KR100652888B1 - The airconditioner with condenser of triple pipe sructure - Google Patents

Abstract

The present invention relates to an air conditioner having a triple tube condenser.

An air conditioner having a condenser of a triple pipe structure of the present invention is composed of a compressor, a condenser, a capillary tube, an evaporator, a water support, a water tank, a water pump, a water level sensor, a temperature sensor, a controller, and an air fan.

The air conditioner having the condenser of the triple pipe structure of the present invention can be cooled by using the water and the refrigerant of the first and the third pipes without installing the condenser outside, so that the installation cost and The production cost is low and the efficiency is high because the condenser is cooled by using water and refrigerant.

Air Conditioner, Triple Tube, Condenser, Evaporator, Temperature Sensor

Description

Air conditioner with triple pipe condenser {THE AIRCONDITIONER WITH CONDENSER OF TRIPLE PIPE SRUCTURE}

1 is an internal configuration of an air conditioner having a condenser of a triple tube structure of the present invention.

Figure 2 is a cross-sectional view of the condenser of the air conditioner having a condenser of the triple tube structure of the present invention.

Figure 3 is a cross-sectional perspective view of the condenser of the air conditioner of the present invention.

Figure 4 is an external perspective view of the air conditioner of the present invention.

5 is a flowchart in which water is sent from the water tank of the air conditioner of the present invention to the first pipe.

6 is a flowchart in which water is sent from the outer tube of the air conditioner of the present invention to the first tube.

<Description of the symbols for the main parts of the drawings>

100: compressor 200: condenser

210: Hall 1 220: Hall 2

230: tube 3 300: capillary tube

400: evaporator 500: drip tray

600: water tank 610: water level sensor

620: temperature sensor 700: water pump

710: first valve 720: second valve

800: control unit 900: air fan

1000: enclosure 1010: air conditioning vent

1020: exit 1 of the building 1010: exit 1 of building 1

The present invention relates to an air conditioner having a triple tube condenser.

As a related art of air conditioner, Korean Utility Model Publication No. 20-020457 (air conditioner without outdoor) is disclosed.

The technology is composed of a condensation means, a spray means, a cooling means, and relates to a technology that the condensed water heat exchanged with the refrigerant while passing through the condenser to maintain the proper temperature by the cooling means to increase the condensation efficiency, the condensate water vapor As the state changes, the amount of loss is reduced, thereby reducing the maintenance cost.

However, the above technique has a problem in that the cooling efficiency is lowered because only one cooling means cools the condenser.

In another related art of air conditioner, Patent Publication No. 10-0396439 discloses an air conditioner without an outdoor unit for cooling a condenser using air and steam.

The technology consists of a condenser fan, a condenser case, a condenser, a vibrator case, a water level regulator, a vibrator, and an air flow control plate, in which air and water vapor flow together through the condenser fan to contact the condenser to perform heat exchange and discharge to the outside. It is a tube.

However, the above technique has a problem in that the cooling efficiency is lowered because only one cooling means cools the condenser.

In order to solve the above problems, the air conditioner of the present invention uses a triple pipe condenser, a water level sensor, and a temperature sensor, so that the air can be cooled without installing the condenser outside.

The present invention relates to an air conditioner having a triple tube condenser.

The air conditioner provided with the condenser of the triple tube structure of this invention,

Since the condenser can be cooled using water and refrigerant in the first and third pipes without external installation, the installation cost and production cost are lower than the air conditioner with the outdoor unit, and the condenser is doubled using water and refrigerant. Cooling efficiency is high.

Air conditioner of the present invention,

A compressor 100 that sucks gas refrigerant and increases pressure to liquefy condensation in the condenser 200;

A condenser (200) for dissipating heat from the refrigerant sent from the compressor (100) by using the water in the first tube (210) and the refrigerant in the third tube (230);

A capillary tube 300 connected to the second tube 220 of the condenser 200 and having an inner diameter of about 5 to 8 times smaller than the inner diameter of the second tube 220;

An evaporator 400 connected to one end of the capillary tube 300 and having an inner diameter of about 5 to 8 times larger than the inner diameter of the capillary tube 300;

It is installed in the lower portion of the evaporator, the inclination is made so that the water can be gathered to the center portion, the water support (500) made of a hole in which the water falls out;

A water tank 600 installed at a lower portion of the water support 500 and collecting water falling from the water support 500;

A water pump 700 connected to the first valve 710 connected to the water tank 600 and a second valve 720 connected to the outer pipe and sending water to the first pipe 210;

A water level sensor 610 installed in the water tank 600, a temperature sensor 620 installed in the condenser 200, and a controller 800 electrically coupled to the water pump 700;

It is installed at the rear of the evaporator 400, and consists of an air fan 900 for sending wind to the outside through the evaporator 400.

The technical spirit of the present invention will be described in detail with reference to the drawings.

However, the technical idea of the present invention is not limited by the drawings.

1 is an overall configuration diagram of an air conditioner of the present invention.

Air conditioner of the present invention compressor 100, condenser 200, capillary tube 300, evaporator 400, water support 500, water tank 600, water pump 700, control unit 800, air fan ( 900, the enclosure 1000.

Compressor 100 of the air conditioner of the present invention increases the pressure to the saturation pressure corresponding to the condensation temperature to suck the low-temperature low-pressure gas refrigerant evaporated in the evaporator 400 to liquefy condensation in the next condenser 200 The device consists of a compressor used in conventional air conditioners.

The condenser 200 of the air conditioner of the present invention is a device for condensing liquid by releasing heat of the gas refrigerant by exchanging the high temperature and high pressure gas refrigerant discharged from the compressor 100 to surrounding air or cooling water.

The condenser 200 of the present invention will be described in detail with reference to FIG.

The condenser 200 is coupled to the first tube 210 of the center, the second tube 220 surrounding the first tube 210, and the third tube 230 surrounding the second tube 220 is coupled do.

The second tube 220 of the condenser 200 is a tube that functions as the condenser 200 of the conventional air conditioner and condenses the refrigerant to discharge heat of the gas refrigerant.

The first pipe 210 of the condenser 200 flows water sent from the water pump 700 to cool the refrigerant in the second pipe 220 of the condenser 200.

Water sent to the first tube 210 of the condenser 200 serves to cool the refrigerant flowing through the second tube 220 of the condenser 200 primarily.

The third tube 220 of the condenser 200 serves to cool the second tube 220 by flowing the liquefied refrigerant sent through the evaporator 400.

The third tube of the condenser 200 surrounds the second tube 220, cools down the heat of the refrigerant, and enters the compressor 100 again.

3 is a cross-sectional perspective view of the condenser 200.

The first pipe 210 and the third pipe 230 of the condenser 200 may be changed by changing the coupling relationship.

That is, the first tube 210 may be inserted into the third tube 230 around the second tube 220 to form a triple tube structure.

In addition, the first tube 210 and the third tube 230 of the condenser 200 may be made by changing the coupling position of both ends.

That is, the water flowing into the first pipe 210 may be started from the place where the condenser 200 and the capillary pipe 300 are connected, and the start of the refrigerant flowing into the third pipe 230 may be a compressor ( You can also start from the beginning of 100).

The first pipe 210 of the condenser 200 adjusts the inflow and outflow of water by the action of the water pump 700, the first valve 710 and the second valve 720.

When water flows into the first pipe 210 of the condenser 200, the sensing data for the level of water is sent from the water level sensor 610 installed in the water tank 600 to the control unit 800. When the abnormality is crossed from the water level sensor 610, the first valve 710 is opened by sending a signal to open the first valve 710.

Next, when the control unit 800 sends a signal for driving the water pump 700, the water pump 700 is activated and the water collected in the water tank 600 flows through the first pipe 210 to open the second pipe of the condenser. Cool it down.

FIG. 5 is a flowchart illustrating a process in which water flows through the first pipe 210 of the condenser 200 by sensing the water level sensor 610 described above.

A process in which water flows through the first pipe 210 of the condenser 200 by the temperature sensor 620 will be described.

The temperature sensor 620 periodically senses the temperature of the second tube 220 of the condenser 200 and sends it to the controller 800. Next, when the value sent from the temperature sensor 620 becomes higher than the specified value, the controller 800 sends a signal to open the second valve 720.

The second valve 720 receiving the signal from the controller 800 is opened, a signal for operating the water pump 700 is sent from the controller 800 to operate the water pump 700, and the first of the condenser 200. Water flows through the pipe 210 to cool the second pipe 220 of the condenser.

FIG. 6 is a flowchart illustrating a process in which water flows through the first pipe 210 of the condenser 200 by sensing the temperature sensor 620.

Water flowing through the first pipe 210 of the condenser 200 is introduced / outflowed by the values of the two sensing devices of the water level sensor 610 and the temperature sensor 620.

The capillary tube 300 is a portion for compressing the refrigerant passing through the condenser 200 through a narrow space.

It is connected to the end of one end of the second tube 220 of the condenser 200.

The inner diameter of the capillary tube 300 is between 1/8 and 1/10 of the inner diameter of the second tube of the condenser 200.

This is the highest efficiency.

The evaporator 400 is connected to the end of one end of the capillary 300, and has an inner diameter of about 8 to 10 times the inner diameter of the capillary 300.

The evaporator 400 is a portion that substantially cools to a place where the refrigerant taken out through the capillary tube 300 vaporizes the surrounding heat while vaporizing. An air fan 900 is installed at the rear of the evaporator 400.

The wind generated from the air fan 900 becomes cold wind through the evaporator 400 and flows out.

The refrigerant vaporized in the evaporator 400 and liquefied again is introduced again through the third pipe 230 of the condenser 200.

One end of the evaporator 400 is connected to the third tube of the condenser 200.

The drip tray 500 is for receiving water droplets formed on the surface of the evaporator 400. It is installed below the evaporator 400 and receives the water and sends it down. Drip tray 500 is inclined so that the water can be collected well, there is a hole in the center of the water falls into the hole.

The water tank 600 is a place where the water collected through the drip tray 500 collects.

The water level sensor 600 is provided with a water level sensor 610 therein.

The water level sensor 610 detects the amount of water and transmits the value to the controller 800.

Water flowing through the water tank 600 is connected to the first valve (710).

The water stand 500 or the water tank 600 is made of various materials using plastic or iron.

Water pump 700 is a pump for sending water to the first pipe 210 of the condenser 200 is composed of a general small water pump. It is electrically connected to the controller 800 and controlled by the controller 800.

The second valve 720 is a valve for introducing external water into the first pipe 210 of the condenser 200.

The first valve 710 and the second valve 720 may use a solenoid valve or a hydraulic valve.

The controller 800 receives the values of the water level sensor 610 and the temperature sensor 620, and operates the first valve 710, the second valve 720, and the water pump 730 from the input values. .

The first valve 710 and the water pump 730 are operated when the value of the water level sensor 610 is greater than or equal to a predetermined value, and the second valve 720 is greater than or equal to the predetermined value. And the water pump 730 is operated.

The controller 800 may be configured as a microcontroller, CPI, PLC, or the like.

4 is a perspective view of the air conditioner of the present invention.

Enclosure 1000 of the air conditioner can be made in a variety of variations in the range that can accommodate the components therein.

The function of the air conditioner provided with the condenser of the triple tube structure of this invention is demonstrated.

The refrigerant enters the second tube 220 of the condenser 200 through the compressor 100.

At this time, the water flows through the water pump 700 to the first pipe 210 installed in the center of the condenser 200 by cooling the heat generated in the second pipe 220 of the condenser 200, the third of the outer shell In the tube 230, a cool refrigerant flowing through the evaporator 400 flows.

The water and the coolant flowing through the first pipe 210 and the third pipe 230 cool the coolant flowing through the second pipe 220.

The refrigerant flowing through the second tube 220 of the condenser 200 is compressed through the capillary tube 300 and vaporized again through the evaporator 400 to take heat away from the surroundings, thereby reducing the temperature.

At this time, by blowing wind from the air fan 900 to send the cold air to the outside.

The air conditioner provided with the condenser of the triple tube structure of this invention,

Since the condenser can be cooled using water and refrigerant in the first and third pipes without installing the condenser, the installation cost and the production cost are lower than those of the air conditioner having the outdoor unit.

In addition, since the condenser is cooled by using water and a refrigerant, the efficiency is high.

Claims (4)

delete In the air conditioner, A compressor 100 that sucks gas refrigerant and increases pressure to liquefy condensation in the condenser 200; A condenser (200) for dissipating heat from the refrigerant sent from the compressor (100) by using the water in the first pipe (210) and the refrigerant in the third pipe (230); A capillary tube 300 connected to the second tube 220 of the condenser 200 and having an inner diameter of about 5 to 8 times smaller than the inner diameter of the second tube 220; An evaporator 400 connected to one end of the capillary tube 300 and having an inner diameter of about 5 to 8 times larger than the inner diameter of the capillary tube 300; It is installed in the lower portion of the evaporator, the inclination is made so that the water can be gathered to the center portion, the water support (500) made of a hole in which the water falls out; A water tank 600 installed at a lower portion of the water support 500 and collecting water falling from the water support 500; A water pump 700 connected to the first valve 710 connected to the water tank 600 and a second valve 720 connected to the outer pipe and sending water to the first pipe 210; A water level sensor 610 installed in the water tank 600, a temperature sensor 620 installed in the condenser 200, and a controller 800 electrically coupled to the water pump 700; Is installed in the rear part of the evaporator 400, and consists of an air fan 900 for sending the wind to the outside through the evaporator 400, The condenser 200 is the first tube 210 of the most center, the second tube 220 surrounding the first tube 210, and the third tube 230 surrounding the second tube 220 is Characterized in that combined, Air conditioner with triple tube condenser In the air conditioner, A compressor 100 that sucks gas refrigerant and increases pressure to liquefy condensation in the condenser 200; A condenser (200) for dissipating heat from the refrigerant sent from the compressor (100) by using the water in the first pipe (210) and the refrigerant in the third pipe (230); A capillary tube 300 connected to the second tube 220 of the condenser 200 and having an inner diameter of about 5 to 8 times smaller than the inner diameter of the second tube 220; An evaporator 400 connected to one end of the capillary tube 300 and having an inner diameter of about 5 to 8 times larger than the inner diameter of the capillary tube 300; It is installed in the lower portion of the evaporator, the inclination is made so that the water can be gathered to the center portion, the water support (500) made of a hole in which the water falls out; A water tank 600 installed at a lower portion of the water support 500 and collecting water falling from the water support 500; A water pump 700 connected to the first valve 710 connected to the water tank 600 and a second valve 720 connected to the outer pipe and sending water to the first pipe 210; A water level sensor 610 installed in the water tank 600, a temperature sensor 620 installed in the condenser 200, and a controller 800 electrically coupled to the water pump 700; Is installed in the rear part of the evaporator 400, and consists of an air fan 900 for sending the wind to the outside through the evaporator 400, When the control unit 800 receives a signal greater than a predetermined value from the water level sensor 610, it is characterized in that for transmitting a signal for opening the first valve 710 and a signal for operating the water pump 700, Air conditioner with triple tube condenser In the air conditioner, A compressor 100 that sucks gas refrigerant and increases pressure to liquefy condensation in the condenser 200; A condenser (200) for dissipating heat from the refrigerant sent from the compressor (100) by using the water in the first pipe (210) and the refrigerant in the third pipe (230); A capillary tube 300 connected to the second tube 220 of the condenser 200 and having an inner diameter of about 5 to 8 times smaller than the inner diameter of the second tube 220; An evaporator 400 connected to one end of the capillary tube 300 and having an inner diameter of about 5 to 8 times larger than the inner diameter of the capillary tube 300; It is installed in the lower portion of the evaporator, the inclination is made so that the water can be gathered to the center portion, the water support (500) made of a hole in which the water falls out; A water tank 600 installed at a lower portion of the water support 500 and collecting water falling from the water support 500; A water pump 700 connected to the first valve 710 connected to the water tank 600 and a second valve 720 connected to the outer pipe and sending water to the first pipe 210; A water level sensor 610 installed in the water tank 600, a temperature sensor 620 installed in the condenser 200, and a controller 800 electrically coupled to the water pump 700; Is installed in the rear part of the evaporator 400, and consists of an air fan 900 for sending the wind to the outside through the evaporator 400, When the control unit 800 receives a signal greater than a predetermined value from the temperature sensor 620, a signal for opening the second valve 710 and a signal for operating the water pump 700, characterized in that, Air conditioner with triple tube condenser

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