KR102570154B1 - Hydrostatic pressure device comprising a hydrogen sulfide gas detector - Google Patents

Abstract

The present invention relates to a hydrostatic pressure device equipped with a hydrogen sulfide sensor, and more particularly, to a hydrostatic pressure device for compression molding an object to be processed containing sulfide located inside a containing portion by using the pressure of a pressurized medium, detecting the generation of hydrogen sulfide. In addition, it relates to a hydrostatic pressure device capable of preventing safety accidents of workers due to exposure to hydrogen sulfide by discharging generated hydrogen sulfide to the outside of the accommodation unit without an opening operation of the sealed accommodation unit.

Description

Hydrostatic pressure device equipped with a hydrogen sulfide detector {HYDROSTATIC PRESSURE DEVICE COMPRISING A HYDROGEN SULFIDE GAS DETECTOR}

The present invention relates to a hydrostatic pressure device equipped with a hydrogen sulfide sensor, and more particularly, to compress a processing target containing sulfide under hydrostatic pressure, but detecting and responding to hydrogen sulfide generated by contact between the processing target and water It is about a hydrostatic pressure device.

The hydrostatic pressure device is a device that compresses and molds the object to be processed through the pressure of accommodating the object to be processed in the vessel and injecting a pressurized medium into the vessel.

At this time, there is an all-solid-state battery containing sulfide among the processing targets subjected to compression molding using a hydrostatic pressure device. When the sulfide meets a pressurized medium containing oxygen due to breakage or damage of the processing target during compression molding and any force, hydrogen sulfide is formed. will occur

Hydrogen sulfide is a highly toxic, flammable gas that can cause respiratory arrest if exposed to high concentrations.

The problem is that during compression molding of an object containing sulfide, even if hydrogen sulfide is generated, the operator does not recognize it, so when the operator opens the closed vessel after compression molding of the object to be processed, the operator is exposed to hydrogen sulfide, which can lead to safety accidents. Not only is there a risk of occurrence, but the pressurized medium inside the vessel in which hydrogen sulfide is generated is contaminated and cannot be reused, and there is a risk of contamination when discharged to the outside.

Republic of Korea Patent Registration No. 10-1638092 (2016.07.04.)

The present invention has been made to solve the problems described above, and an object of the present invention is a hydrostatic pressure device for compression molding a processing target containing sulfide located inside a receiving part by using the pressure of a pressurized medium, It is to provide a hydrostatic pressure device capable of preventing safety accidents of workers due to exposure to hydrogen sulfide since hydrogen sulfide can be discharged from the inside of the accommodating unit without opening operation of the sealed accommodating unit while detecting the occurrence.

The hydrostatic pressure device according to the present invention includes a vessel 150 having a receiving portion 100 in which a processing target containing sulfide is accommodated; a pressurized medium supply unit 200 which introduces a pressurized medium into the housing unit 100 for compression molding of an object to be processed containing sulfides in the housing unit 100; And a hydrogen sulfide generation response unit 300 including a detection unit 310 for detecting the generation of hydrogen sulfide in the accommodation unit 100 and a processing unit 320 for discharging hydrogen sulfide from the accommodation unit 100; It is characterized by doing.

In addition, the sensing unit 310 is characterized in that it consists of a pH detector for measuring the hydrogen ion concentration in the pressurized medium.

In addition, the sensing unit 310 is characterized in that it consists of a sulfur detector for measuring the sulfur concentration in the pressurized medium.

In addition, the processing unit 320 is formed to communicate with the outside at a selected position of the receiving unit 100 and the first pressurized medium discharge unit 321-1 for discharging the pressurized medium inside the housing unit 100. A first processing unit including a hydrogen sulfide discharge pipe 321-2 and a discharge vacuum pump 321-3 provided to discharge hydrogen sulfide inside the accommodating unit 100 through the hydrogen sulfide discharge pipe 321-2. It is characterized in that, including (321).

In addition, the first processing unit 321 is characterized in that it further comprises a discharge sensor for measuring the amount of hydrogen sulfide discharged through the hydrogen sulfide discharge pipe 321-2.

In addition, the first processing unit 321 further includes an outside air supply unit 321-4 that selectively supplies external air into the accommodating unit 100 in response to the operation of the discharge vacuum pump 321-3. It is characterized by doing.

In addition, the processing unit 320 sprays a neutralizing agent into the second pressurized medium discharge unit 322-1 for discharging the pressurized medium inside the housing unit 100 and into the housing unit 100 from which the pressurized medium is discharged. And a second processing unit 322 including a neutralizer injection unit 322-2 for discharging hydrogen sulfide inside the accommodation unit 100 through the second pressurized medium discharge unit 322-1. do.

In addition, the first processing unit 321 is connected to the first pressurized medium discharge unit 321-1 and the hydrogen sulfide discharge pipe 321-2, and a first post-processing unit for purifying the incoming pressurized medium and hydrogen sulfide ( 321-5) is characterized in that it further comprises.

In addition, the second post-processing unit 322 is connected to the second pressurized medium discharge unit 322-1 and further includes a second post-processing unit 322-3 for purifying the incoming pressurized medium and hydrogen sulfide. characterized by

In addition, the hydrostatic pressure device is characterized in that it further comprises an alarm unit for alarming when the sensing unit 310 detects hydrogen sulfide.

The hydrostatic pressure device according to the present invention is a hydrostatic pressure device for compression molding an object to be processed containing sulfide located inside the containing portion by using the pressure of a pressurized medium, and detects the generation of hydrogen sulfide and removes hydrogen sulfide without opening the sealed containing portion. Since it can be discharged from the inside of the accommodation unit, there is an advantage in preventing safety accidents of workers due to exposure to hydrogen sulfide.

In addition, since the hydrostatic pressure device according to the present invention can treat hydrogen sulfide without the operator opening the inside of the sealed housing, the treatment operation according to the generation of hydrogen sulfide can be performed quickly.

1 is a view showing a hydrostatic pressure device according to an embodiment of the present invention
2 is a view showing an example in which a pressure supply unit is added to FIG. 1
3 is a view showing a hydrostatic pressure device according to another embodiment of the present invention
4 is a view showing an example in which a first post-processing unit is added to FIG. 1;
5 is a view showing an example in which a second post-processing unit is added to FIG. 3;

Hereinafter, a hydrostatic pressure device according to an embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

1 is a view showing a hydrostatic pressure device according to an embodiment of the present invention, FIG. 2 is a view showing an example in which a pressure supply unit is added to FIG. 1, and FIG. 3 shows a hydrostatic pressure device according to another embodiment of the present invention. FIG. 4 is a view showing an example in which a first post-processing unit is added to FIG. 1 , and FIG. 5 is a view showing an example in which a second post-processing unit is added to FIG. 3 .

Referring to FIGS. 1 and 2 , the hydrostatic pressure device 1000 according to an embodiment of the present invention introduces a processing target, such as an all-solid-state battery containing sulfide, into the housing 100, and then introduces a pressurized medium to In the apparatus for compression molding an object to be processed through the pressure thereof, when the sulfide reacts with water due to damage of the object to be processed during compression molding of the object to be processed and hydrogen sulfide is generated, it is sensed and hydrogen sulfide is generated inside the receiving part (100). It is a device that can be treated to prevent remaining in

This is because when hydrogen sulfide remains inside the accommodating part 100, when the accommodating part 100 is opened to take out the processing target from the accommodating part 100, the hydrogen sulfide gas inside the accommodating part 100 diffuses and harms the human body. This is to prevent safety accidents for nearby workers.

At this time, hydrogen sulfide may be removed to the extent that it does not harm the human body.

The hydrostatic pressure device 1000 according to an embodiment of the present invention largely includes a vessel 150, a pressurized medium supply unit 200, and a hydrogen sulfide generation response unit 300.

As described above, the accommodating portion 100 formed inside the vessel 150 is configured to provide a space in which an object to be processed including sulfide is accommodated and compressed. At this time, as shown in the drawing, the receiving part 100 may be a configuration of a hydrostatic pressure device that is sealed by fixing the cover on the upper part, lower part, or upper and lower parts, and pressurized medium such as water is supplied to compress and mold the object to be processed. A processing target in various hydrostatic pressure devices other than the configuration shown in the drawing, such as a hydrostatic pressure device that is made of an additional inner vessel and is sealed through sliding movement to an outer vessel that can seal it and compressively molds the processing target. It may be a chamber that is drawn in and compression molded.

The pressurized medium supply unit 200 is formed to supply a pressurized medium from an external or pressurized medium storage tank (not shown) to the inside of the receiving unit 100, and is received by using a pump from the pressurized medium storage unit that stores a separate pressurized medium. The pressurized medium may be supplied into the unit 100, and when the pressurized target is water, the pressurized medium may be supplied into the housing unit 100 using a pump while being directly connected to the water supply facility.

When the hydrogen sulfide generation response unit 300 generates hydrogen sulfide when the sulfide meets the pressurized medium due to damage or damage to the processing target due to compression molding or damage or damage to the processing target by any other force inside the receiving unit 100 , The generated hydrogen sulfide is harmful to the human body, so if the vessel 150 is opened without treating it, not only can human accidents occur, but also when a large amount of hydrogen sulfide is generated due to the increased contact between the pressurized medium and the sulfide, the vessel 150 Internal pressure, acidity, and temperature may have a great influence, increasing the risk of accidents.

Therefore, when hydrogen sulfide is generated inside the vessel, it is necessary to detect it, stop the compression molding operation, and then process it so that hydrogen sulfide does not remain inside the receiving part 100. ) and a processing unit 320 for processing hydrogen sulfide.

The sensing unit 310 is formed inside the accommodating unit 100 to detect the generation of hydrogen sulfide and is formed outside the accommodating unit 100 to detect the generation of hydrogen sulfide or the amount of remaining hydrogen sulfide. .

When the sensing unit 310 is formed outside the accommodating unit 100, it is also possible to detect the generation of hydrogen sulfide by installing the sensing unit 310 on a discharge line (piping) that discharges the pressurized medium inside the accommodating unit. It is also possible to detect the generation of hydrogen sulfide or the amount of remaining hydrogen sulfide by installing the sensing unit 310 on a separate gas discharge line (piping).

The sensing unit 310 may use a sensor that directly detects hydrogen sulfide gas, but when hydrogen sulfide gas is generated, the inside of the vessel is filled with a pressure medium or water and is a high-pressure environment, so the generated hydrogen sulfide gas is rapidly reduced to pressure. Most likely soluble in media or water.

The higher the pressure of the pressure medium, the higher the solubility of hydrogen sulfide. Because of the high solubility of hydrogen sulfide in water, most of the hydrogen sulfide gas is ionized (dissolved) in a very short time, and as a result, the acidity (pH) of the pressure medium increases. It gets lower.

In this case, if a sensor for detecting gas is installed, even if hydrogen sulfide is generated, hydrogen sulfide may not be detected or hydrogen sulfide may be detected only in a very short time.

For this reason, it is preferable that the sensing unit 310 includes a pH detector for measuring the hydrogen ion concentration in the pressurized medium. In one embodiment of the present invention, the sensing unit 310 is provided with a pH detector used to measure the degree of contamination, so that it can detect whether hydrogen sulfide is generated through a change in the acidity (pH) standard index of the pressurized medium.

In another embodiment of the present invention, the sensing unit 310 may include a sulfur detector that directly measures the sulfur concentration in the pressurized medium. As described above, since hydrogen sulfide gas is ionized (dissolved) within a very short time in a high-pressure environment, the generated hydrogen sulfide can be detected by measuring sulfur ions dissolved in water.

As described above, the sensing unit 310 is composed of a pH detector for measuring the hydrogen ion concentration in a pressurized medium made of water or a sulfur detector for measuring the sulfur concentration in a pressurized medium made of water, so that the inside of the accommodating part 100 It is possible to detect whether or not hydrogen sulfide is generated in

Of course, the sensing unit 310 may be composed of a sensor, a pH detector, or a sulfur detector for detecting hydrogen sulfide gas, and a sensor for detecting hydrogen sulfide gas for precise measurement of whether hydrogen sulfide is generated, a pH detector, and a sulfur detector. By having all of them, Through this comparison, precise detection of hydrogen sulfide generation can be made.

When the sensing unit 310 senses hydrogen sulfide, the processing unit 320 discharges the pressurized medium supplied to the accommodating unit 100 from the accommodating unit 100, and removes hydrogen sulfide remaining in the air inside the accommodating unit 100. It is controlled to be discharged to the outside of the accommodating part 100 .

1 and 2, the processing unit 320 includes a first pressurized medium discharge unit 321-1 for discharging a pressurized medium contaminated by dissolving hydrogen sulfide generated inside the housing unit 100, and a housing unit A hydrogen sulfide discharge pipe 321-2 coupled to a selected position of 100 to discharge gaseous hydrogen sulfide, and a receiving portion 100 from which pressurized medium is discharged through a first pressurized medium discharge portion 321-1 A first processing unit 321 comprising a discharge vacuum pump 321-3 provided to discharge gaseous hydrogen sulfide remaining inside to the outside of the receiving unit 100 through a hydrogen sulfide discharge pipe 321-2 can do.

That is, the first processing unit 321 stops the pressurization operation when the sensing unit 310 detects hydrogen sulfide in the accommodating unit 100, and discharges the contaminated pressurized medium through the first pressurized medium discharge unit 321-1. By discharging the hydrogen sulfide remaining in the containing part 100 from which the pressurized medium is discharged to the outside of the containing part 100 through negative pressure, the operator prevents safety accidents caused by the remaining hydrogen sulfide when the containing part 100 is opened. can do.

In other words, when the sensing unit 310 detects hydrogen sulfide, since the pressurized medium in the containing unit 100 is already contaminated, it cannot be reused. Accordingly, the flow to the pressurized medium supply unit 200 is blocked, the contaminated pressurized medium is discharged to the outside of the receiving unit 100 through the first pressurized medium discharge unit 321-1, and the remaining hydrogen sulfide is discharged through the vacuum pump 321 Through the operation of -3), the hydrogen sulfide discharge pipe 321-2 is discharged to the outside of the accommodating part 100.

At this time, since the first pressurized medium discharge unit 321-1 discharges the pressurized medium in liquid state, it is preferable to be provided at the lower part of the accommodating unit 100, and the hydrogen sulfide discharge pipe 321-2 is hydrogen sulfide in gaseous state. Since it discharges, it is preferable to be disposed on the top of the receiving part 100.

In addition, the first processing unit 321 may further include a discharge sensor (not shown) provided in the hydrogen sulfide discharge pipe 321-2 and capable of measuring the amount of hydrogen sulfide discharged through the hydrogen sulfide discharge pipe 321-2. can

A sensor that measures hydrogen sulfide gas can be used as an emission sensor.

That is, since the first processing unit 321 can acquire information by measuring the amount of hydrogen sulfide discharged in addition to detecting hydrogen sulfide inside the accommodation unit 100 through the detection unit 310 through the emission sensor, the detected hydrogen sulfide By adjusting the output of the discharge vacuum pump 321-3 according to the amount of , it is possible to minimize the energy consumed in discharging the hydrogen sulfide remaining in the accommodating part 100, and the hydrogen sulfide remaining in the accommodating part 100 In this state, the receiving part is opened, and it is possible to prevent workers from being injured by hydrogen sulfide.

At this time, the emission sensor may further include a display means capable of outputting the amount of hydrogen sulfide emitted to the operator.

In addition, since the first pressurized medium discharge unit 321-1 must be discharged so that the pressurized medium does not remain, it is preferable to be formed in the lower part of the receiving unit 100, and the hydrogen sulfide discharge pipe 321-2 is Since hydrogen sulfide, which is a gas, is discharged from the accommodating part 100 using vacuum pressure, it is preferably formed on the top or side of the accommodating part 100.

In addition, the first processing unit 321 may further include an outside air supply unit 321-4 capable of supplying fresh air from the outside into the receiving unit 100. That is, the first processing unit 321 discharges the remaining hydrogen sulfide inside the accommodation unit 100 through the discharge vacuum pump 321-3. It is difficult to smoothly discharge the hydrogen sulfide remaining in the unit 100, or it may take a long time to discharge all the hydrogen sulfide.

To this end, the first processing unit 321 supplies a selected amount of outside air into the receiving part 100 through the outside air supply unit 321-4 in response to the operation of the discharge vacuum pump 321-3, thereby discharging the vacuum pump. (321-3) can smoothly discharge the sulfur gas remaining in the containing part 100 (see FIG. 2).

Referring to FIG. 3, the processing unit 320 injects a neutralizing agent into the second pressurized medium discharge unit 322-1 for discharging the pressurized medium when hydrogen sulfide is sensed, and the receiving unit 100 from which the pressurized medium is discharged to obtain hydrogen sulfide. The second processing unit 322 including a neutralizing agent injection unit 322-2 for discharging through the second pressurized medium discharge unit 322-1 may be formed.

That is, the second processing unit 322 stops the pressurization operation when the detection unit 310 detects hydrogen sulfide in the accommodating unit 100, and discharges the contaminated pressurized medium through the second pressurized medium discharge unit 322-1. After neutralizing the hydrogen sulfide remaining in the receiving unit 100 from which the pressurized medium is discharged through the neutralizing agent sprayed through the neutralizing agent spraying unit 322-2, it is received through the second pressurized medium discharging unit 322-1. By discharging to the outside of the unit 100, it is possible to prevent safety accidents caused by hydrogen sulfide remaining when the operator opens the housing unit 100.

At this time, since the neutralizing agent injection unit 322-2 is provided inside the receiving unit 100, it is of course necessary to be formed with such strength that damage or breakage due to its pressure does not occur when pressurized for compression molding of the object to be processed.

The neutralizing agent injected through the neutralizing agent injection unit 322-2 is a monohydric alcohol such as methanol, ethanol, or propanol, or a polar aprotic solvent such as tetrahydrofuran, dimethylformamide, or dimethylimidazoli dinon, methyl pyrrolidone, and the like. Of course, if hydrogen sulfide remaining in the accommodating unit 100 can be neutralized and treated according to washing and neutralization of the hydrogen sulfide remaining in the accommodating unit 100, it is possible to use various materials other than the above-mentioned materials.

Of course, in one embodiment of the present invention, the neutralizer injection unit 322-2, the first pressurized medium discharge unit 321-1, and the hydrogen sulfide discharge pipe 321-2 are all used to It is also possible to remove hydrogen sulfide more effectively.

4, the first processing unit 321 is connected to the first pressurized medium discharge unit 321-1 and the hydrogen sulfide discharge pipe 321-2, and the first pressurized medium discharge unit 321-1 and hydrogen sulfide A first post-processing unit 321-5 for purifying the contaminated pressurized medium and hydrogen sulfide introduced through the discharge pipe 321-2 is further included.

The first post-processing unit 321-5 is composed of a pressure tank for smooth inflow and storage of pressurized medium and hydrogen sulfide flowing through the first pressurized medium discharge unit 321-1 and the hydrogen sulfide discharge pipe 312-2. Preferred, but not limited.

The first post-processing unit 321-5 may include a sulfur treatment means (not shown) for treating sulfide and hydrogen sulfide, including activated carbon, etc., to purify and discharge sulfide and hydrogen sulfide through the sulfur treatment means. it is desirable

As shown in FIG. 4, the first pressurized medium discharge unit 321-1 for delivering pressurized medium in liquid state is connected to the upper part of the first post-processing unit 321-5, and discharges hydrogen sulfide for delivering hydrogen sulfide in gaseous state. The pipe 321-2 is connected to the lower part of the first post-processing unit 321-5 where the solution is submerged, so that the gas discharged through the hydrogen sulfide discharge pipe 321-2 passes through the first post-processing unit 321-2. It is preferable to pass through the solution contained in 5) to completely dissolve gaseous hydrogen sulfide, but the coupling position between the first pressurized medium discharge part and the hydrogen sulfide discharge pipe can be variously changed depending on the application.

In addition, a discharge pipe 340 equipped with a discharge valve 341 for selectively discharging the solution purified in the first post-processing unit 321-5 may be added, and the interior of the first post-processing unit 321-5 It may further include an acidity adjusting unit 330 for completely dissolving gaseous hydrogen sulfide by adjusting the acidity of the solution stored therein.

Referring to FIG. 5, the second processing unit 322 is connected to the second pressurized sales/discharge unit 322-1 like the first processing unit 321, and the contamination introduced through the second pressurized sales unit 322-1. It further includes a second post-processing unit 322-3 for purifying the compressed medium and the neutralizing agent sprayed into the housing unit 100 and cleaning the housing unit 100 through neutralization of hydrogen sulfide. .

Like the first post-processing unit 321-5, the second post-processing unit 322-3 has pressure for smooth inflow and storage of the pressurized medium, hydrogen sulfide, and neutralizer flowing through the second pressurized medium discharge unit 322-1. It is preferably made of a tank, and the first post-processing unit 321-5 and the second post-processing unit 322-3 may be integrated into one post-processing unit.

In addition, a sulfur treatment means for treating sulfides, hydrogen sulfide, and neutralizing agents including activated carbon may be provided, and it is preferable to purify and discharge sulfides, hydrogen sulfide, and neutralizing agents through the sulfur treatment means.

Although pumps, valves, etc. are not shown in detail in drawings such as FIGS. 4 and 5, various means for controlling the flow of fluid, such as pumps or valves, can be installed and used in various ways as needed.

In the hydrostatic pressure device according to an embodiment of the present invention, when the sensing unit 310 detects hydrogen sulfide in the accommodating unit 100, the pressurization operation must be stopped, the pressurized medium must be discharged, and the remaining sulfide water must be discharged. For rapid operation, an alarm unit (not shown) may further include an alarm unit (not shown) for alarming when the sensor unit 310 detects sulfide water in the housing unit 100 .

It is preferable that the alarm unit alarms the operator with a sound such as a warning sound, and in addition to this, it is preferably formed to alarm the operator through a flickering light or a separate display means through an output.

1000: hydrostatic pressure device
100: receiving part
200: pressurized medium supply unit
300: hydrogen sulfide generation response unit
310: sensing unit
320: processing unit
321: first processing unit
321-1: first pressurized medium discharge unit
321-2: Hydrogen sulfide discharge pipe
321-3: discharge vacuum pump
321-4: outdoor air supply unit
321-5: first post-processing unit
322: second processing unit
322-1: second pressurized medium discharge unit
322-2: neutralizing agent injection unit
322-3: second post-processing unit

Claims (9)

a vessel 150 having an accommodating portion 100 in which an object to be processed including sulfide is accommodated;
a pressurized medium supply unit 200 which introduces a pressurized medium into the housing unit 100 for compression molding of an object to be processed containing sulfides in the housing unit 100; and
A hydrogen sulfide generation countermeasure unit 300 including a detection unit 310 for detecting the generation of hydrogen sulfide in the accommodation unit 100 and a processing unit 320 for discharging hydrogen sulfide from the accommodation unit 100; ,
The processing unit 320
When detecting hydrogen sulfide, a first pressurized medium discharge unit 321-1 for discharging the pressurized medium inside the accommodating unit 100;
A hydrogen sulfide discharge pipe 321-2 formed to communicate with the outside at a selected position of the accommodating part 100;
A hydrogen sulfide detection unit including a first processing unit 321 including a discharge vacuum pump 321-3 provided to discharge hydrogen sulfide inside the accommodating unit 100 through the hydrogen sulfide discharge pipe 321-2 hydrostatic pressure device.
According to claim 1,
The sensing unit 310 is
A hydrostatic pressure device having a hydrogen sulfide sensing unit having a hydrogen sulfide sensing unit comprising a pH detector for measuring the hydrogen ion concentration in the pressurized medium.
According to claim 1,
The sensing unit 310 is
A hydrostatic pressure device with a hydrogen sulfide sensor having a hydrogen sulfide sensor, comprising a sulfur detector for measuring the sulfur concentration in the pressurized medium.
delete According to claim 1,
The first processing unit 321
Hydrostatic pressure device with a hydrogen sulfide sensor, further comprising a discharge sensor for measuring the amount of hydrogen sulfide discharged through the hydrogen sulfide discharge pipe 321-2.
According to claim 1,
The first processing unit 321
Hydrostatic pressure device with a hydrogen sulfide sensor, further comprising an external air supply unit 321-4 for selectively supplying external air to the inside of the accommodation unit 100 in response to the operation of the discharge vacuum pump 321-3.
a vessel 150 having an accommodating portion 100 in which an object to be processed including sulfide is accommodated;
a pressurized medium supply unit 200 which introduces a pressurized medium into the housing unit 100 for compression molding of an object to be processed including sulfides in the housing unit 100; and
A hydrogen sulfide generation countermeasure unit 300 including a detection unit 310 for detecting the generation of hydrogen sulfide in the accommodation unit 100 and a processing unit 320 for discharging hydrogen sulfide from the accommodation unit 100; ,
The processing unit 320
When detecting hydrogen sulfide, a second pressurized medium discharge unit 322-1 for discharging the pressurized medium inside the accommodating unit 100;
A second processing unit including a neutralizing agent spraying unit 322-2 for discharging hydrogen sulfide through the second pressurized medium discharging unit 322-1 by injecting a neutralizing agent into the receiving unit 100 from which the pressurized medium is discharged ( 322), a hydrostatic pressure device with a hydrogen sulfide sensor.
According to claim 1,
The first processing unit 321
Hydrogen sulfide further comprising a first post-processing unit 321-5 connected to the first pressurized medium discharge unit 321-1 and the hydrogen sulfide discharge pipe 321-2 to purify the incoming pressurized medium and hydrogen sulfide. Hydrostatic pressure device equipped with a sensor.
According to claim 1 or 7,
The hydrostatic pressure device further includes an alarm unit for alarming when the sensing unit 310 detects hydrogen sulfide, the hydrostatic pressure device having a hydrogen sulfide sensor.

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