KR102640382B1 - a device for fume hood which embedded scrubber - Google Patents

Abstract

In the present invention, the air discharged from the experimental space of the fume hood is supplied to a scrubber unit through a duct to remove contaminants and then discharged to the outside through an exhaust pipe, and the scrubber unit includes a plurality of nozzles that collect contaminants by scattering water. It consists of a structure filled with polling that collects contaminants in the contaminated water, and the contaminated water is supplied to the water tank after passing through a reprocessing unit that neutralizes the contaminated water, and the water collected in the water tank is recycled through a pump and nozzle. This relates to a fume hood with a built-in scrubber installed for supply.

Description

Fume hood with built-in scrubber {a device for fume hood which embedded scrubber}

In the present invention, the air discharged from the experimental space of the fume hood is supplied to a scrubber unit through a duct to remove contaminants and then discharged to the outside through an exhaust pipe, and the scrubber unit includes a plurality of nozzles that collect contaminants by scattering water. It consists of a structure filled with polling that collects contaminants in the contaminated water, and the contaminated water is supplied to the water tank after passing through a reprocessing unit that neutralizes the contaminated water, and the water collected in the water tank is supplied through a pump and nozzle. This relates to a fume hood with a built-in scrubber installed for resupply.

Generally, a fume hood is installed in a place or laboratory where hazardous chemicals are handled and is an essential facility to maintain a comfortable laboratory working environment by forcibly exhausting gases such as gases, odors, and vapors harmful to the human body to the outside. A work plate is provided to form a work space, a door is provided at the front to open and close up and down, and an exhaust duct is provided at the top to exhaust harmful gases generated in the work space.

Experiments are conducted using experimental equipment placed on a work plate with the door provided on the front of the fume hood configured as described above properly opened, and the harmful gases generated during the experiment are exhausted to the outside through the exhaust duct.

As a way to purify such exhaust gas, a fume hood device technology with a scrubbing function is proposed in conventional patent No. 1324717, and the structure is as shown in Figure 1, the scrubbing unit 120, the device main body 100 It includes a collection chamber 127 including a water tank (not shown), a spray nozzle 125, a demister 126, and a polling 128, and the water in the water tank When the pump 124 operates, it flows to the spray nozzle 125 through the pipe P.

In addition, a collection chamber 127 is provided in the lower area of the spray nozzle 125 and is equipped with a plurality of polling 128 to collect adsorbed substances by water sprayed from the spray nozzle 125. A demister (126) is provided at the top of (125) to remove moisture in the vapor phase-changed by water sprayed by the spray nozzle (125).

In addition, the guide passage 130 is provided to ensure that harmful gases on the hood 110 side are well transmitted to the scrubbing unit 120, and is disposed between the hood 110 and the scrubbing unit 120, and is disposed between the hood 110 and the scrubbing unit 120, The processing gas is discharged through the discharge portion 107.

However, the scrubbing unit as described above is configured to purify harmful gases by scrubbing them and does not purify and recycle contaminated water, which has the disadvantage of lowering the purification effect.

In addition, the configuration of depositing contaminants through the spray nozzle 125 has the disadvantage that the collection effect is reduced due to micronized moisture.

The purpose of the present invention to improve the above-described conventional problems is to easily purify and discharge the polluted air generated in the fume hood, to enable recycling of the water used for purification, and to remove contaminants from the polluted air into water. The purpose is to provide a fume hood with a built-in scrubber that operates in response to the opening of the door and is installed to adjust the water supply amount in response to the wind speed.

In order to achieve the above object, the present invention supplies the air discharged from the experimental space of the fume hood to a scrubber unit through a duct to remove contaminants and is then discharged to the outside through an exhaust pipe, and the scrubber unit scatters water to remove contaminants. It is composed of a plurality of nozzles that collect and is filled with polling that collects contaminants in the contaminated water. The contaminated water is supplied to the water tank after passing through a reprocessing unit that neutralizes the contaminated water, and the contaminated water is collected in the water tank. A fume hood with a built-in scrubber is provided to re-supply water through a pump and nozzle.

In addition, the water tank is connected to a resupply pipe through which make-up water is supplied, and the reprocessing unit provides a fume hood with a built-in scrubber connected to a neutralization unit installed to supply hydrogen or base at regular intervals.

In addition, the duct provides a scrubber-built fume hood to which a water separation unit having a plurality of collision plates is further connected to remove moisture in the air discharged from the scrubber.

In addition, the nozzle is spiral-shaped and has a diameter that gradually decreases from the top to the bottom, providing a fume hood with a built-in scrubber installed to scatter the supplied water.

Continuing, a fume hood with a built-in scrubber is provided, further comprising a pretreatment separation unit on one side of the reprocessing unit, which is integrated with a cyclone and a U trap.

In addition, the duct provides a scrubber-built fume hood that is equipped with a pollution detection sensor and is installed to re-supply the fume hood inside the scrubber through a bypass pipe in case of contamination.

As described above, according to the present invention, the contaminated air generated in the fume hood can be easily purified and discharged, the water used for purification can be recycled, contaminants in the contaminated air can be easily collected with water, and the polluted air generated in the fume hood can be easily purified and discharged. As it operates in response, it has the effect of controlling the amount of water supply in response to the surface wind speed.

Figure 1 is a block diagram showing a conventional fume hood.
Figure 2 is a perspective view showing a fume hood according to the present invention.
Figure 3 is a connection state diagram of the fume hood according to the present invention.
Figure 4 is a block diagram showing a fume hood according to the present invention.
Figure 5 is a schematic diagram showing the pretreatment separation unit of the fume hood according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail based on the attached drawings.

As shown in Figures 2 to 5, the fume hood 100 of the present invention is provided with an experiment space (S) on the inside and a fume hood body 110 with a sliding door 130 is installed in front of it.

At this time, the air discharged from the experimental space is supplied to the scrubber unit 200 through the duct 150 to remove contaminants, and is then discharged to the outside through the exhaust pipe 170 having a ventilation fan 175.

In addition, the scrubber unit 200 is composed of a plurality of nozzles 210 that collect contaminants by scattering water and a poling 230 that collects contaminants in contaminated water.

At this time, the nozzle 210 is spiral-shaped and has a diameter that gradually decreases from the top to the bottom, and is installed to scatter the supplied water.

In addition, the contaminated water is installed to be supplied to the water tank 400 after passing through a reprocessing unit 300 that neutralizes the contaminated water.

At this time, the water collected in the water tank 400 is installed to be re-supplied to the scrubber unit 200 through the pump 410 and the nozzle 210.

In addition, the water tank 400 is connected to a resupply pipe 500 through which supplemental water is supplied, and the reprocessing unit 300 is connected to a neutralization tank 370 installed to supply hydrogen or base at regular intervals.

In addition, the exhaust pipe 170 is further connected to a water separation unit 600 having a plurality of collision plates 610 to remove moisture in the air discharged from the scrubber.

Continuing, on one side of the reprocessing unit 300, a preprocessing separation unit 700 is further provided, in which a cyclone 710 and a U trap 730 are sequentially provided.

In addition, the exhaust pipe 170 may be equipped with a pollution detection sensor 176 and installed to re-supply the inside of the scrubber through the bypass pipe 177 when contaminated.

The operation of the present invention configured as described above will be described.

As shown in Figures 2 to 5, the fume hood system 100 of the present invention is provided with an experiment space (S) and opens the door in the fume hood body 110 having a sliding door 130 in front of it. When conducting an experiment, dust in the contaminated air generated in the experimental space (S) is collected and removed by counterflow and spray under the condition of a constantly wet airflow.

Also, during the spraying operation, contaminants such as dust are collected in water, and the collected water is first collected through the filled poling 230.

In addition, the contaminated water is supplied to the water tank 400 after secondary treatment while passing through a reprocessing unit 300 that neutralizes the contaminated water, and the water collected in the water tank 400 is supplied to the pump 410 and the nozzle. It is circulated through the operation of resupplying to the scrubber unit 200 through (210).

At this time, the air discharged from the experimental space is supplied to the scrubber unit 200 through the duct 150 to remove contaminants, and then is discharged to the outside without contaminants through the exhaust pipe 170 having a ventilation fan 175. It is discharged to .

In addition, the scrubber unit 200 is filled with a plurality of nozzles 210 that scatter water to collect contaminants and a polling 230 that collects contaminants in contaminated water, making it easy to scatter water into the air. Contaminants contained in water are collected by polling.

At this time, the nozzle 210 is spiral-shaped and has a diameter that gradually decreases from the top to the bottom to facilitate the spray supply.

In addition, the contaminated water is installed to be supplied to the water tank 400 after passing through the reprocessing unit 300, which neutralizes the contaminated water by supplying hydrogen or base at regular intervals, and is included in the water that has been primarily treated by polling. Neutralize the contaminated contaminants once again.

In addition, on one side of the reprocessing unit 300, a pretreatment separation unit 700 including a cyclone 710 and a U trap 730 is further provided, so that sludge with a high specific gravity in the water to be neutralized is sedimented. Ask them to collect it.

At this time, the water collected in the water tank 400 is installed to be re-supplied to the scrubber unit 200 through the pump 410 and the nozzle 210, and the water tank 400 has a resupply pipe 500 through which supplemental water is supplied. It is connected to replenish water that is naturally lost.

In addition, the cyclone 710 is connected so that the pipe discharged when water is supplied to the U trap is exposed to the water, thereby preventing foreign substances with a large specific gravity from being discharged into the U trap.

In addition, the exhaust pipe 170 is further connected to a water separation unit 600 having a plurality of collision plates 610 to remove moisture in the air discharged from the scrubber unit.

In addition, the exhaust pipe 170 is equipped with a pollution detection sensor 176, so that when polluted, it is not immediately discharged into the atmosphere, but is installed to re-supply the inside of the scrubber through the bypass pipe 177 to perform the collection operation by water. It is to be performed repeatedly.

100...fume hood 110...fume hood body
130...sliding door 150...duct
170...exhaust pipe 200...scrubber unit
210...Nozzle 230...Poling
300...reprocessing unit 400...water tank
500...resupply pipe 600...water separation unit
700...preprocessing unit

Claims (6)

The air discharged from the experimental space of the fume hood is supplied to the scrubber unit through the duct to remove contaminants, and then discharged to the outside through the exhaust pipe.
The scrubber unit is composed of a plurality of nozzles that collect contaminants by scattering water and a polling ring that collects contaminants in contaminated water.
The contaminated water that has passed through the scrubber unit is supplied to the water tank after passing through a reprocessing unit that neutralizes the contaminated water,
The water collected in the water tank is installed to be re-supplied to the scrubber unit through a pump and nozzle,
The nozzle is spiral-shaped and has a diameter that gradually decreases from the top to the bottom,
On one side of the reprocessing unit, a preprocessing separation unit consisting of a cyclone and a U trap in a sequentially connected structure is installed,
A fume hood with a built-in scrubber in which the pipe for discharge to the U trap is exposed and connected to the water of the cyclone. The method of claim 1, wherein the water tank is connected to a resupply pipe through which supplemental water is supplied,
The reprocessing unit is a fume hood with a built-in scrubber, characterized in that it is connected to a neutralization unit installed to supply hydrogen or base at regular intervals. The scrubber-built fume hood according to claim 1, wherein the duct is further connected to a water separation unit having a plurality of collision plates to remove moisture in the air discharged from the scrubber. delete delete The scrubber-built fume hood according to claim 1, wherein the duct is equipped with a contamination detection sensor and is installed to re-supply the inside of the scrubber through a bypass pipe when contamination occurs.

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