KR200332786Y1 - condensation apparatus for evaporative gas - Google Patents

Abstract

The present invention relates to a condensation recovery device of the vapor, it is formed in a cylindrical shape, the upper portion is opened, the outlet port 101 is formed in the lower side, the gas inlet 102 is formed with a gas inlet 102 is introduced into the side )and; The refrigerant is flow-circulated into the coil-shaped evaporation tube 111 formed in the pressure reducing tube 100 to evaporate the refrigerant liquefying the gas introduced through the gas inlet 102 by heat exchange with the refrigerant. Cooling means 110 for circulating flow to the tube 111 side; A pump extending into the pressure reducing tube 100 through an upper opening of the pressure reducing tube 100 and connected to the vacuum pump 150 to flow gas inside the pressure reducing tube 100 to the vacuum pump 150 side. Pipe 120; In addition, a condensation recovery apparatus for a vapor formed therein is formed in an upper opening of the pressure reducing tube 100 to seal the pressure reducing tube 100 with the outside. Accordingly, there is an advantage that the condensation efficiency of the vapor is increased by liquefying the vapor by direct heat exchange with the refrigerant.

Description

Condensation apparatus for evaporative gas

The present invention relates to a condensation recovery device for vapors, and more particularly, to liquefy and extract volatile organic compounds and water by liquefying vaporized volatile organic compounds and vaporized water in contact with a refrigerant evaporation tube. The present invention relates to a condensation recovery device for vapors.

In general, various research institutes, schools, and enterprises are concentrated samples for various experiments, and a concentration device for concentrating such samples to a high concentration is essentially provided. The concentrator uses the principle of distillation by heat transfer to vaporize chemical substances such as vapors and harmful components, such as alcohol aldehydes, contained in the sample in a gaseous state and concentrate only the desired sample components. Therefore, when the concentration of the sample is highly concentrated, the work must be done without changing the physical properties of the essential components inside the sample is usually performed by vacuum distillation.

Hereinafter, a process of concentrating a sample by such dark distillation will be briefly described with reference to the drawing of FIG. 1. As shown, aspirate 2 is used to depressurize the inside of the sample flask 1a of the concentrator 1. That is, the tap water flowing through the upper portion of the aspirate (2) is discharged to the lower portion, and the gas present in the sample flask (1a) is discharged to the outside due to the pressure drop due to the flow rate of the tap water, thereby concentrating the concentrator (1). The sample flask 1a in the chamber is depressurized. In addition, vapor and gaseous harmful substances generated during the concentration of the sample are discharged to the outside by the action of the tap water to concentrate the sample.

However, the above apparatus has the following problems.

Since the tap water must be continuously supplied through the aspirate (2), not only is the waste of tap water severe, but there is a problem in that the loss of the sample is severe because the decompression inside the sample flask 1a is not so great.

First of all, the harmful substances generated during the concentration of the sample are mixed with the tap water supplied immediately without any filtration and flow into the sewer, which causes environmental pollution. Also, unconcentrated gaseous harmful substances are exposed to the atmosphere. There is a problem that causes odor inside the laboratory and causes air pollution.

In another conventional technology, a concentration device system having an integrated gas-liquid separator and a coolant circulating device registered in advance by the applicant is introduced in Korean Utility Model Registration No. 20-240531.

The prior art, as shown in Figures 2 and 3, and a concentrator 10 having a sample flask 14 containing a sample; A vacuum pump 40 for depressurizing the inside of the sample flask 14 and discharging the gas generated during the concentration to the outside, and is located between the concentrator 40 and the vacuum pump 40 by the vacuum pump 40. A gas-liquid separator (30) comprising a glass cooler (50) through which gas from the sample flask (40) passing out is separated into gas and liquid; The coolant circulating in the glass cooler 50 may be configured to circulate a low temperature coolant, and the coolant circulator 60 may adjust the temperature of the supplied coolant.

However, the prior art has a problem in that cooling to below a predetermined temperature is impossible due to the characteristics of the cooling liquid, so that the efficiency of gas-liquid separation is lowered when the vaporization temperature is low.

Accordingly, the present invention has been made to solve the problems of the prior art, the vaporized gas by the heat exchange between the refrigerant flowing through the vaporized gas and the vapor evaporation tube to the decompression tube containing the coil-shaped evaporation tube An object of the present invention is to provide a condensation recovery device for a vapor to liquefy.

1-a sectional view of a thickening device according to the prior art;

2-a perspective view of a concentration system according to the prior art;

3 is a schematic view showing the construction of a concentration system according to the prior art;

Figure 4 is a schematic diagram showing the configuration of the condensation recovery apparatus of the vapor according to the present invention.

<Description of Symbols for Major Parts of Drawings>

100: pressure reducing tube 101: outlet

102 gas inlet 110 cooling means

111: evaporator 112: compressor

113 condenser 114 capillary tube

120: pump pipe 130: valve body

140: cover portion 141: inner cover portion

142: outer cover 150: vacuum pump

The present invention for achieving the above object is formed in a tubular shape, the upper portion is opened, the outlet is formed in the lower portion, the gas inlet through which the gas inlet is formed; Cooling means for circulating a refrigerant into a coil-shaped evaporation tube formed in the pressure reducing tube to circulate a refrigerant liquefied through the gas inlet through heat exchange with the refrigerant to the evaporation tube; A pump tube extending into the pressure reducing tube through an upper opening of the pressure reducing tube and connected to a vacuum pump to flow gas inside the pressure reducing tube to the vacuum pump side; In addition, a condensation recovery device for a vapor comprising a cover portion formed in the upper opening of the pressure reducing tube to seal the pressure reducing tube with the outside as a technical gist.

Here, it is preferable that the valve body is formed at the outlet of the pressure reducing pipe so as to selectively seal the pressure pipe with the outside.

The cooling means may include: a compressor connected to the evaporation tube to compress a low temperature low pressure gas refrigerant to a high temperature high pressure gas refrigerant; A condenser connected to the compressor to convert a high temperature and high pressure gas refrigerant into a low temperature and high pressure liquid refrigerant; And a capillary tube connected to the condenser to convert the liquid refrigerant of low temperature and high pressure into a liquid refrigerant of low temperature and low pressure to be delivered to the evaporation tube side.

Accordingly, there is an advantage that the condensation efficiency of the vapor is increased by liquefying the vapor by direct heat exchange with the refrigerant.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a schematic view of the condensation recovery apparatus configuration of the vapor according to the present invention.

As shown, the condensation recovery apparatus of the vapor according to the present invention is largely reduced to the pressure reducing pipe 100, the cooling means 110, the pump pipe 120, the valve body 130 and the cover portion 140 It is composed.

First, the pressure reduction tube 100 will be described.

The pressure reducing tube 100 is formed in a substantially cylindrical shape with a rounded bottom, an upper portion is opened, an outlet 101 is formed in the lower portion, and a gas inlet 102 through which gas is introduced is formed at one side of the upper side. .

The pressure reducing tube 100 is formed of a glass material, sus material, plastic material, or the like.

And the outlet 101 is provided with a valve body 130 is configured to selectively lock / open the valve body 130.

The cover part 140 is formed at the upper opening of the pressure reducing tube 100, and the cover part 140 includes an inner cover part 141 and an outer cover part 142, and an inner cover part 141. The through-hole is formed is coupled to the pipe connected to the pump pipe 120 and the evaporation pipe 111, and is formed of rubber, Teflon or plastic to maintain the airtight. In addition, the outer cover part 142 is formed to surround the outer surface of the upper end of the pressure reducing tube 100 in order to stabilize the coupling of the inner cover part 141. If necessary, the outer cover portion 142 and the upper end of the pressure reducing tube 10, the upper end of the adjacent surface by forming a screw can be coupled to each other by a stable coupling.

The cooling means 110 is largely composed of an evaporator tube 111, a compressor 112, a condenser 113, and a capillary tube 114.

The evaporation tube 111 is formed in a coil-like tubular shape, is formed of a metal tube material such as copper, stainless steel, titanium, brass, etc., is installed in the pressure vessel 100, the evaporation tube 111 formed on the top One side of the) is connected to the capillary tube 114, the other side formed in the lower portion is connected to the compressor (112).

The evaporation tube 111 is connected to the capillary tube 114 and the low-temperature low-pressure liquid refrigerant transferred from the capillary tube 114 side exchanges heat with the gas introduced from the gas inlet 102. That is, the gas introduced into the gas inlet 102 is heat-exchanged in such a manner that it heat-exchanges with the liquid refrigerant flowing through the evaporation tube 111 while moving toward the upper side of the evaporation tube 111 and moving downward. . The condensed water is collected at the base of the pressure reducing tube 100 and the gas which is not liquefied is discharged to the outside of the pressure reducing tube 100 through the pump tube 120 described later.

The refrigerant passing through the evaporation tube 111 is converted into gas refrigerant of low temperature and low pressure, and is converted into gas refrigerant of high temperature and high pressure by the compressor 112, and is converted into low temperature and high pressure liquid refrigerant in the condenser 113, and the capillary tube 114 is turned on. After passing through the liquid refrigerant of low temperature and low pressure it is forced to flow again to the evaporation pipe (111). Here, since the cooling means 110 is a well-known technology, further detailed description thereof will be omitted.

Here, the position of the gas inlet 102 formed in the decompression tube 100 is formed to substantially coincide with the upper portion of the evaporation tube 111.

The pump tube 120 is formed in the pressure reducing tube 100 through the inner cover part 141, one side end of the pump tube 120 of the lower side of the pressure reducing tube 100 It is formed at about a quarter point and the other end of the pump pipe 120 is connected to the vacuum pump 150. Therefore, the inside of the pressure reducing tube 100 is configured to be a vacuum by the operation of the vacuum pump 150.

In addition, the gas introduced into the gas inlet 102 contacts the upper surface of the evaporation tube 111 to exchange heat with the refrigerant, condensing instantaneously, and the non-condensed gas at a time difference is lowered by the pumping of the vacuum pump 150. Condensed in such a way as to be in sufficient contact with the evaporation tube 111 is collected at the bottom of the decompression tube 100, the non-condensed gas is introduced into the end side of the pump tube 120 is vacuum pump 150 It is discharged to the outside by the pumping action of). Here, the gas discharged to the outside becomes clean air containing no impurities.

In this case, the liquid collected at the bottom of the pressure reducing tube 100 may be discharged to the outside of the pressure reducing tube 100 by opening the valve body 130.

The operation effect by the above configuration is as described later.

First, the user couples the cover part 140 to the opening of the pressure reducing tube 100 and locks the valve body 140 of the outlet 101 to seal the pressure reducing tube 100 with the outside.

Then, the vacuum pump 150 and the cooling means 110 are operated.

By operating the vacuum pump 150, the inside of the pressure reducing tube 100 becomes a vacuum, and the low temperature and low pressure liquid refrigerant flows to the evaporation tube 111 by the operation of the cooling means 110.

In the above state, the user introduces the gas into the pressure reduction tube 100 through the gas inlet 102.

The introduced gas contacts the upper surface of the evaporation tube 111 to exchange heat with the refrigerant to condense it instantaneously, and the non-condensed gas at a time difference is moved downward by the pumping of the vacuum pump 150 and thus the evaporation tube 111. It condenses in such a way that it makes sufficient contact with it.

The condensed liquid is collected at the bottom of the decompression tube 100, and the gas which is not condensed is introduced into the end side of the pump tube 120 to be discharged to the outside by the pumping action of the vacuum pump 150. Here, the gas discharged to the outside is clean air containing no impurities, and the liquid collected at the bottom of the pressure reducing tube 100 is discharged to the outside of the pressure reducing tube 100 by opening the valve body 130.

The condensation recovery device of the present application can also be used as a cold trap of a vacuum dryer, if necessary.

According to the present invention, the condensation of the vapor by injecting the gas into the pressure-reducing tube containing the coil-shaped evaporation tube and liquefying the vapor by direct heat exchange between the vapor and the refrigerant circulating the evaporation tube. The efficiency is increased.

Claims (3)

A pressure reducing tube (100) formed in a cylindrical shape and having an upper opening, an outlet (101) formed at a lower portion thereof, and a gas inlet (102) through which gas is introduced into a side surface thereof; The refrigerant is flow-circulated into the coil-shaped evaporation tube 111 formed in the pressure reducing tube 100 to evaporate the refrigerant liquefying the gas introduced through the gas inlet 102 by heat exchange with the refrigerant. Cooling means 110 for circulating flow to the tube 111 side; A pump extending into the pressure reducing tube 100 through an upper opening of the pressure reducing tube 100 and connected to the vacuum pump 150 to flow gas inside the pressure reducing tube 100 to the vacuum pump 150 side. Pipe 120; And, And a cover part (140) formed in the upper opening of the pressure reducing tube (100) to seal the pressure reducing tube (100) with the outside. The vapor condensation recovery apparatus of claim 1, wherein a valve body (130) is formed at an outlet (101) of the pressure reducing pipe (100) to selectively seal the pressure reducing pipe (100) with the outside. The method of claim 1 or 2, wherein the cooling means 110, A compressor (112) connected to the evaporation tube (111) to compress a low temperature low pressure gas refrigerant to a high temperature high pressure gas refrigerant; A condenser (113) connected to the compressor (112) to convert a gas refrigerant of high temperature and high pressure into a liquid refrigerant of low temperature and high pressure; And a capillary tube (114) connected to the condenser (113) to convert the liquid refrigerant of low temperature and high pressure into a liquid refrigerant of low temperature and low pressure, and to deliver it to the evaporation tube (111) side.