KR20220147469A - fume hood - Google Patents

Abstract

The present invention relates to a laboratory fume hood. Specifically, air containing harmful gases discharged from a chamber is primarily filtered through a filter. In state of being compressed and stored inside a dual pressure tank, the primary filtered air is circulated and purified in each pressure tank. When a door is opened, the filtered air stored in the pressure tank is supplied to the inside of the chamber under its own pressure. In addition, an exhaust port is installed on a door side to face a chamber side so that the filtered air in the pressure tank is discharged through the chamber and the door at the same time. Accordingly, when the door is opened, harmful gases are prevented from entering a laboratory.

Description

laboratory fume hood

The present invention relates to a laboratory fume hood, and in detail, air containing harmful gases discharged from a chamber is first filtered through a filter, and then compressed and stored in a dual pressure tank inside each pressure tank. After purifying the primary filtered air by circulating it, when the door is opened, the filtered air stored in the pressure tank is supplied into the chamber at its own pressure. It relates to a laboratory fume hood that prevents harmful gas from flowing into the laboratory when the door is opened by allowing it to be discharged through the chamber and the door at the same time.

In general, a fume hood for an experiment is provided in the laboratories of various research institutes performing chemical experiments so that experiments in which harmful gases are generated can be performed in the laboratory space therein. Accordingly, by allowing various harmful gases generated during the experiment to be discharged to the outside of the laboratory, researchers conducting experiments can not only block contact with harmful gases, but also ensure the safety of researchers. it is for

In a conventional fume hood for experiments performing such a functional operation, an experiment space is formed inside a housing that becomes an exterior, and a suction means for inhaling various harmful gases generated when performing an experiment in the experiment space is mainly located on the upper side of the housing. is mounted

In addition, in order to block or expose the experimental space from the outside, a door sliding up and down is installed and configured.

At this time, the suction means is manufactured to be connected to a separate discharge pipe for discharging the inhaled harmful gas to the outside of the laboratory.

In such a conventional experimental fume hood, the suction and exhaust devices are always operated to prevent harmful gases from flowing into the laboratory during the experiment. is emitted as

However, these conventional experimental fume hoods were exposed to many problems in actual use. Conventional fume hoods for experiments have a problem in that the exhaust of harmful gases is not performed smoothly, so that researchers who conduct experiments are exposed to risks due to harmful gases as they are.

That is, in the conventional fume hood for experiments, the suction direction of the harmful gas using the suction means is in only one direction (the upper part of the fume hood), so that a vortex of the harmful gas occurs in the lower corner of the experiment space, and also in the inner space of the fume hood. There was a problem in that a vortex of air was generated, so that noxious gas was smoothly discharged.

In addition, the conventional experimental fume hood had a problem in that the intake external air could not be smoothly sucked. That is, the conventional experimental fume hood has disadvantages such as negative pressure acting inside the fume hood because the inflow of external air does not proceed smoothly through the open part of the front door in the process of inhaling external air.

Therefore, there is a need to develop a fume hood in which a certain amount of air from the external space is introduced so that the pressure inside and outside the fume hood is uniform, and the harmful gas remaining in the internal space can be smoothly discharged.

In order to solve this problem, a laboratory fume hood, which is Korean Patent Publication No. 10-1741627, is disclosed.

In the laboratory fume hood, as shown in FIG. 1 , air passages 131 and 141 are formed on both side surfaces 13a and 13b of the main body provided with the door 11 that can be opened and closed and the rear surface 14 edges, and the front (15) On the bottom, the guide 16 spaced apart from the bottom surface 12 at a predetermined interval is bent in a "memory" shape, and a small guide wing 160 having a 45 ° inclination at its tip is speech in which the air A chamber 10 that forms a flow path 161 and an air blocking plate 17 for inducing a vortex toward the hood 20 is installed on the upper surface of the chamber 10, which is disposed on the upper side of the chamber 10 to generate harmful effects in the chamber 10 An exhaust unit 20 equipped with a hood 21 for discharging substances, an air supply unit 30 provided with a blower 31 disposed on the lower side of the chamber 10, and installed on the rear surface of the chamber 10 An organic gas removal filter ( 61) and an air purification chamber 60 in which a HEPA filter 63 for removing fine dust is installed.

However, since the conventional laboratory fume hood purifies harmful gases only through the organic gas removal filter and HEPA filter installed in the air purification room, and supplies it back to the chamber, the air purification ability is relatively poor, and the air is discharged separately from the door. Because it does not, there is a problem that the harmful gas in the chamber is leaked into the laboratory.

Domestic Registered Patent Publication No. 10-1741627 Domestic Registered Patent Publication No. 10-1315249

The present invention is to solve the above problems, the air containing the harmful gas discharged from the chamber is first filtered through a filter, and then compressed and stored inside the dual pressure tanks. An object of the present invention is to provide a laboratory fume hood that allows the filtered air stored in the pressure tank to be supplied into the chamber under its own pressure when the door is opened after secondary filtering while circulating the primary filtered air.

In addition, the present invention installs an inclined air supply port at the upper and lower parts of the door to face the chamber so that the filtered air of the pressure tank is discharged simultaneously through the chamber and the upper and lower parts of the door. There is another purpose to providing a fume hood.

Features of the present invention for achieving the above object,

a chamber having a door sliding to an upper surface, an air supply passage is partitioned by a partition wall at a lower portion of the floor, air supply holes in the form of a perforated network are formed in the floor surface, and air supply ports are formed in upper and lower portions of the door; an exhaust hood installed at the upper end of the chamber to discharge harmful substances generated in the chamber; a filtration chamber integrally formed on a side surface of the chamber; a filter module installed inside the filtration chamber and primarily filtering air containing harmful gases through the exhaust hood; It is connected to the filter module and provides suction pressure so that the air containing the harmful gas in the chamber is sucked and passed through the filter module, and the air containing the harmful gas filtered primarily by the filter module is sucked and pressurized exhaust air pump; And it is installed inside the filtration chamber, is connected to the air pump, compresses and stores air containing harmful gas that is first filtered and discharged under pressure, and after secondary filtering while circulating the compressed and stored air, the air supply hole of the chamber and It is characterized in that it includes a pressure tank module that discharges under its own pressure to the inlet.

Here, the laboratory fume hood further includes a door sensor installed on the door to detect opening and closing of the door and to operate the air pump when the door is opened.

Here, the air supply port of the chamber is installed to have an inclination toward the chamber.

Here, the air supply hole of the chamber is formed to have a smaller diameter on the door side to discharge more air from the inside of the chamber to form an air flow from the door side to the inside.

Here, the pressure tank module includes first and second pressure tanks formed in a donut shape to form a circulation passage, an activated carbon filter is installed therein at regular intervals, and a circulation fan is installed therein; a pressure sensor for measuring the respective pressures of the first and second pressure tanks; and a controller for compressing air into the second pressure tank or the first pressure tank when air is compressed to a reference pressure or more in the first pressure tank or the second pressure tank through the pressure sensor.

Here, an electric damper for introducing external air is installed in the air supply passage of the chamber, and the controller closes the door in a state where the pressure of the first pressure tank or the second pressure tank is less than a reference value through the pressure sensor When the chamber is closed, the electric damper is opened to introduce air into the chamber, and the air is compressed and stored in the first pressure tank or the second pressure tank.

According to the present inventor's laboratory fume hood configured as described above, air containing harmful gas discharged from the chamber is first filtered through a filter, and then compressed and stored inside the dual pressure tanks. After secondary filtering while circulating the primary filtered air, when the door is opened, the filtered air stored in the pressure tank is supplied into the chamber at its own pressure, thereby increasing the filtration capacity of the exhausted harmful gas through secondary filtration and relatively increasing the filtration capacity of the pump. Energy can be saved by collecting the harmful gas by using the evaporator and storing it in a pressure tank and then supplying it to the chamber without a separate blower by the pressure of the compressed and stored air.

In addition, according to the present invention, by installing an inclined air supply port at the upper and lower parts of the door to face the chamber, the filtered air of the pressure tank is discharged simultaneously through the chamber and the upper and lower parts of the door, thereby preventing harmful gas from flowing into the laboratory when the door is opened. It can prevent them from being exposed to the dangers caused by harmful gases.

1 is a view showing the configuration of a conventional laboratory fume hood.
2 is a perspective view showing the configuration of a laboratory fume hood according to the present invention.
FIG. 3 is a partial cross-sectional view taken along line AA of FIG. 1 .
4 is a front view showing the configuration of a laboratory fume hood according to the present invention.
5 is a partial cross-sectional perspective view showing the configuration of a pressure tank in a laboratory fume hood according to the present invention.

Hereinafter, the configuration of the laboratory fume hood according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the terms described below are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification.

Figure 2 is a perspective view showing the configuration of a laboratory fume hood according to the present invention, Figure 3 is a partial cross-sectional view taken along line A-A of Figure 1, Figure 4 is a front view showing the configuration of a laboratory fume hood according to the present invention, Figure 5 is the present invention It is a partial cross-sectional perspective view showing the configuration of a pressure tank in a laboratory fume hood according to

2 to 5 , the laboratory fume hood 100 according to the present invention includes a chamber 110 , an exhaust hood 120 , a filtration chamber 130 , a filter module 140 , and an air pump ( 150 ), a pressure tank module 160 , and a door sensor 170 .

First, the chamber 110 is provided with a door (D) that has a space formed therein and slides to the upper surface, the air supply passage (S) is partitioned by a partition wall (W) at the bottom of the bottom surface, and has a perforated network shape on the floor surface. The air supply hole 111 is formed, and the air supply port 113 is formed in the upper and lower portions of the door (D).

In addition, the air supply port 113 is preferably installed with an inclination toward the chamber 110 to prevent the internal air from leaking out through the open portion of the door D during air supply, and the air supply hole 111 is By discharging more air from the inside of the chamber 110, the diameter of the door (D) side is formed smaller to form an air flow from the door (D) side to the inside, and the diameter of the inside of the chamber 110 is formed larger. it is preferable

In addition, an electric damper 115 for introducing external air is installed in the air supply passage S of the chamber 110 .

In addition, the exhaust hood 120 is installed at the inner upper end of the chamber 110 to discharge harmful substances generated in the chamber 110 .

Subsequently, the filtration chamber 130 is integrally formed on the side surface of the chamber 110 .

In addition, the filter module 140 is installed inside the filtration chamber 130 and primarily filters air containing harmful gases through the exhaust hood 120 . At this time, it is preferable that the filter module 140 includes at least two organic gas removal filters such as activated carbon and zeolite for removing organic harmful gases, and HEPA filters for removing fine dust.

In addition, the air pump 150 is installed inside the filtration chamber 130 and is connected to the filter module 140 , and provides suction pressure to suck the air containing the harmful gas in the chamber 110 to the filter module 140 . to pass through, and the air containing the harmful gas filtered primarily by the filter module 140 is sucked and discharged under pressure.

Further, the pressure tank module 160 includes a first pressure tank 161 , a second pressure tank 163 , a pressure sensor 165 , and a controller 167 .

The first pressure tank 161 is installed inside the filtration chamber 130, is formed in a donut shape to form a circulation flow path, an activated carbon filter (F) is installed therein at regular intervals, and a circulation fan (B) therein. This is installed, is installed inside the filtration chamber 130, is connected to the air pump 150, compresses and stores air containing harmful gas that is first filtered and discharged under pressure, and is secondary filtered while circulating the compressed and stored air. Then, it is discharged under its own pressure to the air supply hole 111 and the air supply port 113 of the chamber 110 . At this time, the activated carbon filter (F) is preferably installed to be replaceable.

The second pressure tank 163 is installed in parallel with the first pressure tank 161 in the filtration chamber 130 in the same size and shape as the first pressure tank 161 , and is connected to the air pump 150 for the primary Air containing harmful gas that is filtered and discharged under pressure is compressed and stored, and the compressed and stored air is circulated and filtered for secondary filtration, and then discharged under its own pressure to the air supply hole 111 and the air supply port 113 of the chamber 110 .

The pressure sensor 165 measures the respective pressures of the first and second pressure tanks 161 and 163 .

When the air is compressed above the reference pressure in the first pressure tank 161 or the second pressure tank 163 through the pressure sensor 165 , the controller 167 controls the second pressure tank 163 or the first pressure tank 161 . ) to compress the air. At this time, the controller 167 controls the chamber 110 by closing the door D in a state where the pressure of the first pressure tank 161 or the second pressure tank 163 is less than the reference value through the pressure sensor 165 . In this case, the electric damper 115 is opened to introduce air into the chamber 110 , and the air is compressed and stored in the first pressure tank 161 or the second pressure tank 163 .

In addition, on the supply side of the first pressure tank 161 and the second pressure tank 163 of the pressure tank module 160 , a three-way solenoid valve for changing the flow path according to the control of the controller 165 , and a check valve for preventing reverse flow , a water separator or a dehumidifying filter for removing condensed water is preferably installed, and a solenoid valve operated independently under the control of the controller 165 is preferably installed on the discharge side.

Subsequently, the door sensor 170 is installed on the door (D) as an optical sensor to detect the opening and closing of the door (D), and when the door (D) is opened, a control signal is transmitted to the controller (165) to transmit the control signal to the air pump (150). to operate

Hereinafter, the operation of the laboratory fume hood according to the present invention will be described in detail with reference to the accompanying drawings.

First, in the first pressure tank 161 of the pressure tank module 160, the stored compressed air is filtered and stored while passing through the activated carbon filter F while being circulated by the circulation fan B, and the second pressure tank 163 ) is empty.

In this state, when the door D is opened and sensed by the door sensor 170 , the controller 165 operates the air pump 150 and simultaneously operates the first pressure tank 161 of the pressure tank module 160 . Compressed air is supplied to the air supply hole 111 and the air supply port 113 of the chamber 110 at its own pressure.

Then, the harmful gas generated during the experiment in the chamber 110 is increased by the air supplied from the air supply hole 111 and the air supply port 113 and the suction pressure of the air pump 150 and sucked in the exhaust hood 120 . do. At this time, it is preferable that the supply air pressure and the suction pressure are designed to be balanced so that all the air in the chamber 110 can be sucked from the exhaust hood 120 .

The air containing the harmful gas sucked in from the exhaust hood 120 is first filtered while passing through the filter module 140 installed in the filtration chamber 130 , and then the second pressure tank 163 is controlled by the controller 165 . compressed and stored in

The compressed air stored in the second pressure tank 163 is filtered while passing through the activated carbon filter (F) while being circulated by the circulation fan (B).

On the other hand, when the door D is closed, the controller 167 measures the pressure of the second pressure tank 163 through the pressure sensor 165 and, if it is less than the reference value, opens the electric damper 115 to open the chamber 110 inside. By introducing air into the furnace, the air is compressed and stored in the second pressure tank 163 .

Then, when the door D is opened again, the controller 167 measures the pressure of the first pressure tank 161 through the pressure sensor 165, and if it is less than the minimum value, the compressed air stored in the second pressure tank 163 is supplied. , and when the internal pressure of the first pressure tank 161 falls below the minimum value during the air supply, the air is supplied with the compressed air stored in the second pressure tank 163 .

Furthermore, when the pressure value of the first and second pressure tanks 163 is less than the minimum value, the controller 167 opens the electric damper 115 to supply air to the first pressure tank 161 or the second pressure tank 163 . compress and save

And, the controller 167 basically controls the first pressure tank 161 and the second pressure tank 163 to operate alternately with each other.

The present invention may be variously modified and may take various forms, and in the detailed description of the invention, only specific embodiments thereof have been described. However, it is to be understood that the present invention is not limited to the particular form recited in the detailed description, but rather, it is to be understood to cover all modifications and equivalents and substitutions falling within the spirit and scope of the invention as defined by the appended claims. should be

110: chamber 120: exhaust hood
130: filtration chamber 140: filter module
150: air pump 160: pressure tank module
170: door sensor

Claims (6)

a chamber having a door sliding to an upper surface, an air supply passage is partitioned by a partition wall at a lower portion of the floor, air supply holes in the form of a perforated network are formed in the floor surface, and air supply ports are formed in upper and lower portions of the door;
an exhaust hood installed at the upper end of the chamber to discharge harmful substances generated in the chamber;
a filtration chamber integrally formed on a side surface of the chamber;
a filter module installed in the filtration chamber and primarily filtering air containing harmful gases through the exhaust hood;
It is connected to the filter module and provides suction pressure so that the air containing the harmful gas in the chamber is sucked and passed through the filter module, and the air containing the harmful gas filtered primarily by the filter module is sucked and pressurized exhaust air pump; and
Installed in the filtration chamber, connected to the air pump, compressed and stored air containing harmful gas that is first filtered and discharged under pressure, circulates the compressed and stored air and performs secondary filtration, and then connects to the air supply hole of the chamber A laboratory fume hood comprising a pressure tank module evacuating the instrument under its own pressure. The method of claim 1,
The laboratory fume hood,
The laboratory fume hood further comprising a door sensor installed on the door to detect the opening and closing of the door and operating the air pump when the door is opened. The method of claim 1,
The air inlet of the chamber,
Laboratory fume hood, characterized in that it is installed to have an inclination in the direction of the chamber. The method of claim 1,
The air supply hole of the chamber,
Laboratory fume hood, characterized in that the diameter of the door side is formed smaller so that more air is discharged from the inside of the chamber to form an air flow from the door side to the inside. The method of claim 1,
The pressure tank module,
first and second pressure tanks formed in a donut shape to form a circulation passage, an activated carbon filter is installed therein, and a circulation fan is installed therein;
a pressure sensor for measuring the respective pressures of the first and second pressure tanks; and
and a controller for compressing air into the second pressure tank or the first pressure tank when air is compressed to a reference pressure or more in the first pressure tank or the second pressure tank through the pressure sensor. 6. The method of claim 5,
In the air supply passage of the chamber,
An electric damper that draws in outside air is installed,
The controller is
When the chamber is closed by closing the door while the pressure of the first pressure tank or the second pressure tank is less than the reference value through the pressure sensor, the electric damper is opened to introduce air into the chamber, A laboratory fume hood for compressed air storage in a pressure tank or a second pressure tank.

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