KR20220090030A - Super seperator - Google Patents

Abstract

The present invention relates to a super separator, and more particularly, to a fuel cell station, as well as a water electrolysis station, and a facility requiring gas-liquid separation to significantly increase the gas-liquid separation efficiency without limiting the installation location of the heat exchanger. It relates to an improved super separator that can contribute to increasing efficiency.

Description

Super separator

The present invention relates to a super separator, and more particularly, to a fuel cell station, as well as a water electrolysis station, and a facility requiring gas-liquid separation to significantly increase the gas-liquid separation efficiency without limiting the installation location of the heat exchanger. It relates to an improved super separator that can contribute to increasing efficiency.

In the fuel cell station, as well as in the water electrolysis station or the compression system through a compressor, phase separation of substances discharged after reaction or compression must be performed.

That is, the gas-liquid must be separated, because if the gas-liquid is not separated, it may cause equipment failure.

Therefore, most facilities requiring gas-liquid separation include a condenser for gas-liquid separation.

However, since phase separation of gas and liquid is not perfect only by natural cooling in the condenser, a heat exchanger or an additional cooling system is connected to the vent line at the rear end of the condenser to increase the phase separation efficiency.

For this reason, the separator of FIG. 1 installed in the condenser has no choice but to have a structure in which the lower end of the filter 10 is blocked, that is, a sealed structure.

For example, after the gas-liquid mixture requiring phase separation is introduced into the inlet 20 of the separator, only the gas passes through the filter 10, and the liquid collects outside the filter 10 and then falls to the bottom and automatically drains when a certain amount is filled, and is separated The gas is discharged through the outlet 22 and moves to the subsequent line.

At this time, if the lower end of the filter 10 is not blocked, since some of the liquid is sucked into the filter 10 through the open lower end and then discharged to the outlet 22, the gas-liquid separation effect is almost absent. Therefore, the lower end of the filter 10 must be blocked.

However, the gas from which the gas-liquid is separated through the filter 10 is not 100% gas-liquid separated, but only about 70-80% separated. In the facility, it is necessary to further increase the gas-liquid separation efficiency by passing the secondary heat exchanger 32 after the outlet 22 .

Of course, in general, the gas-liquid is primarily separated through the primary heat exchanger 30 before entering the separator, that is, before the inlet 20 to increase the separation efficiency.

However, in the conventional separator structure, the secondary heat exchanger 32 cannot be used. This is because the liquid separated through the secondary heat exchanger 32 flows into the separator and accumulates inside the filter 10, and the filter 10. This is because the lower end of the filter can not be drained because it is blocked, and eventually the inside of the filter 10 is filled with water, so that the gas-liquid can no longer be separated.

For this reason, up to now, the filter 10 of the separator had to have a structure in which the lower end was inevitably blocked.

For this reason, since the secondary heat exchanger 32 cannot be installed in a facility that wants a high level of gas-liquid separation efficiency, a large number of unnecessary facilities must be additionally provided to increase the gas-liquid separation efficiency, waste of money, equipment volume, etc. There were many shortcomings.

Domestic Patent No. 10-1322680 (Oct. 22, 2013), Gas-liquid separator for cascade type fuel cell

The present invention was created to solve the problems in the prior art as described above, and is applied to not only fuel cell stations but also water electrolysis stations and facilities requiring gas-liquid separation without limiting the installation location of the heat exchanger. Its main purpose is to provide an improved super separator that can significantly increase the gas-liquid separation efficiency and contribute to increasing the efficiency of the facility.

The present invention provides a means for achieving the above object, in a super separator having a housing (100) and a filter (200) built into the housing (100); The housing 100 includes a gas-liquid mixture inlet pipe 110 piped through an upper end, a gas outlet pipe 210 piped to the center of the upper end surface of the housing 100, and an on/off valve 312 through the lower end surface. ) comprising a drain 310 having; The filter 200 includes a filter body 208 that separates gas and liquid and allows only gas to pass therethrough, a filter body 202 having a plurality of holes in which the filter body 208 is built in and through which gas can pass, An upper cover 204 fixed to the upper end of the filter body 202 and to which the gas discharge pipe 210 is connected, and a filter body 208 fixed to the lower portion of the filter body 202 opposite to the upper cover 204 ) comprises a lower cover 206 to which the liquid discharge pipe 220 for discharging the liquid flowing into the interior is connected; The liquid discharge pipe 220 provides a super separator, characterized in that the lower end is submerged in water.

At this time, a water level sensor 300 for detecting the level of water stored in the lower portion of the housing 100 is further installed in the housing 100; The water level sensor 300 is also characterized in that it is configured to drain by opening the opening/closing valve 312 when the water level reaches a certain level.

According to the present invention, it is applied to not only a fuel cell station, but also a water electrolysis station and a facility requiring gas-liquid separation to significantly increase the gas-liquid separation efficiency without limiting the installation location of the heat exchanger, thereby contributing to enhancing the efficiency of the facility. effect can be obtained.

1 is an exemplary cross-sectional view of a separator according to the prior art.
2 is an exemplary cross-sectional view of a separator according to the present invention.
3 is an exemplary view showing the main part of a separator according to the present invention.

Hereinafter, a preferred embodiment according to the present invention will be described in more detail with reference to the accompanying drawings.

As shown in FIGS. 2 to 3 , the super separator according to the present invention includes a housing 100 and a lower open-type filter 200 charged in the housing 100 .

At this time, the housing 100 is an external shape in which the filter 200 is built, and a gas-liquid mixture inlet pipe 110 is piped on the upper surface.

And, a flange for fixing to the equipment is provided around the upper end.

In addition, the gas discharge pipe 210 is exposed through the center of the upper surface of the housing 100 , and the gas discharge pipe 210 is connected in communication with the upper end of the filter 200 .

In addition, a liquid discharge pipe 220 is connected to the lower end of the filter 200 in communication, and the lower end of the liquid discharge pipe 220 extends to the lower portion of the housing 100 .

In addition, a drain hole 310 is formed in the center of the bottom surface of the housing 100 , and an on/off valve 312 is installed in the drain hole 310 .

In this case, the on-off valve 312 is a solenoid valve and is configured to operate according to the detection signal of the water level sensor 300 .

Here, the water level sensor 300 is a non-contact sensor for detecting a water level rising from the bottom surface of the housing 100 and discharging the liquid when a predetermined water level is reached.

However, the discharged liquid is not drained entirely, but is drained leaving only enough to submerge the lower end of the liquid discharge pipe 220 .

Therefore, even when initially installed, the lower end of the liquid discharge pipe 220 must be maintained in a state submerged in water, which is to obtain an effect of sealing the lower end of the filter 200 .

That is, the lower end of the liquid discharge pipe 220 is submerged in water by filling a little water on purpose.

In addition, even in the case of the water level sensor 300, it is not limited to the illustrated position, it is an easy point to detect, and it can be installed anywhere, and it is not necessarily a non-contact type, and both a mechanical contact type are possible.

In addition, even in the case of the shape of the housing 100, it is a matter of course that as one example has been described, it can be transformed into various shapes according to the place of use.

On the other hand, as shown in the example of FIG. 3 , the filter 200 includes a filter body 208 that separates gas and liquid and allows only gas to pass through, and a plurality of holes through which the filter body 208 is built in, through which gas can pass. a filter body 202 having a filter body 202 having a top cover 204 fixed to the upper end of the filter body 202 and connected to a gas discharge pipe 210 for discharging only filtered gas, and a filter facing the top cover 204 It is fixed to the lower portion of the body 202 and includes a lower cover 206 to which the liquid discharge pipe 220 for discharging the liquid flowing into the filter body 208 is connected.

At this time, the filter body 202 is molded of synthetic resin.

In addition, the upper cover 204 and the lower cover 206 are configured to be detachably attached to and removed from the upper and lower ends of the filter body 202, respectively.

In addition, the gas discharge pipe 210 and the liquid discharge pipe 220 are coupled in such a way that they are fitted into the opening of the upper cover 204 and the opening of the lower cover 206 , respectively.

As described above, since the filter 200 according to the present invention has an open lower side, that is, the lower part of the liquid discharge pipe 220, the secondary heat exchanger ( 32, see FIG. 1) can be installed, so that the gas-liquid separation efficiency can be maximized.

The super separator according to the present invention having such a configuration has the following operating relationship.

When the gas-liquid mixture requiring gas-liquid separation enters the gas-liquid mixture inlet pipe 110 of the separator, the only space that can escape from the inside of the housing 100 is through the filter 200 .

That is, the lower part of the housing 100 is filled with water to some extent, and since the lower end of the liquid discharge pipe 220 constituting the lower end of the filter 200 is partially submerged, the only place that can communicate with the gas discharge pipe 210 is the filter ( 200), more precisely, it must pass through the filter body 208.

However, since the filter body 208 blocks the passage of moisture, that is, only gas passes through, the water is filtered by the filter body 208 and drips downward, and the dripped water is accumulated on the inner bottom of the housing 100 . . That is, water is stored.

In other words, since the super separator according to the present invention also has a structure in which the lower end of the filter 200 is blocked, the gas-liquid separation efficiency is not different from that of the conventional separator.

However, the existing separator cannot attach the secondary heat exchanger 32 to the gas discharge side, but the super separator of the present invention has the advantage that the secondary heat exchanger 32 can be installed in the gas discharge side.

That is, even when the secondary heat exchanger 32 is installed, when water generated in the secondary heat exchange process flows into the super separator, the gas discharge pipe 210 → the inner hollow of the filter body 208 → the liquid discharge pipe 220 → the housing Because water drips down and is stored in the inner lower end of 100, clogging of the filter body 208 by water does not occur.

Therefore, it is possible to separate the gas-liquid with higher efficiency, that is, high efficiency, through the secondary heat exchange.

And, when the water inside the housing 100 rises to a certain extent, it is detected and designed to automatically drain to a predetermined water level.

100: housing
200: filter

Claims (2)

A super separator having a housing (100) and a filter (200) built into the housing (100);
The housing 100 includes a gas-liquid mixture inlet pipe 110 piped through an upper end, a gas outlet pipe 210 piped to the center of the upper end surface of the housing 100, and an on/off valve 312 passing through the lower end surface. ) comprising a drain 310 having;
The filter 200 includes a filter body 208 that separates gas and liquid and allows only gas to pass therethrough, a filter body 202 having a plurality of holes in which the filter body 208 is built in and through which gas can pass, An upper cover 204 fixed to the upper end of the filter body 202 and to which the gas discharge pipe 210 is connected, and a filter body 208 fixed to the lower portion of the filter body 202 opposite to the upper cover 204 ) includes a lower cover 206 to which the liquid discharge pipe 220 for discharging the liquid flowing into it is connected;
The liquid discharge pipe 220 is a super separator, characterized in that the lower end is submerged in water.
The method of claim 1,
A water level sensor 300 for detecting the level of water stored in the lower portion of the housing 100 is further installed in the housing 100; The water level sensor (300) is a super separator, characterized in that it is configured to drain by opening the on-off valve (312) when the water level reaches a certain level.

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