergency, it is effective for an exhaust gas treatment system provided with a dry-type abatement apparatus.

  In order to solve the above-described problems, according to the first aspect of the present invention, a main exhaust line for transporting exhaust gas discharged from equipment, a detoxifying device provided in the main exhaust line, and a main exhaust line Of these, exhaust is provided at a portion located at the rear stage of the abatement apparatus, and is controlled so as to have a preset first exhaust capacity in a normal state, and the pressure in the main exhaust line is maintained at a negative pressure. And the main exhaust line located between the abatement device and the exhaust unit, and the exhaust gas is exhausted during a period when the exhaust unit is lower than a preset second exhaust capability. An automatic exhaust valve that is provided in the auxiliary exhaust line, is closed in a normal state, and is opened during a period when the exhaust capacity of the exhaust unit is lower than the second exhaust capacity; The auxiliary exhaust line Among them, an ejector provided in a portion located after the automatic opening / closing valve, and connected to the ejector, supply compressed gas to the ejector during a period when the exhaust capacity of the exhaust section is lower than the second exhaust capacity. A compressed gas supply line, a first exhaust capacity and a second exhaust capacity are preset, and the exhaust section, the automatic open / close valve, and a control section for controlling the compressed gas supply line. An exhaust gas treatment system is provided.

  Moreover, according to the invention which concerns on Claim 2, the main exhaust line which conveys the exhaust gas discharged | emitted from the installation, the abatement apparatus provided in the said main exhaust line, and the said detoxification among the said main exhaust lines An exhaust unit that is provided in a portion located at the rear stage of the apparatus, is controlled so as to have a first exhaust capacity set in advance in a normal state, and maintains the pressure in the main exhaust line at a negative pressure; Connected to the main exhaust line located between the harmful device and the exhaust part, provided in the sub exhaust line through which the exhaust gas flows during a power failure, and in the sub exhaust line, and is normally closed, during the power failure An automatic open / close valve that is open at the same time, an ejector provided in a portion of the auxiliary exhaust line that is positioned downstream of the automatic open / close valve, and the ejector connected to the ejector at the time of the power failure A compressed gas supply line for supplying the condensed gas, is set in advance the first exhaust capability, an exhaust gas treatment system characterized by comprising a control unit for controlling the exhaust portion is provided.

  Moreover, according to the invention which concerns on Claim 3, among the main exhaust line which conveys the exhaust gas discharged | emitted from the installation, the abatement apparatus provided in the said main exhaust line, and the said detoxification among the said main exhaust lines An exhaust section that is provided in a portion located at the rear stage of the apparatus and is controlled so as to have a first exhaust capacity set in advance in a normal state, and maintains the pressure in the main exhaust line at a negative pressure; and the main exhaust A vacuum measuring device that is provided in a line and connected to the main exhaust line that is located between the abatement device and the exhaust unit, and that is configured to measure a degree of vacuum in the main exhaust line. The auxiliary exhaust line through which the exhaust gas flows when the degree of vacuum in the main exhaust line is higher than that of the main exhaust line, and the auxiliary exhaust line is normally closed, and the main exhaust line is in a closed state, and is more than the preset vacuum value. The degree of vacuum in the exhaust line An automatic open / close valve that is open when it is turned, an ejector provided in a portion of the auxiliary exhaust line that is positioned downstream of the automatic open / close valve, and the ejector. A compressed gas supply line that supplies compressed gas to the ejector when the degree of vacuum in the exhaust line exceeds, the first exhaust capacity, and the vacuum value are set in advance, and the vacuum measured by the vacuum measuring instrument There is provided an exhaust gas processing system comprising the automatic opening and closing valve and a control unit for controlling the compressed gas supply line based on the degree.

  Moreover, according to the invention which concerns on Claim 4, the said abatement apparatus is a dry-type abatement apparatus, The exhaust-gas processing system of any one of Claim 1 thru | or 3 characterized by the above-mentioned is provided. The

  Moreover, according to the invention which concerns on Claim 5, the said compressed gas is nitrogen gas or a noble gas, The exhaust gas processing system of any one of Claims 1 thru | or 4 characterized by the above-mentioned is provided. The

  Moreover, according to the invention which concerns on Claim 6, the said installation is an electronic device manufacturing apparatus used when manufacturing an electronic device, The one of Claims 1 thru | or 5 characterized by the above-mentioned. An exhaust gas treatment system is provided.

  According to the exhaust gas treatment system of the present invention, even if the exhaust fan has a reduced exhaust capacity or an emergency such as a power failure, the exhaust gas is drawn into the abatement device by the action of the ejector. It is possible to continue, and the inside of the pipe through which the exhaust gas flows can be kept at a negative pressure.

  In addition, the compressed gas used in the ejector can prevent the downstream gas from staying after the ejector. Furthermore, even if the abatement capability of the abatement apparatus is reduced and the combustible gas flows downstream, the compressed gas used for the ejector can be diluted and discharged below the lower explosion limit.

1 is a diagram (system diagram) schematically showing a schematic configuration of an exhaust gas treatment system according to a first embodiment of the present invention. It is a figure (system diagram) which shows typically a schematic structure of an exhaust-gas processing system concerning a 2nd embodiment of the present invention. It is a figure (system diagram) which shows typically a schematic structure of the conventional exhaust gas processing system. It is a figure (system diagram) which shows typically schematic structure of other conventional exhaust gas processing systems.

  Embodiments to which the present invention is applied will be described below in detail with reference to the drawings. The drawings used in the following description are for explaining the configuration of the embodiment of the present invention, and the size, thickness, dimension, etc. of each part shown in the figure are the dimensional relationship of the actual exhaust gas treatment system. May be different.

(First embodiment)
FIG. 1 is a diagram (system diagram) schematically showing a schematic configuration of an exhaust gas treatment system according to a first embodiment of the present invention.

 Referring to FIG. 1, an exhaust gas treatment system 10 of the first embodiment is connected to an electronic device manufacturing apparatus 11 (equipment) that is an apparatus for exhausting exhaust gas, and includes a main exhaust line L11, a dry type A detoxification device 12 (a decontamination device), an exhaust fan 13 as an exhaust, a sub exhaust line L12, a check valve 15, automatic open / close valves 17 (automatic open / close valves) 26, an ejector 18, An active gas supply source 21, an inert gas supply line L 13 that is a compressed gas supply line, a pressure reducing valve 23, a flow rate regulator 24, and a control unit 28 are included.

One end of the main exhaust line L11 is connected to the electronic device manufacturing apparatus 11, and the other end is a gas outlet. Exhaust gas is discharged from the electronic device manufacturing apparatus 11 to the main exhaust line L11. The main exhaust line L11 transports the exhaust gas.
Examples of the exhaust gas include raw material gases used when the electronic device manufacturing apparatus 11 manufactures electronic devices (for example, combustible gas, pyrophoric gas, toxic gas, corrosive gas, and global warming gas) Gas that adversely affects living organisms and the environment.

As the main exhaust line L11, for example, a pipe having an outer diameter in the range of 48.6 mm to 114.3 mm can be used.
Further, the material of the main exhaust line L11 is not particularly limited, but can be appropriately selected according to the properties of the components contained in the exhaust gas, for example.
Specifically, when a combustion-type abatement apparatus is used instead of the dry-type abatement apparatus 12, the exhaust gas may become a high temperature. In this case, a material that can withstand the high temperature (for example, metal ) Should be selected.

The dry-type abatement apparatus 12 is an abatement apparatus that performs exhaust gas abatement. The dry-type abatement apparatus 12 is provided in the main exhaust line L11 located between the position where the sub exhaust line L12 is connected and the electronic device manufacturing apparatus 11.
By the way, the pressure of the exhaust gas discharged from the electronic device manufacturing apparatus 11 is lower than the atmospheric pressure, and the gas in the main exhaust line L11 is discharged by the exhaust fan 13 provided at the rear stage of the dry abatement apparatus 12 at the normal time. Thus, detoxification is performed while drawing the exhaust gas into the dry abatement apparatus 12 while keeping the pressure in the main exhaust line L11 at a negative pressure.
By using the dry-type abatement device 12 as the abatement device, the abatement capability can be maintained even during a power failure.

  In the first embodiment, as an example of the abatement apparatus, a case where a dry abatement apparatus is used will be described as an example. However, the abatement apparatus is adapted to the components of exhaust gas to be abolished, It can select suitably from a dry-type abatement apparatus, a combustion-type abatement apparatus, and a wet-type abatement apparatus.

The exhaust fan 13 is provided in a main exhaust line L11 located at the rear stage of the dry abatement apparatus 12. The exhaust fan 13 is inverter-controlled by the control unit 28 and operates at the first exhaust capacity A set in the control unit 28 in advance during normal times.
The “first exhaust capacity A” means that the pressure in the main exhaust line L11 can be maintained at a specified negative pressure in a state where a normal amount of exhaust gas is discharged from the electronic device manufacturing apparatus 11. Exhaust capacity.

Further, the exhaust gas exhaust capacity of the exhaust fan 13 is set to a lower limit value (second exhaust capacity B) preset in the control unit 28 due to a rapid increase in the processing amount of exhaust gas or a failure or abnormality of the exhaust fan 13. When the value falls below, the control unit 28 detects that an abnormality has occurred in the exhaust gas treatment system 10 (detects that an abnormality has occurred).
The “second exhaust capacity B” is an exhaust in which the pressure in the main exhaust line L11 cannot be maintained at a negative pressure in a state where a normal amount of exhaust gas is discharged from the electronic device manufacturing apparatus 11. Is ability.

In the first embodiment, the case where the exhaust fan 13 is used as an example of the exhaust unit has been described as an example. However, the exhaust unit is not limited to the exhaust fan 13.
The exhaust part only needs to be able to draw the exhaust gas in the main exhaust line L11, and for example, a blower or a pump can be used as the exhaust part.

One end of the auxiliary exhaust line L12 is connected to the main exhaust line L11 located between the dry-type abatement apparatus 12 and the exhaust fan 13, and the other end is a gas outlet.
The size and material of the sub exhaust line L12 can be the same as the size and material of the main exhaust line L11 described above.

 The check valve 15 is provided in the main exhaust line L11 located at the rear stage of the exhaust fan 13. The check valve 15 is a valve for preventing air from entering the main exhaust line L11 located on the exhaust fan 13 side from the outlet side of the main exhaust line L11 when the exhaust capacity of the exhaust fan 13 is reduced. is there.

  The inert gas supply line L13 side is normally in a standby state. At this time, the inert gas supply source 21 is open, the pressure reducing valve 23 is adjusted to a predetermined pressure, the flow regulator 24 is adjusted to a predetermined gas flow rate, and the automatic opening / closing valve 26 is closed. is there.

The automatic opening / closing valve 17 is provided in the auxiliary exhaust line L12. The automatic opening / closing valve 17 is in a closed state at a normal time and is in an open state at an abnormal time. By opening the automatic opening / closing valve 17, exhaust gas is supplied to the auxiliary exhaust line L12.
The ejector 18 is provided in the auxiliary exhaust line L12 located at the subsequent stage of the automatic opening / closing valve 17. The ejector 18 does not require electric power, and forms a vacuum by supplying compressed gas.

The inert gas supplied to the ejector 18 becomes a high-speed gas flow in the ejector 18 and is injected downstream. The upstream gas is entrained in the flow of the high-speed gas and is pushed out to the downstream side, so that the upstream side of the ejector 18 has a negative pressure.
When a combustion-type abatement apparatus is used as the abatement apparatus, the ejector 18 is preferably made of metal because the gas after the abatement process becomes a high temperature.

The inert gas supply source 21 is connected to one end of the inert gas supply line L13. The inert gas supply source 21 is a gas supply source filled with an inert gas supplied to the ejector 18, but is not limited thereto as long as it is a gas supply source capable of supplying an inert gas.
Such a gas supply source is not particularly limited to the inert gas supply source 21, and for example, a high-pressure gas container, a gas production apparatus, a large gas storage tank, or the like can be used.

It is important that the inert gas supplied from the inert gas supply source 21 is a gas that does not react with components contained in the exhaust gas. As such an inert gas (compressed gas), for example, nitrogen gas, or a rare gas such as helium gas or argon gas can be used.
As described above, by using nitrogen gas and rare gas as the compressed gas, the exhaust gas can be safely diluted and released without reacting with the components contained in the exhaust gas.

 The inert gas supply line L13 has one end connected to the inert gas supply source 21 and the other end connected to the ejector 18. The inert gas supply line L13 is a line for supplying an inert gas to the ejector 18.

  The pressure reducing valve 23 is provided in an inert gas supply line L13 located in the vicinity of the inert gas supply source 21. The pressure reducing valve 23 is not particularly limited to a pressure reducing valve as long as the supply pressure of the inert gas can be adjusted. For example, a control valve or the like may be used instead of the pressure reducing valve.

In the exhaust gas treatment system 10 of the first embodiment, the case where one pressure reducing valve 23 is provided in the inert gas supply line L13 has been described as an example, but the exhaust gas processing system 10 is disposed in the inert gas supply line L13. The number of pressure reducing valves 23 is not limited to this.
For example, it is good also as a structure which can be pressure-reduced in multistage by providing the several pressure reduction valve 23 in the inert gas supply line L13.

The flow rate regulator 24 is provided in the inert gas supply line L13 located at the subsequent stage of the pressure reducing valve 23. The flow rate regulator 24 is for adjusting the flow rate of the inert gas supplied to the ejector 18.
The automatic opening / closing valve 26 is provided in an inert gas supply line L13 located at the subsequent stage of the flow rate regulator 24. The automatic opening / closing valve 26 is in a closed state at a normal time, and is opened in an abnormal state. When the automatic opening / closing valve 26 is opened, an inert gas is supplied to the ejector 18.

  The control unit 28 is electrically connected to the exhaust fan 13, the automatic open / close valve 17, and the automatic open / close valve 26. Specifically, the control unit 28 is electrically connected to the exhaust fan 13 via the signal line C1, and is electrically connected to the automatic opening / closing valve 17 via the signal line C3. Further, the control unit 28 is electrically connected to the automatic opening / closing valve 26 via a signal line C4.

The control unit 28 is preset with a steady exhaust capability (first exhaust capability A) of the exhaust fan 13. The control unit 28 performs inverter control of the exhaust fan 13 so as to achieve the first exhaust capability A.
In addition, a lower limit value (second exhaust capacity B) of the exhaust fan 13 is set in the control unit 28 in advance. Further, the control unit 28 performs control to open the automatic open / close valve 17 and the automatic open / close valve 26 during a period in which the exhaust capability of the exhaust fan 13 decreases and falls below the second exhaust capability B.

Next, a detoxification method (that is, an operation method of the exhaust gas treatment system 10) using the exhaust gas treatment system 10 of the first embodiment will be described with reference to FIG.
First, an operation method of the exhaust gas treatment system 10 at normal time will be described.
In normal operation, first, the automatic opening / closing valves 17 and 26 are closed. Thereby, the exhaust gas discharged from the electronic device manufacturing apparatus 11 is drawn into the dry-type abatement apparatus 12 by the exhaust fan 13 and subjected to the abatement process. At this time, the exhaust fan 13 operates at the first exhaust capacity A set in the control unit 28 in advance.

  On the other hand, the auxiliary exhaust line L12 side is in a standby state. Specifically, in the standby state, the inert gas supply source 21 can supply the inert gas, the pressure reducing valve 23 is adjusted to a predetermined pressure, and the flow rate regulator 24 has a predetermined gas flow rate. It is adjusted to.

In the exhaust gas treatment system 10 of the first embodiment, the pressure in the main exhaust line L11 is preferably set within the range of -1.5 to -0.5 kPaG.
If the pressure in the main exhaust line L11 is less than -1.5 kPaG, the load on the exhaust fan 13 becomes large, the exhaust fan 13 becomes large, and it is not preferable because it is a high-cost facility.
On the other hand, if the pressure in the main exhaust line L11 exceeds −0.5 kPaG, the electronic device manufacturing apparatus 11 lacks the ability to exhaust the exhaust gas, which is not realistic as the pressure of the abatement apparatus (dry abatement apparatus 12). .
On the other hand, by setting the pressure in the main exhaust line L11 within the range of -1.5 to -0.5 kPaG, the load of the exhaust fan 13 becomes appropriate, and the electronic device manufacturing apparatus is operated by the dry abatement apparatus 12. The exhaust gas from 11 can be efficiently removed.

Next, an operation method of the exhaust gas treatment system 10 at the time of abnormality will be described.
When the exhaust capacity of the exhaust fan 13 decreases and an emergency occurs, the automatic opening / closing valve 17 receives a signal from the control unit 28 and automatically opens. At the same time, the automatic opening / closing valve 26 is opened, an inert gas is supplied to the ejector 18, and the inside of the pipe is kept at a negative pressure even if the exhaust capacity of the exhaust fan 13 is reduced. At substantially the same time, the exhaust fan 13 is stopped.

  In this way, the exhaust gas is drawn into the dry-type abatement device 12 and can be removed even in an emergency. In addition, the inert gas supplied to the ejector 18 can prevent gas from staying on the downstream side of the ejector 18.

Furthermore, even if the combustible gas contained in the exhaust gas passes through the dry abatement apparatus 12 without being detoxified in the dry abatement apparatus 12, it can be diluted and discharged below the lower explosion limit.
During an emergency, it is preferable to keep supplying the inert gas to the ejector 18 for safety.

The pressure in the main exhaust line L11 when the ejector 18 is activated is preferably in the range of −1.5 to −0.5 kPaG, for example.
The pressure reducing valve 23 is selected so that an inert gas having a flow rate suitable for the ejector 18 can be made to flow so that the pressure in the main exhaust line L11 falls within the range of −1.5 to −0.5 kPaG. And the flow regulator 24 may be adjusted.

  The exhaust gas treatment system of the first embodiment includes a main exhaust line L11 for transporting exhaust gas discharged from the electronic device manufacturing apparatus 11 (equipment), and a dry-type abatement apparatus 12 (provided in the main exhaust line L11). An abatement device) and a portion of the main exhaust line L11 located at the rear stage of the dry abatement device 12 and are controlled so as to have a first exhaust capacity A set in advance during normal operation. The exhaust fan 13 (exhaust part) that keeps the pressure in the exhaust line L11 at a negative pressure is connected to the main exhaust line L11 located between the dry abatement device 12 and the exhaust fan 13, and the exhaust fan 13 is preset. The auxiliary exhaust line L12 through which the exhaust gas flows during a period when the exhaust capacity is lower than the second exhaust capacity B, and the auxiliary exhaust line L12 are provided in a normal state and are closed. In addition, an automatic open / close valve 17 (automatic open / close valve) that is opened during a period when the exhaust capacity of the exhaust fan 13 is lower, and an ejector 18 provided in a portion of the auxiliary exhaust line L12 that is located at the subsequent stage of the automatic open / close valve 17. And an inert gas supply line L13 (compressed gas supply line) for supplying compressed gas to the ejector 18 during a period when the exhaust fan 13 is connected to the ejector 18 and the exhaust capacity of the exhaust fan 13 is lower than the second exhaust capacity B. The exhaust capability A and the second exhaust capability B are preset, and the exhaust fan 13, the automatic opening / closing valve 17, and the control unit 28 for controlling the inert gas supply line L13 are provided.

 According to the exhaust gas processing system 10 of the first embodiment configured as described above, even if the exhaust fan 13 has a reduced exhaust capability without providing a spare exhaust fan or an uninterruptible power supply, By supplying an appropriate amount of inert gas to the ejector 18, the exhaust gas can be continued by drawing the exhaust gas into the dry-type abatement device 12, and the inside of the main exhaust line L <b> 11 and the sub exhaust line L <b> 12 through which the exhaust gas flows can be obtained. Negative pressure can be maintained.

 Further, the inert gas supplied to the ejector 18 can prevent the gas from staying on the downstream side. Furthermore, in the unlikely event that the abatement capability of the dry abatement device 12 is reduced and the combustible gas contained in the exhaust gas flows downstream of the dry abatement device 12, the inert gas supplied to the ejector 18 Can be diluted below the lower explosion limit and released.

(Second Embodiment)
FIG. 2 is a diagram (system diagram) schematically showing a schematic configuration of an exhaust gas treatment system according to a second embodiment of the present invention. 2, the same components as those in the exhaust gas processing system 10 according to the first embodiment shown in FIG.

  Referring to FIG. 2, an exhaust gas processing system 40 according to the second embodiment further includes a controller 41 and a vacuum degree measuring device 42 in addition to the configuration of the exhaust gas processing system 10 according to the first embodiment. Except having it, it is comprised similarly to the exhaust-gas processing system 10. FIG.

 The control unit 41 is electrically connected to the exhaust fan 13 via the signal line C1. The control unit 41 is set in advance with a steady exhaust capability (first exhaust capability A) of the exhaust fan 13, and performs inverter control of the exhaust fan 13 so that the exhaust capability becomes the first exhaust capability A.

The vacuum degree measuring device 42 is provided in a portion of the main exhaust line L11 located between the connection position of the sub exhaust line L12 and the dry abatement apparatus 12. The vacuum degree measuring device 42 is electrically connected to the control unit 28 via the signal line C2.
The vacuum degree measuring device 42 measures the degree of vacuum in the main exhaust line L11 on the outlet side of the dry abatement apparatus 12, and transmits the measured degree of vacuum to the control unit 28 via the signal line C2.

The control unit 28 is electrically connected to the automatic opening / closing valve 17 via the signal line C3 and electrically connected to the automatic opening / closing valve 26 via the signal line C4. A vacuum upper limit value is set in the controller 28 in advance.
The control unit 28 performs control to open the automatic opening / closing valves 17 and 26 when the degree of vacuum measured by the degree-of-vacuum measuring instrument 42 exceeds a preset vacuum upper limit value (when the vacuum deteriorates).

Next, a detoxification method (that is, an operation method of the exhaust gas treatment system 40) using the exhaust gas treatment system 40 of the second embodiment will be described with reference to FIG.
The operation method of the exhaust gas treatment system 40 is almost different from the operation method of the exhaust gas treatment system 10 of the first embodiment described above, except that the method for detecting an abnormality is different. There is no.

First, an operation method of the exhaust gas treatment system 40 in a normal time will be described.
First, in a normal time, the automatic open / close valves 17 and 26 are closed. The exhaust gas of the electronic device manufacturing apparatus 11 is drawn into the dry-type abatement apparatus 12 by the exhaust fan 13 and subjected to the abatement process.
At this time, the exhaust fan 13 operates at the first exhaust capacity A set in the control unit 41 in advance. At this time, the value of the degree-of-vacuum measuring device 42 becomes a value smaller than the vacuum upper limit value set in the control unit 28 in advance.

  On the other hand, the inert gas supply line L13 side is in a standby state. Specifically, the inert gas supply source 21 is opened, the pressure reducing valve 23 is adjusted to a predetermined pressure, and the flow rate regulator 24 is adjusted to a predetermined gas flow rate.

Next, an operation method of the exhaust gas treatment system 40 at the time of abnormality will be described.
When the degree of vacuum measured by the degree-of-vacuum measuring device 42 exceeds the vacuum upper limit value set in advance in the control unit 28 (the vacuum deteriorates), an automatic open / close valve 17 receives a signal from the control unit 28. Will open automatically. At the same time, the automatic opening / closing valve 26 is opened, an inert gas is supplied to the ejector 18, and the inside of the pipe is kept at a negative pressure. At substantially the same time, the exhaust fan 13 is stopped.
In this way, the exhaust gas is drawn into the dry-type abatement device 12 and can be removed even in an emergency.

In addition, the inert gas supplied to the ejector 18 can prevent gas from staying on the downstream side of the ejector 18.
Furthermore, even if the flammable gas contained in the exhaust gas is not harmed by the dry abatement device 12 (abatement device) and passes through the dry abatement device 12, it is diluted below the lower explosion limit. Can be released.
When the ejector 18 is activated, the degree of vacuum measured by the degree-of-vacuum measuring device 42 is lower than the vacuum upper limit value set in the control unit 28 in advance (the vacuum becomes better) and is not an emergency, but the ejector 18 It is necessary to continue supplying inert gas.

  According to the exhaust gas treatment system 40 of the second embodiment, the main exhaust line L11 that transports the exhaust gas discharged from the electronic device manufacturing apparatus 11 (equipment), and the dry type abatement provided in the main exhaust line L11. It is provided in a portion of the apparatus 12 (detoxifying apparatus) and the main exhaust line L12 located at the rear stage of the dry detoxifying apparatus 12, and is controlled so as to have a preset first exhaust capacity A during normal times. An exhaust fan 13 (exhaust section) that keeps the pressure in the main exhaust line L11 at a negative pressure, a vacuum degree measuring device 42 that is provided in the main exhaust line L11 and measures the degree of vacuum in the main exhaust line L11, and a dry type It is connected to a main exhaust line L11 located between the abatement device 12 and the exhaust fan 13, and the sub-flow through which the exhaust gas flows when the degree of vacuum in the main exhaust line L11 exceeds a preset vacuum value. The automatic open / close valve 17 (provided in the gas line L12 and the auxiliary exhaust line L12 is normally closed and is opened when the degree of vacuum in the main exhaust line L11 exceeds a preset vacuum value. An automatic on-off valve) and an auxiliary exhaust line L12, and an ejector 18 provided in a portion located at the rear stage of the automatic on-off valve 17 and the ejector 18 are connected to the main exhaust line L11 with a predetermined vacuum value. When the degree of vacuum exceeds the inert gas supply line L13 (compressed gas supply line) for supplying an inert gas (compressed gas) to the ejector, the degree of vacuum measured by the degree-of-vacuum measuring device 42, and a preset vacuum The automatic open / close valve 17 and the control unit 28 for controlling the inert gas supply line L13 based on the values are provided.

 According to the exhaust gas processing system 40 of the second embodiment having the above-described configuration, the exhaust fan 13 is not reduced in exhaust capacity without providing a spare exhaust fan or an uninterruptible power supply. However, when the degree of vacuum in the main exhaust line L11 exceeds a preset vacuum value (when the vacuum deteriorates), an abnormal condition is detected, and an inert gas is supplied to the ejector 18 in an appropriate amount, thereby eliminating dry detoxification. The exhaust gas can be drawn into the apparatus 12 and the detoxification process can be continued, and the inside of the pipe through which the exhaust gas flows can be kept at a negative pressure.

In addition, the inert gas used in the ejector 18 can prevent gas from staying on the downstream side of the ejector 18.
Furthermore, in the unlikely event that the abatement capability of the dry abatement device 12 is reduced and the combustible gas contained in the exhaust gas flows downstream, the inert gas supplied to the ejector 18 is diluted below the lower limit of explosion. Can be released.

  The preferred embodiments of the present invention have been described in detail above, but the present invention is not limited to such specific embodiments, and within the scope of the present invention described in the claims, Various modifications and changes are possible.

 For example, in the second embodiment described above, the control unit 41 that controls the exhaust fan 13 and the control unit 28 that controls the automatic open / close valves 17 and 26 are separated (in other words, two controls). However, instead of the control units 28 and 41, one control unit having the same function as that of the control units 28 and 41 is provided, and the one control unit causes an abnormality. The determination of time may be a mode in which the state of the exhaust fan 13 and the degree of vacuum in the main exhaust line L11 are double checked.

Further, when the automatic open / close valves 17 and 26 have a specification of “closed” when energized and “open” when deenergized, the automatic open / close valves 17 and 26 are automatically opened due to a power failure.
Thereby, in an emergency caused by a power failure, the exhaust gas can be drawn into the abatement device by the function of the ejector, so that the detoxification can be continued, and the inside of the pipe through which the exhaust gas flows may be kept at a negative pressure. .

  The present invention relates to an exhaust gas processing system for processing exhaust gas discharged from equipment (for example, an electronic device manufacturing apparatus used for forming a thin film constituting an electronic device such as a semiconductor, a liquid crystal, a solar cell, and an LED). It is applicable to.

  DESCRIPTION OF SYMBOLS 10,40 ... Exhaust gas processing system, 11 ... Electronic device manufacturing apparatus, 12 ... Dry-type abatement device, 13 ... Exhaust fan, 15 ... Check valve, 17, 26 ... Automatic on-off valve, 18 ... Ejector, 21 ... Inactive Gas supply source, 23 ... pressure reducing valve, 24 ... flow rate regulator, 28, 41 ... control unit, 42 ... vacuum measuring device, C1 to C4 ... signal line, L11 ... main exhaust line, L12 ... sub exhaust line, L13 ... Inert gas supply line

Claims (6)

A main exhaust line for transporting exhaust gas discharged from the facility;
An abatement device provided in the main exhaust line;
The main exhaust line is provided in a portion located at the rear stage of the abatement device, and is controlled so as to have a first exhaust capacity set in advance, and the pressure in the main exhaust line is controlled. An exhaust section that maintains a negative pressure;
It is connected to the main exhaust line located between the abatement device and the exhaust unit, and the exhaust gas flows in a period in which the exhaust unit has an exhaust capability lower than a preset second exhaust capability. An exhaust line;
An automatic on-off valve provided in the auxiliary exhaust line, which is normally closed and opened during a period when the exhaust capacity of the exhaust section is lower than the second exhaust capacity;
Of the auxiliary exhaust line, an ejector provided at a portion located at the rear stage of the automatic opening / closing valve,
A compressed gas supply line that is connected to the ejector and that supplies compressed gas to the ejector during a period when the exhaust capacity of the exhaust section is less than the second exhaust capacity;
The first exhaust capacity and the second exhaust capacity are preset, and the control unit for controlling the exhaust unit, the automatic on-off valve, and the compressed gas supply line;
An exhaust gas treatment system comprising: A main exhaust line for transporting exhaust gas discharged from the facility;
An abatement device provided in the main exhaust line;
The main exhaust line is provided in a portion located at the rear stage of the abatement device, and is controlled so as to have a first exhaust capacity set in advance, and the pressure in the main exhaust line is controlled. An exhaust section that maintains a negative pressure;
A sub-exhaust line connected to the main exhaust line located between the abatement apparatus and the exhaust unit, and through which the exhaust gas flows during a power failure;
An automatic on-off valve that is provided in the auxiliary exhaust line and is normally closed, and is opened in the event of a power failure;
Of the auxiliary exhaust line, an ejector provided at a portion located at the rear stage of the automatic opening / closing valve,
A compressed gas supply line connected to the ejector for supplying compressed gas to the ejector at the time of the power failure;
A control unit configured to control the exhaust unit, the first exhaust capability being set in advance;
An exhaust gas treatment system comprising: A main exhaust line for transporting exhaust gas discharged from the facility;
An abatement device provided in the main exhaust line;
The main exhaust line is provided in a portion located at the rear stage of the abatement device, and is controlled so as to have a preset first exhaust capacity in a normal state, thereby reducing the pressure in the main exhaust line. An exhaust to keep the pressure,
A vacuum degree measuring device that is provided in the main exhaust line and measures the degree of vacuum in the main exhaust line;
A sub exhaust connected to the main exhaust line located between the detoxifying device and the exhaust unit, and through which the exhaust gas flows when the degree of vacuum in the main exhaust line exceeds a preset vacuum value. Line,
An automatic on-off valve that is provided in the auxiliary exhaust line, is normally closed, and is opened when the degree of vacuum in the main exhaust line exceeds a preset vacuum value;
Of the auxiliary exhaust line, an ejector provided at a portion located at the rear stage of the automatic opening / closing valve,
A compressed gas supply line connected to the ejector for supplying compressed gas to the ejector when the degree of vacuum in the main exhaust line exceeds the vacuum value;
The first exhaust capacity and the vacuum value are set in advance, and based on the degree of vacuum measured by the degree-of-vacuum measuring device, the automatic open / close valve and a control unit for controlling the compressed gas supply line;
An exhaust gas treatment system comprising:   The exhaust gas treatment system according to any one of claims 1 to 3, wherein the abatement apparatus is a dry abatement apparatus.   The exhaust gas processing system according to any one of claims 1 to 4, wherein the compressed gas is nitrogen gas or a rare gas.   6. The exhaust gas processing system according to claim 1, wherein the facility is an electronic device manufacturing apparatus used when manufacturing an electronic device.

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