KR102118871B1 - Heat pump system by electro-osmosis - Google Patents

Abstract

The present invention can cool water remaining in a water tank by evaporating hot water in the water tank by using a vacuum pump by providing an electro-osmosis membrane composite on a discharge side of the vacuum pump and selectively separate only water vapor including water droplets sucked by the vacuum pump by using a membrane. In addition, very low pressure water vapor can be easily discharged to outdoor air at atmospheric pressure by using a difference between partial pressure of water vapor inside the membrane of the electro-osmosis membrane composite and partial pressure of water vapor in the outdoor air.

Description

Electric osmosis heat pump system{Heat pump system by electro-osmosis}

The present invention relates to an electric osmosis heat pump system, and more particularly, to an electric osmosis heat pump system capable of maximizing the cooling efficiency of the heat pump using a vacuum pump and an electric osmosis membrane composite.

In general, a vapor compression type refrigerator includes a compressor, a condenser, an expansion valve, and an evaporator, and sequentially performs a process of compressing, condensing, expanding, and evaporating a refrigerant to cool air entering the room using latent heat of evaporation. .

Recently, various technologies have been proposed to replace the vapor compression cycle due to the development of various materials and material technologies.

In particular, interest in cooling systems that do not use compressors and refrigerants is increasing.

Korean Registered Patent No. 10-0528392

An object of the present invention is to provide an electric osmosis heat pump system that can maximize the cooling efficiency.

An electric osmosis heat pump system according to the present invention includes a water pump for pumping cold water; A cooling coil for exchanging cold water pumped by the water pump with external air; A hot water discharge flow path connected to the cooling coil to discharge hot water heated by heat exchange in the cooling coil; A water tank provided between the hot water discharge flow path and the water pump to flow hot water discharged into the hot water discharge flow path; A vacuum pump provided to be connected to the water tank to cool the inside of the water tank by evaporating hot water in the water tank; It is provided on the discharge side of the vacuum pump, and when the voltage is applied, the water vapor evaporated by the vacuum pump is moved toward the outdoors by electric osmosis, and the water vapor is outdoor using the partial pressure difference between the water vapor and outdoor air. An electro-osmosis membrane composite to discharge; And a cold water discharge flow path connected to the water tank and guiding cold water cooled in the water tank to the water pump.

The present invention, by providing an electro-osmosis membrane composite on the discharge side of the vacuum pump, not only can cool the water remaining in the water tank by evaporating the hot water in the water tank using a vacuum pump, the membrane containing water vapor containing droplets sucked by the vacuum pump It has the advantage of selectively separating only water vapor.

In addition, by using the difference between the partial pressure of water vapor inside the membrane of the electric osmosis membrane composite and the partial pressure of water vapor in the outdoor air, there is an advantage that water vapor at a very low pressure can be easily discharged to outdoor air having an atmospheric pressure level.

In addition, since the pressure ratio of the vacuum pump can be lowered and the pressure inside the system can be lowered overall, the cooling efficiency of the system can also be improved.

1 is a block diagram schematically showing an electric osmosis membrane heat pump system according to an embodiment of the present invention.
2 is a view schematically showing the configuration of the electro-osmosis membrane composite according to an embodiment of the present invention.

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

1 is a block diagram schematically showing an electric osmosis membrane heat pump system according to an embodiment of the present invention. 2 is a view schematically showing the configuration of the electro-osmosis membrane composite according to an embodiment of the present invention.

Referring to Figure 1, the electric osmosis membrane heat pump system according to an embodiment of the present invention, water pump 10, cold water supply flow path 11, cooling coil 20, hot water discharge flow path 21, water tank 30 ), an electric osmosis membrane complex 40, a cold water discharge passage 12, and a vacuum pump 50.

The water pump 10 is a pump that pumps cold water cooled in the water tank 30.

The cold water supply flow path 11 is a flow path connecting the water pump 10 and the cooling coil 20 to supply cold water to the cooling coil 20.

The cold water supply flow path 11 is provided with a purified water supply valve 15 for receiving purified water from the outside.

The cooling coil 20 is a heat exchanger for exchanging cold water supplied to the cold water supply passage 11 with external air. The cooling coil 20 cools the external air using the cold water, and supplies the cooled air to the indoor demand.

The hot water discharge flow path 21 is a flow path connecting the cooling coil 20 and the water tank 30 and guiding the heated hot water heated by the cooling coil 20 to the water tank 30.

A pressure reducing valve 22 is installed in the hot water discharge passage 21.

The water tank 30 is provided between the hot water discharge flow path 21 and the water pump 10, and the hot water discharged into the hot water discharge flow path 21 flows in and is temporarily stored.

The vacuum pump (Vacuum pump) 50, is connected to the water tank (30). The vacuum pump 50 evaporates the hot water in the water tank 30 to suck droplets and water vapor. As the hot water in the water tank 30 is evaporated when the vacuum pump 50 is operated, water in the water tank 30 may be cooled while the heat of evaporation is deprived.

The electrical osmosis membrane composite 40 is connected to the discharge pipe 51 of the vacuum pump 50.

The vacuum pump 50 and the water tank 30 are installed indoors, and the electric osmosis membrane composite 40 is connected to the discharge pipe 51 of the vacuum pump 50 and installed outdoors.

Referring to Figure 2, the electro-osmosis membrane composite 40, a porous body 41, a pair of electrodes 42, a power supply 43, a membrane 44, a support panel 45 and a droplet discharge unit ( (Not shown).

The electrical osmosis membrane composite 40 is a laminate in which the electrode 42, the porous body 41, the electrode 42, the support panel 45, and the membrane 44 are sequentially stacked.

The porous body 41 is formed of a porous material to absorb water vapor evaporated by the vacuum pump 50.

The electrodes 42 are provided on the front and rear surfaces of the porous body 41, respectively. The electrode 42 is disposed to be in contact with the front and rear surfaces of the porous body 41, and it will be described, for example, using a mesh electrode formed in a mesh form to pass through the droplet and the water vapor.

The power supply unit 43 is connected to the pair of electrodes 42 to apply a voltage to the electrodes 42.

The membrane 44 is a water vapor separation membrane separating the droplets and the water vapor by selectively passing only the water vapor among the droplets absorbed by the porous body 41 and the water vapor.

In addition, the membrane 44 serves to smoothly discharge the separated water vapor to the outside air by using a partial pressure difference between the separated water vapor and the outdoor air.

That is, although the pressure difference between the atmospheric pressure of the outdoor air and the inside of the electric osmosis membrane composite 40 is very large, since the membrane 44 uses only a partial pressure difference of water vapor, it is possible to discharge water vapor to the outdoors.

The support panel 45 is a support provided between the electrode 42 or the porous body 41 and the membrane 44. The support panel 45 is formed of the porous material.

The droplet discharge unit (not shown) is an discharge pipe for draining the droplets separated from the membrane 44.

When explaining the operation of the electric osmosis membrane heat pump system according to an embodiment of the present invention configured as described above, as follows.

First, cold water pumped from the water pump 10 flows into the cooling coil 20.

In the cooling coil 20, the cold water is heated through heat exchange with external air, and the external air is cooled and the cooled air is supplied to the indoor demand.

The hot water discharged from the cooling coil 20 flows into the water tank 30.

When the vacuum pump 50 is operated, hot water in the water tank 30 is evaporated by the pressure difference generated by the vacuum pump 50 and sucked into the vacuum pump 50.

As the hot water in the water tank 30 evaporates, the heat of evaporation is taken away, and the temperature of the water remaining in the water tank 30 is lowered.

The water vapor including droplets sucked by the vacuum pump 50 is sucked into the electric osmosis membrane composite 40 through the discharge pipe 51 of the vacuum pump 50.

When a voltage is applied to the electric osmosis membrane composite 40, water vapor including droplets sucked by the vacuum pump 50 due to the electroosmotic phenomenon may be sucked into the electric osmosis membrane composite 40.

In the electric osmosis membrane complex 40, water vapor including the droplets is absorbed by the porous body 41.

At this time, a droplet and water vapor coexist in the porous body 41, and the droplet and the water vapor move in a direction toward the membrane 44 by the electroosmotic phenomenon.

Only the water vapor among the droplets and the water vapor moved in the direction toward the membrane 44 may pass through the membrane 44.

That is, the droplet and the water vapor may be separated from the membrane 44.

The droplets separated from the membrane 44 are discharged to the outside or the water tank 30 through the droplet discharge unit (not shown).

The water vapor separated from the membrane 44 is discharged to outdoor air.

At this time, since the partial pressure of the water vapor separated from the membrane 44 is higher than the water vapor partial pressure in the outdoor air, the water vapor separated from the membrane 44 by the water vapor partial pressure difference can be smoothly discharged into the outdoor air. .

In general, the suction side pressure in the vacuum pump 50 is very low to about 0.01 bar level, and outdoor air is 1 bar level, which is the atmospheric pressure level.

Therefore, in the absence of the electrical osmosis membrane composite 40, it is impossible to discharge water vapor from the vacuum pump 50, which is 0.01 bar, to outdoor air, which is 1 bar. In order to discharge water vapor directly from the vacuum pump 50 to outdoor air, there is a problem in that the pressure ratio of the vacuum pump 50 must be very high.

On the other hand, since the membrane 44 uses a partial pressure difference of water vapor, the partial pressure of water vapor of the outdoor air outside is lower than the partial pressure of water inside the membrane 44, so that the partial pressure of water vapor from the membrane 44 having a high partial pressure of water vapor is low. It is possible to exhaust with outdoor air

Therefore, by easily discharging water vapor to outdoor air through the electric osmosis membrane composite 40, the vacuum pump 50 having a low pressure ratio can be used.

In addition, since the pressure ratio of the vacuum pump 50 can be lowered and the pressure inside the system can be lowered overall, the cooling efficiency of the system can also be improved.

Although the present invention has been described with reference to the embodiments shown in the drawings, these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: water pump 20: cooling coil
30: water tank 40: electro-osmosis membrane complex
41: porous body 42: electrode
43: support panel 44: membrane
50: vacuum pump

Claims (8)

A water pump for pumping cold water;
A cooling coil for exchanging cold water pumped by the water pump with external air;
A hot water discharge flow path connected to the cooling coil and discharging heated water heat-exchanged from the cooling coil;
A water tank provided between the hot water discharge flow path and the water pump to flow hot water discharged into the hot water discharge flow path;
A vacuum pump provided to be connected to the water tank to cool the inside of the water tank by evaporating hot water in the water tank;
It is provided on the discharge side of the vacuum pump, and when the voltage is applied, the water vapor evaporated by the vacuum pump is moved toward the outdoors by electric osmosis, and the water vapor is outdoor using the partial pressure difference between the water vapor and outdoor air. An electro-osmosis membrane composite to discharge;
It is connected to the water tank, and includes a cold water discharge flow path for guiding the cold water cooled in the water tank to the water pump,
The electro-osmosis membrane composite,
A porous body formed of a porous material to absorb the water vapor evaporated by the vacuum pump,
A pair of electrodes connected to the front and rear surfaces of the porous body,
A power supply unit that applies the voltage to the pair of electrodes,
A membrane provided on the front surface of the porous body, passing only the water vapor among the water droplets and the water vapor absorbed into the porous body, and using the partial pressure difference between the water vapor and outdoor air passing through, the membrane for discharging the water vapor into the outdoor air Including,
The electro-osmosis membrane composite,
The electrode, the porous body, the electrode, the electrical osmosis heat pump system that is a laminate in which the membrane is sequentially stacked. delete The method according to claim 1,
The electro-osmosis membrane composite,
Electric osmosis heat pump system is provided between the electrode and the membrane, further comprising a support panel formed of the porous material. The method according to claim 1,
The electrode, an electric osmosis heat pump system formed in a mesh form to allow the water vapor to pass. The method according to claim 1,
The vacuum pump and the water tank are installed indoors,
The electric osmosis membrane composite is connected to the discharge pipe of the vacuum pump, and the electric osmosis heat pump system installed outdoors. The method according to claim 1,
An electric osmosis heat pump system in which the pressure reducing valve is installed in the hot water discharge passage. delete A water tank in which hot water heated through heat exchange is stored;
A vacuum pump provided to be connected to the water tank to cool the inside of the water tank by evaporating hot water in the water tank;
A porous body formed of a porous material to absorb water vapor evaporated by the vacuum pump, a pair of electrodes connected to front and rear surfaces of the porous body, and a power supply unit that applies a voltage to the pair of electrodes, and the porous body It is provided on the front surface of the sieve, and includes a membrane for discharging the water vapor into the outdoor air, using only the water vapor among the water droplets and the water vapor absorbed into the porous body, and using the partial pressure difference between the water vapor and the outdoor air passing through the water vapor. And, when the voltage is applied to move the water vapor evaporated by the vacuum pump by the electro-osmotic phenomenon in the direction toward the outdoors, and using the partial pressure difference between the water vapor and the outdoor air vapor and the electro-osmosis membrane composite for discharging the water vapor to the outdoor ;
It is connected to the water tank, and includes a cold water discharge passage for discharging the cold water cooled in the water tank,
The electro-osmosis membrane composite,
The electrode, the porous body, the electrode, the electro-osmosis heat pump system is a laminate in which the membrane is sequentially stacked.

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