KR200361857Y1 - A seperate system of liquid fluid and air for chemical laboratory transfer system - Google Patents

Abstract

In general, a device in which a chemical in a storage tank is sucked and moved using a vacuum and then pressurized again to be returned to the storage tank using a vacuum suction input, and in general, a vacuum force is generated to move chemicals through a vacuum suction method. A gas-liquid separator is used between the vacuum ejector and the suction port.

The gas-liquid separator is composed of a suction port for performing vacuum suction and exhaust on the upper part, and a type of tank configured with an exhaust port and a discharge port on the lower part. Due to the scattering in the interior of the chemical liquid on the upper inner surface of the gas-liquid separator due to such scattering there is a problem that is supplied to the vacuum ejector.

The present invention is to solve the problems of the conventional gas-liquid separator as described above by installing a projection tube protruding into the inlet and the exhaust port configured in the upper portion of the gas-liquid separator, respectively, while minimizing the scattering of chemicals sucked into the gas-liquid separator It is characterized by preventing chemicals that may be formed on the inner surface of the exhaust through the exhaust port.

Description

Gas-liquid separation device of chemical chemical transport system {A SEPERATE SYSTEM OF LIQUID FLUID AND AIR FOR CHEMICAL LABORATORY TRANSFER SYSTEM}

The present invention relates to a gas-liquid separator, and more particularly, to a gas-liquid separator for use when moving to a third place by the vacuum suction input of chemicals.

In general, a gas-liquid separation device is known as a series of devices that separate gas and liquid, but is used to transfer to a third place using a vacuum suction input of chemicals. do.

The accompanying drawings 1 are shown to help understanding of the present invention, which is an extract of a part of the apparatus for transferring chemicals in a storage tank to a third place through a vacuum suction input.

In the state in which the suction valve 1 'is opened, the vacuum suction input of the vacuum ejector 3 extends from the gas-liquid separator 2 to the suction tank 1 through the valve 2'.

At this time, the vacuum suction input reaches the storage tank 7 and the pipe 8 between the storage tank 7 and the suction valve 1 'so that the chemicals therein are supplied to the suction tank 1 by suction.

The chemicals sucked into the suction tank 1 are closed by the suction valve 1 'and then open the discharge valve 1 ", and then moved to the third mechanism 9 again to be used as desired. It is known as a device such as 7) or to a third place depending on its use.

Chemicals sucked into the suction tank (1) in the above-mentioned transfer system is transferred by the vacuum suction force, wherein the vacuum suction input generated from the vacuum ejector (3) to the suction tank (1) through the gas-liquid separator (2) It can be seen that it is formed crazy.

The gas-liquid separator 2 is used to prevent the liquid chemicals scattered or overflowed from the suction tank 1 by the vacuum suction input to the vacuum ejector 3 through the gas-liquid separator 2.

That is, the gas-liquid separator 2 is used to solve problems such as malfunction of the vacuum ejector 3 by preventing the chemicals from being supplied to the vacuum ejector 3 and collecting and discharging the liquid.

Such a separator (2) is shown in cross-section in the accompanying drawings, Figure 2, if specifically looked at it as follows.

As shown in FIG. 2, the suction port 4 and the exhaust port 5 for suctioning and evacuating the vacuum pressure are formed in the upper part, and the lower part is composed of a closed tank. It consists of an outlet 6 for discharging chemicals sucked from the suction tank (1).

The gas-liquid separator 2 having such a structure has the following problems.

There is a problem that chemicals that can be sucked from the suction tank 1 during the vacuum suction are scattered inside the gas-liquid separator 2.

Due to such scattering, there is a problem that chemicals are formed on the upper inner surface 2 ′ of the gas-liquid separator 2.

Due to this problem, the chemical ejector having the chemicals formed on the upper inner surface 2 ′ of the gas-liquid separator 2 passes through the exhaust port 5 installed at the upper portion of the gas-liquid separator 2 to evacuate the vacuum ejector 3. The problem is that the supply becomes.

Due to this problem, the chemical is filled in the vacuum ejector 3, which causes problems such as malfunction of the vacuum ejector 3.

The present invention is to solve the problems with the conventional gas-liquid separator as described above, while minimizing the scattering of chemicals sucked in, to prevent the chemicals that may be formed on the inner surface of the gas-liquid separator is discharged through the exhaust port.

In order to achieve the above object, the present invention was able to solve the conventional problems by installing protrusion tubes protruding into the inlet and the exhaust port formed in the upper portion of the gas-liquid separator.

1 is a reference diagram showing a part of the chemical concentration measuring apparatus,

2 is a cross-sectional view of a conventional gas-liquid separator;

Figure 3 is a cross-sectional view of the gas-liquid separation device of the present invention.

<Explanation of symbols for main parts of drawing>

1: measuring instrument 2: gas-liquid separator

3: vacuum ejector 4: inlet

5: exhaust port 6: exhaust port

11: suction protrusion tube 12: exhaust protrusion tube

Hereinafter, the present invention with reference to the accompanying drawings in detail 3 as follows.

In the gas-liquid separator 2 having the inlet port 4 and the exhaust port 5 formed thereon,

Provided is the gas-liquid separation device of the present invention is fixed to the suction inlet pipe 11 and the exhaust protrusion pipe 12 protruding into the inlet 4 and the exhaust port 5, respectively.

This is to prevent the chemicals that may be sucked from the measuring device (1) through the suction projection pipe 11 to the maximum suppression of the scattering in the gas-liquid separator (2).

Even through the maximum suppression of such scattering may occur when the chemicals are buried in the upper surface (2 ') of the gas-liquid separator (2).

In this way, the chemicals bound to the inner upper surface 2 ′ of the gas-liquid separator 2 suck air into the vacuum ejector 3, which sucks through the gas-liquid separator 2, and is inserted into the exhaust port 5. Since the fixed exhaust protrusion pipe 12 is formed so as to protrude from the inner upper surface 2 'of the gas-liquid separator 2 inward, it is buried in the inner upper surface 2' of the gas-liquid separator 2. When the air inside the gas-liquid separator 2 is sucked, it is possible to prevent the exhaust with the chemicals.

The chemicals in the vacuum ejector (3) by the present invention because the discharge of the air in the gas-liquid separator (2), that is, only discharge the air during the transfer of the vacuum force can fundamentally prevent the discharge of chemicals This can be prevented from flowing in or outward.

As described above, in the present invention, the chemicals may be prevented from being sucked into the gas-liquid separator by the vacuum ejector as well as prevent the air from being sucked out as needed. It is a very useful design that can prevent the emission to the outside and fundamentally block the pollution of the environment.

Claims (1)

In the gas-liquid separator 2 having the inlet port 4 and the exhaust port 5 formed thereon, A gas-liquid separator for chemical concentration measurement of chemicals, characterized in that the suction port (11) and the exhaust pipe (12) protruding into the suction port (4) and the exhaust port (5) forcibly fixed.