KR102242729B1 - Chamber for Diagnosis of Chemical Accident Damage - Google Patents

Abstract

The present invention relates to a chamber for diagnosing damage from a chemical accident, wherein the chamber for diagnosing damage from a chemical accident has a space portion formed therein, a sample collection port is formed on the side, and a gas detection device is formed on the upper surface thereof, and the An opening/closing door mounted on one surface of the housing so as to be opened and closed, a fan coupled to the upper surface of the housing, an input tube mounted on the upper side of the housing through the inside, and provided to be detachably attached to the housing, and the inner bottom surface of the housing And a mounting block on which a sample container in which a biological sample is accommodated is mounted on an upper surface, and the present invention provides a test chamber for testing damage caused by a chemical accident, but the pollution degree of the air and the biological sample Each can be measured and the damage can be quantified, thereby indirectly predicting the damage caused by ecosystem pollution and air pollution occurring after an actual chemical accident, and thus has a remarkable effect to enable appropriate response.

Description

Chamber for Diagnosis of Chemical Accident Damage}

The present invention relates to a chamber for diagnosing damage from a chemical accident, and more specifically, a test chamber for testing to quantify damage in the event of an actual chemical accident, and diagnosing the degree of damage by exposing an accident preparation material inside the chamber. It relates to a chamber for diagnosing damage from chemical accidents.

In general, hazardous chemicals are inevitably used in industrial facilities such as chemical plants, manufacturing plants, and steel mills.

When such hazardous chemicals are leaked to the outside, problems such as human damage and environmental destruction are caused.

Therefore, when hazardous chemicals from industrial facilities are leaked, it is very important to predict the damage in real time to minimize human damage.

However, in general, it is difficult to identify and quantify the damage caused by the specific gas generated in the event of a chemical accident disappears quickly.

To solve this problem, the necessity of developing a test chamber has emerged so that the degree of expected damage caused by an actual chemical accident can be calculated.

Korean Patent Publication, Registration No. 10-1017402

The present invention provides a test chamber for testing the damage caused by a chemical accident so that the damage can be quantified, so that the damage caused by ecosystem pollution and air pollution occurring after the actual chemical accident can be predicted and appropriate responses can be made. It is intended to provide a chamber for the diagnosis of damage caused by chemical accidents.

The present invention relates to a chamber for diagnosing damage from a chemical accident, wherein the chamber for diagnosing damage from a chemical accident has a space portion formed therein, a sample collection port is formed on the side, and a gas detection device is formed on the upper surface thereof, and the An opening/closing door mounted on one surface of the housing so as to be opened and closed, a fan coupled to the upper surface of the housing, an input tube mounted on the upper side of the housing through the inside, and provided to be detachably attached to the housing, and the inner bottom surface of the housing It is coupled to, and characterized in that it comprises a seating block on which the sample container in which the biological sample is accommodated is mounted on the upper surface.

In addition, the inlet pipe is a cylindrical hollow body with both ends closed, and an inlet port is formed in the upper outer periphery, and a plurality of hollow holes are formed in the lower outer periphery.

In addition, a stirring unit is provided on the bottom of the housing, and the stirring unit is disposed at a lower side of the mounting block to stir the biological sample seated on the mounting block.

Therefore, the present invention provides a test chamber capable of measuring the pollution degree of air and biological samples, so that the damage caused by a chemical accident can be quantified. There is a remarkable effect of indirectly predicting damage and allowing appropriate response.

1 is a perspective view of a chamber for diagnosing damage from a chemical accident according to the present invention.
2 is a front view of a chamber for diagnosing damage from a chemical accident according to the present invention.
3 is a left side view of a chamber for diagnosing damage from a chemical accident according to the present invention.
Figure 4 is a perspective view of a state in which the input tube is separated from the housing of the present invention.

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings.

The accompanying drawings are only examples shown to describe the technical idea of the present invention in more detail, so the technical idea of the present invention is not limited to the form of the accompanying drawings.

1 is a perspective view of a chamber for diagnosis of damage from a chemical accident of the present invention, FIG. 2 is a front view of a chamber for diagnosis of damage from a chemical accident of the present invention, and FIG. 3 is a left side view of the chamber for diagnosis of damage from a chemical accident of the present invention to be.

1 to 3, the chamber 1000 for diagnosing damage from a chemical accident of the present invention includes a housing 100, a fan 200, and a stirring unit 300.

In more detail, as shown in Fig. 1, the housing 100 has a rectangular parallelepiped shape with a space portion formed therein, and is an element provided so that the inner space portion can be sealed.

In the present invention, the housing 100 is provided in a rectangular parallelepiped shape, but the housing may be implemented in various forms.

In addition, in the present invention, the housing is made of a transparent acrylic material so that the experimenter can see the inside.

In addition, in the present invention, the upper surface of the housing 100 is opened and a separate cover 101 is used to open and close the upper surface of the housing 100, but this is only an example.

And it would be desirable to have a handle coupled to the cover 101 so that the cover 101 can be easily attached and detached.

Subsequently, a gas detection port 102 is formed on the upper surface or the cover 101 of the housing 100, and a sample collecting port 104 is formed on the side surface.

In particular, the sample collecting port 104 is formed on one surface of the housing close to the receiving block 160 to be described later, so that the experimenter collects a biological sample placed on the receiving block through the sample collecting port.

In addition, a separate stopper (not shown) is provided detachably in the gas detection device 102 and the sample collection port 104 so that the experimenter can selectively open and close the gas detection device and the sample collection port. .

In addition, a guide member (not shown) in the shape of a hollow body may be additionally coupled to the gas detection device 102 and the sample collection port 104.

The inner periphery of the guide member is formed to be tapered to have a smaller diameter toward the inside of the housing, and a stopper for opening and closing the inner periphery of the guide member is also tapered to have the same shape as the guide member. Efficiently close districts and sampling ports.

In addition, the guide member mounted on the sample collecting port 104 is provided to have an inclination that goes downward toward the inside of the housing, and is disposed on the inner bottom surface of the housing 100 through the sample collecting port 104 It would be desirable to facilitate access to the seating block 160.

In addition, a duct insertion port (not shown) may be formed to be openable and closed on the upper surface or the cover 101 of the housing 100 so that a duct may be mounted as necessary for ventilation inside the housing.

The duct insertion port is for ventilation and cleaning inside the housing.

In addition, the upper surface or the cover 101 of the housing 100 may be formed to open and close an injection hole (not shown) through which an accident-preparing material is injected into the injection pipe 140, which will be described later, installed inside the housing. have.

Subsequently, an opening/closing door 120 capable of opening and closing is mounted on the other side of the housing 100.

The experimenter supplies a biological sample to the inner space of the housing 100 through the opening/closing door 120.

In more detail, the housing 100 is formed with an entrance (not shown), and the opening and closing door 120 is hingedly coupled to the entrance to be rotatably mounted.

In addition, the opening and closing member 122 is additionally coupled to the entrance, and the opening and closing member 122 has a rectangular plate shape, but is formed of a soft material such as rubber, and a plurality of radial incisions are formed in the middle, When the experimenter puts and removes the inside of the housing 100 through the entrance, the air inside the housing cannot easily escape to the outside.

In addition, according to the needs of the experimenter, the experimenter may optionally attach an additional vinyl, so that the air inside does not easily escape to the outside.

That is, the experimenter first rotates the opening and closing door in order to insert and remove a specific object inside the housing, and then goes through a process of inserting a hand into the housing through a cut line formed in the opening member disposed at the rear of the opening door. do.

In addition, an input tube 140 is mounted inside the upper side of the housing 100 so as to pass through the housing.

As shown in FIG. 4, the input pipe 140 is provided to be detachable from the housing 100.

The inlet pipe 140 is an element that exposes the accident preparation material (chemical substance) that the experimenter wants to experiment with inside the housing.

The input tube 140 is a hollow body with both ends closed. In the present invention, as an example of the input tube 140, a hollow tube made of glass material having a circular vertical section was used, but the reactivity of the test material Accordingly, hollow tubes of various materials such as acrylic materials can be used.

In addition, a handle (not shown) is provided at one end of the input tube 140 to facilitate attachment and detachment of the input tube.

In addition, the input tube is provided to be sealed when mounted in the housing, and a sealing member (not shown) is mounted on the input tube insertion port 106 formed on the outer circumferential surface of the housing, and the input tube insertion port 106 When the input pipe 140 mounted in the housing is mounted in the housing, it is sealed.

The inlet pipe 140 is long mounted in the housing 100 in the horizontal direction.

In addition, an inlet port 142 into which an accident preparation material (chemical substance) is injected is formed in the upper outer periphery of the inlet pipe 140, and a plurality of hollow holes 144 are formed in the outer periphery.

In the present invention, when an experimenter conducts an experiment for diagnosing damage to a chemical accident, a non-woven fabric (not shown) is laid on the inner circumferential surface of the input pipe corresponding to the inlet 142, and the accident preparation material is dropped onto the non-woven fabric. , The injection pipe is mounted inside the housing so that the accident preparation material is vaporized and exposed to the inside of the housing.

That is, the accident preparation material introduced through the inlet 142 is exposed to the entire interior of the housing through the hollow hole 144.

Subsequently, the mounting block 160 is coupled to the inner bottom surface of the housing 100.

The mounting block 160 is an element for stably mounting the experimental container 10 in which the biological sample is accommodated on the upper surface.

A mounting groove having the same shape as the cross section of the test container 10 is formed on the upper surface of the mounting block 160, and the size is preferably formed to be slightly larger than the cross-sectional area of the test container.

In the present invention, as an example, two mounting blocks 160 are combined in the housing.

Next, the fan 200 is coupled to the housing 100.

The fan 200 includes a plurality of blades and a motor that rotates the blades, and is an element for circulating air in the housing 100.

In the present invention, the fan 200 is coupled to the cover 101, but is disposed on the upper side of the inlet pipe 140, so that the fan vaporizes the accident-preparatory material injected into the inlet pipe, The accident preparation material is spread evenly in the interior space of the housing.

In addition, in the present invention, the fan 200 is coupled to the upper surface (cover) of the housing 100, but may be coupled to any one surface of the housing 100.

Subsequently, a stirring unit 300 is provided on the bottom of the housing 100, and the stirring unit 300 is disposed to correspond to the sample container 10 seated on the mounting block.

The stirring unit 300 is an element for stirring a biological sample accommodated in the sample container 10.

The stirring unit 300 agitates the biological sample accommodated in the sample container 10 to make the concentration of the biological sample and the reactant uniform, so that the experimenter has the degree of precipitation of accident-preparatory substances (chemicals) in the biological sample. Try to grasp more accurately.

Hereinafter, a method of diagnosing damage from a chemical accident through the chamber 1000 for diagnosing damage from a chemical accident according to the present invention will be described.

First, the experimenter drops accident-preparing substances (chemical substances) such as hydrogen chloride and hydrogen fluoride into the inlet pipe 140 through the inlet 142.

In this case, the injection pipe 140 is mounted inside the housing 100 and a nonwoven fabric is laid inside the injection pipe 140.

In addition, at this time, the fan 200 is in a driven state, and accordingly, the accident preparation material is vaporized and evenly exposed inside the housing.

After a certain period of time, the experimenter places the sample container 10 in which biological samples such as human saliva and livestock (cow) saliva are accommodated through the opening and closing door 120 to the seating block 160.

At this time, the stirring unit 300 is in a driven state, and accordingly, the biological sample is stirred.

The experimenter uses a separate measuring device to check the pollution level (concentration) of the air through the gas detection port 102 of the housing 100 at regular time intervals, and collects a biological sample through the sample collection port 104 to obtain the contamination level. By checking and analyzing the (precipitation level of accident-prepared substances), damage can be tested in the event of a chemical accident.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but this is only for describing the invention, and for those of ordinary skill in the art to which the present invention belongs, various modifications or equivalents It will be appreciated that one embodiment is possible.

Therefore, the true scope of the present invention should be determined by the technical idea of the claims.

1000: Chamber for diagnosis of chemical accident damage
10: sample container
100: housing
101: cover
102: gas detection zone
104: Sample collection port
106: inlet pipe insertion port
120: open and close door
122: opening and closing member
140: input pipe
142: Inlet
144: hollow hole
160: seating block
200: fan
300: stirring unit

Claims (3)

A housing having a space portion formed therein, a sample collecting hole formed on a side surface, and a gas detection hole formed on an upper surface;
An opening/closing door mounted on one surface of the housing to be opened and closed;
A fan coupled to one surface of the housing;
An input tube mounted through the inside of the upper side of the housing and provided to be detachably attached to the housing;
A chamber for diagnosing damage from a chemical accident, comprising: a seating block coupled to the inner bottom surface of the housing and on which a sample container accommodating a biological sample is mounted on the upper surface.
The method of claim 1,
The inlet pipe is a cylindrical hollow body with both ends closed, and an inlet is formed in the upper outer periphery, and a plurality of hollow holes are formed in the lower outer periphery.
The method of claim 1,
A chamber for diagnosing damage to a chemical accident, characterized in that a stirring unit is provided on the bottom of the housing, and the stirring unit is disposed at a lower side of the mounting block to agitate a biological sample seated on the mounting block.

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