KR20120056514A - Electrical energy saving type constant -temperature dehumidifier - Google Patents

Abstract

PURPOSE: A constant-temperature dehumidifier for saving electric energy is provided to prevent interferences between gas and fluids flowing through each opening by offering the 3side sealing machine for mixing refrigerants, which has three openings. CONSTITUTION: A constant-temperature dehumidifier for saving electric energy comprises a 3side sealing unit for mixing refrigerants. The 3side sealing unit for mixing the refrigerants is installed instead of a refrigerant mixer, a check valve, and a manual control valve. The 3side sealing unit for mixing the refrigerants comprises a pipe unit, a first inlet pipe on a cylindrical tube, an outlet pipe on the cylindrical tube, and a second inlet pipe on the cylindrical tube. The pipe unit comprises an inner cylinder tube. The inner cylinder tube is extended from a front end opening, a side opening, and an inner surface of a central part. The first inlet pipe and the outlet pipe are welded with being inserted into the front end opening. The second inlet pipe is connected to the side opening. The second inlet pipe is connected to the pipe unit through an interval between the inner cylinder tube and pipe unit.

Description

Electrical energy saving type constant -temperature dehumidifier

The present invention relates to a dehumidifier, and more particularly, by using a refrigerant mixing triangulator having three openings instead of a valve employed in the dehumidifier, a gas or liquid entering and exiting each opening does not interfere with each other in the valve. Since refrigerant is mixed in the valve, the cause of compressor failure due to the pressure change in the pipe is eliminated, so that it is possible to not only improve the reliability of the product but also to save the electric energy due to ultra-low power consumption, and to realize precise temperature control. will be.

In general, the dehumidification method for removing moisture in the air is a cooling method of condensation separation of water vapor below the dew point temperature by cooling, and compression of condensation separation above the saturation point of water by increasing the partial pressure of water vapor by compression. A dehumidification system is constituted by a single method or a combination of two or more types of the method, an absorption method of dehumidifying using a liquid absorbent, and an adsorption method of dehumidifying using a porous adsorbent.

Here, the cooling dehumidifier using the refrigerant compressor includes a compressor (1) for compressing the refrigerant gas, a condenser (2) for liquefying the refrigerant gas compressed through the compressor (1), and the Expansion valve (3) for decompressively expanding the refrigerant liquid condensed in the condenser (2), and an evaporator (4) for cooling and condensing hot and humid air using the refrigerant liquid expanded through the expansion valve (3). do.

The dehumidifier using the conventional refrigerant compressor having the above-described configuration, the hot and humid air sucked while the suction fan 5 rotates is cooled and condensed below the dew point while passing through the surface of the evaporator 4 cooled by the evaporation of the refrigerant. do.

Therefore, the moisture contained in the air is converted into condensate formed by dew drops, and then naturally falls into the drain pipe 7 by the condensate receiver 6, and the cooled, dehumidified dry air passing through the evaporator 4 is While cooling the condenser 2 in the rear of the evaporator 4, the operation of reheating and sending it to the room is repeatedly performed.

Although the dehumidification method is used in an integrated type, the heat of condenser 2 is about 1.2 times higher than that of the evaporator 4, so that the room temperature is increased when continuously operated. Therefore, the room temperature cannot be kept constant. There is this.

As a supplement to the problem that the indoor temperature rises, when the indoor temperature rises by using a 2-way or 3-way solenoid valve as shown in FIGS. A conventional dehumidification method is known in which a refrigerant gas is sent and the indoor temperature is lowered, thereby switching to an indoor waste heat recovery coil to dehumidify.

However, since the conventional two-way dehumidifier shown in FIG. 2 or the conventional three-way dehumidifier shown in FIG. 3 uses only a check valve and a two-way valve or a three-way valve, a cooling function is provided. During operation, if the liquid refrigerant condensed in the waste heat recovery coil is filled with the cooling air passing through the evaporator and the dehumidification is required, when the waste heat line automatic control valve is opened, an impact such as liquid hammering occurs in the pipe. In this case, when the solenoid valve in the condenser direction is closed, a shock is applied to the compressor by a sudden change in the pressure in the pipe, causing frequent valve breakage and failure of the compressor.

In consideration of the above circumstances, as a solution to various problems caused by the conventional dehumidifiers shown in FIGS. 1 to 3, the "air-cooled dehumidifier" filed by the applicant of the present invention is registered as Utility Model Registration No. 0379080 and registered. It is published in the Shinan Gazette.

"Air-cooled dehumidifier" of the Utility Model Registration No. 0379080 is an air-cooled dehumidifier having an evaporator 11, a compressor 12, and a condenser 13, as shown in Figure 4a, wherein the compressor 12 and the condenser 13 A refrigerant branch pipe (20) for separating and supplying a part of the compressed refrigerant branched from the refrigerant connection pipe between the; An inlet end connected to an outlet of the refrigerant branch pipe 20, and a waste heat recovery coil 30 formed of a heat exchanger disposed at a rear end of the evaporator 11 based on the flow path of the inlet air to be dehumidified; A refrigerant pipe (40) connecting the outlet end of the waste heat recovery coil (30) and the condenser (13); It consists of a refrigerant mixer (60) for mixing the refrigerant flowing from the refrigerant engine (40) and the compressor 12 to send to the condenser (13), the flow rate of the incoming refrigerant before the inlet end of the waste heat recovery coil (30) An automatic control valve 50 for controlling is configured, and a check valve 65 for allowing refrigerant to flow only on the refrigerant condenser 13 to the condenser 13 is configured, and the condenser 13 in the compressor 12. On the refrigerant circulation pipe directly connected to the will be made by configuring a manual control valve (70).

Reference numeral 10 denotes a filter, 14 denotes a blower, 15 denotes an expansion valve, and 16 denotes a receiver tank.

However, the "air-cooled dehumidifier" of Utility Model Registration No. 0379080 having the above-described configuration is operated by cooling function operation because each of the check valve 65 and the manual control valve 70 uses only a 2-way valve. When the liquid refrigerant condensed in the waste heat recovery coil 30 is filled with the cooling air passing through the evaporator 11 and the dehumidification is required, when the waste heat line automatic control valve 50 opens, liquid hammering and The same shock is generated, and when the manual control valve 70 in the condenser 13 direction is closed, the compressor 12 is shocked by a sudden change in the pressure in the pipe, and thus the need for frequent adjustment of the manual control valve 70 is required. And will cause inconvenience in use.

In addition, the "water-cooled dehumidifier" filed by the applicant of the present invention is also registered in Utility Model Registration No. 0379081 and posted in the Utility Model Registration.

"Water-cooled dehumidifier" of the Utility Model Registration No. 0379081 is configured as shown in Figure 4b, except for the configuration of the water-cooled condenser 13, the same as the configuration of the air-cooled dehumidifier described above, that is, the problem that occurs in the air-cooled dehumidifier Frequently, the need for adjustment of the manual control valve 70 and inconvenience in use have been caused even in the water-cooled dehumidifier.

Such inconvenience of frequent adjustment and use of the manual control valve 70 not only causes economic loss, but also significantly lowers the reliability of the customer who uses the product, thereby resulting in low responsiveness to the dehumidifier product from the customer. Instead of the check valve 65 and the manual control valve 70 by employing a new refrigerant mixing triangulation machine can be used to reduce the manufacturing cost and completely solve the problem can be significantly reduced electrical energy consumed.

The present invention has been made to solve various drawbacks and problems caused by conventional conventional dehumidifiers and to improve the problems of the applicant's pre-registered utility models. The object of the present invention is to provide three openings instead of the valves employed in the dehumidifiers. By using the refrigerant mixed triangulator having a structure that does not cause interference between the gas or liquid entering each opening, the refrigerant mixed triangulator is formed to eliminate the failure cause of the compressor due to the pressure change in the pipe, thereby improving the reliability of the product. It is to provide an electric energy saving constant temperature dehumidifier with excellent economy.

Another object of the present invention is the energy ultra-low power effect that can maintain the proper temperature and humidity through the most ideal waste heat use, in particular, in the case of reheating by electricity using green energy, it requires only 1/4 of the power of a conventional dehumidifier. It is to provide an electric energy-saving constant temperature dehumidifier.

Still another object of the present invention is to enable precise temperature control without the need of an electric auxiliary heater required for precise temperature control in a conventional conventional dehumidifier. In addition, the present invention provides an electric energy-saving constant temperature dehumidifier capable of realizing precise temperature control even in the case of temperature control using a sub-motor in one stage.

Still another object of the present invention is to operate the waste heat recovery coil in series while lowering the operating current of the compressor to increase the coefficient of performance in the case of the dehumidification operation, so that the valve failed even when the valve fails. Compressor failure does not occur because it does not cause a high pressure rise, it is to provide an electric energy-saving constant temperature dehumidifier that can greatly extend the life of the constant temperature dehumidifier simply by replacing the failed valve.

Electric energy saving constant temperature dehumidifier of the present invention for achieving the above object is the filter 10 and the evaporator 11, the compressor 12, the air-cooled condenser or water-cooled condenser 13, the blower 14, the receiver tank 16 And a refrigerant part which is separated from the expansion valve 15 installed before the inlet end of the evaporator 11 and the refrigerant connection pipe between the compressor 12 and the condenser 13 and supplies a part of the compressed refrigerant. The waste heat recovery coil 30 consisting of the engine 20 and a heat exchanger disposed at the rear end of the evaporator 11 based on the flow path of the inlet air to be dehumidified by the inlet end connected to the outlet of the refrigerant branch pipe 20. And a refrigerant pipe (40) connecting the outlet end of the waste heat recovery coil (30) to the air-cooled condenser or the water-cooled condenser (13) and the inlet end of the waste heat recovery coil (30) to regulate the flow rate of the inflow refrigerant. Automatic control valve 50 and the refrigerant Refrigerant mixer 60, which mixes the refrigerant flowing from the engine 40 and the compressor 12, and sends it to the air-cooled condenser 13, and the air-cooled condenser or water-cooled condenser 13 installed on the refrigerant engine 40 Air-cooled or consisting of a check valve (60 'or 65) for allowing the refrigerant to flow only, and a manual control valve (70) installed on the refrigerant circulation pipe connected between the compressor (12) and the air-cooled condenser or water-cooled condenser (13) In a water-cooled dehumidifier; Instead of the coolant mixer 60, the check valve 60 ′ or 65, and the manual control valve 70, one coolant mixer trigear 100 is installed.

The present invention uses a refrigerant mixing triangulator having three openings instead of the valves employed in the dehumidifier, so that the inside of the refrigerant mixing triangulation is formed in a structure that does not cause interference between gases or liquids entering and exiting each opening. The cause of compressor failure is eliminated, which not only improves the reliability of the product, but also provides excellent economic efficiency. The energy saving effect, especially in the case of reheating by electricity using green energy, can maintain proper temperature and humidity through the most ideal waste heat use. It requires only 1/4 of the power of a conventional dehumidifier, which enables ultra-power saving, and precise temperature control is possible without the electric auxiliary heater required for precise temperature control in a conventional dehumidifier. By controlling the temperature step by step, the deviation of the control temperature can be reduced. In addition, precise temperature control can be realized even in the case of temperature control using a sub-motor in one stage.In the case of dehumidification operation, it is possible to connect waste heat recovery coils in series while increasing the coefficient of performance by lowering the operating current of the compressor. Therefore, even in the case of a valve failure, a failed valve does not cause an abnormal high pressure rise of the compressor, and thus, a compressor failure does not occur. Therefore, there is a particular advantage that the life of the constant temperature dehumidifier can be greatly extended by simply replacing the failed valve.

1 is a configuration diagram of a conventional cooling dehumidifier,
2 is a block diagram of a conventional two-way air-cooled dehumidifier,
3 is a block diagram of a conventional three-way air-cooled dehumidifier,
Figure 4a is a block diagram of a conventional air-cooled dehumidifier,
Figure 4b is a block diagram of a conventional water-cooled dehumidifier,
Figure 5a is a block diagram of the air-cooled electric energy-saving constant temperature dehumidifier of the present invention,
Figure 5b is a block diagram of the water-cooled electric energy-saving constant temperature dehumidifier of the present invention,
6 is a perspective view of the refrigerant mixing triangulator according to the present invention,
7 is a cross-sectional view of the refrigerant mixing triangulator according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the electric energy-saving constant temperature dehumidifier of the present invention.

Figure 5a is a block diagram of the present invention air-cooled electric energy-saving constant temperature dehumidifier, Figure 5b is a block diagram of the water-cooled electric energy-saving constant temperature dehumidifier of the present invention, Figure 6 is a perspective view of a refrigerant mixing triplex according to the present invention, Figure 7 is the present invention As a cross-sectional view of the refrigerant mixing triangulation according to the present invention, the electric energy-saving thermostatic dehumidifier of the present invention includes a filter 10, an evaporator 11, a compressor 12, an air-cooled condenser or a water-cooled condenser 13, a blower 14, and a receiver tank 16. Is provided, and separates and supplies a portion of the compressed refrigerant branched from the refrigerant connection pipe between the expansion valve 15 and the compressor 12 and the condenser 13 installed before the inlet end of the evaporator 11. A waste heat recovery coil (30) consisting of a refrigerant branch pipe (20) and an inlet end connected to an outlet of the refrigerant branch pipe (20), and a heat exchanger disposed at the rear end of the evaporator (11) based on the flow path of the inflow air to be dehumidified. ) And the waste heat A refrigerant regulator (40) connecting the outlet end of the water coil (30) and the air-cooled condenser or water-cooled condenser (13), and is automatically installed to adjust the flow rate of the incoming refrigerant is installed before the inlet end of the waste heat recovery coil (30) A valve 50, a refrigerant mixer 60 which mixes the refrigerant flowing from the refrigerant engine 40 and the compressor 12 and sends it to the air-cooled condenser 13, and is installed on the refrigerant engine 40 Check valve (60 'or 65) for allowing the refrigerant to flow only to the air-cooled condenser or the water-cooled condenser (13), and the manual control installed on the refrigerant circulation pipe connected between the compressor 12 and the air-cooled or water-cooled condenser (13) In an air-cooled or water-cooled dehumidifier consisting of a valve 70; Instead of the refrigerant mixer 60, the check valve 60 ′ or 65, and the manual control valve 70, one refrigerant mixer trigeerator 100 is installed.

The refrigerant mixing triangular chamber (100) comprises: a tubular body (101) having front end openings (101a, 101b), side openings (101c), and an inner cylindrical tube (101d) extending from an inner side in a central portion thereof; A first inlet pipe 102 on the cylindrical pipe body inserted into the tip opening 101a and fixed by welding; An outlet tube 103 on the cylindrical tube body inserted into the tip opening portion 101b and fixed by welding; And a second inlet tube 104 on the cylindrical tube body fixedly connected to the side opening 101c, wherein the second inlet tube 104 is connected between the tube body 101 and the inner cylindrical tube 101d. 101).

In addition, the coolant mixture triangulator 100 has a cube in the outer peripheral surface of the central portion.

In addition, the first inlet pipe 102 is connected to the outlet end of the waste heat recovery coil 30, the second inlet pipe 104 is connected to the outlet end of the compressor 12, the outlet pipe ( 103 is connected to the inlet end of the air cooled condenser or water cooled condenser 13.

Next will be described in detail the operation of the electric energy-saving constant temperature dehumidifier configured as described above.

When operating the electric energy-saving constant temperature dehumidifier of the present invention, the air in the dehumidification room is introduced into the filter 10, filtered, and then applied to the compressor 12 through the evaporator 11, and the compressor 12 compresses the refrigerant. The compressed high-temperature high-pressure refrigerant gas is discharged from the compressor 12 and transferred to the air-cooled condenser or the water-cooled condenser 13 through the refrigerant mixing triangulator 100, and a part of the refrigerant gas passes through the refrigerant branch pipe 20. It is introduced into the waste heat recovery coil (30).

Compression heat (waste heat) generated by the compression of the refrigerant of the compressor 12 is recovered to the waste heat recovery coil 30 through the refrigerant branch pipe 20 and heat exchanged in the waste heat recovery coil 30 made of a heat exchanger.

The refrigerant gas introduced into the air-cooled condenser or the water-cooled condenser 13 circulates through the receiver tank 16 and the expansion valve 15 to the evaporator 11 and flows back into the compressor 12 to be introduced into the compressor 12. Air cooling and dehumidification operation is performed.

At this time, the refrigerant gas introduced into the waste heat recovery coil 30 passes through the waste heat recovery coil 30 and then is recycled through the refrigerant recovery pipe 40. Thus, the refrigerant gas is recovered from the waste heat recovery coil 30 and the compressor 12. The refrigerant is mixed in the refrigerant mixing triangulator 100 and circulated to the air-cooled condenser or the water-cooled condenser 13 and the receiver tank 16.

As a result, the cool, saturated steam with high humidity in the conventional dehumidifier is raised to an appropriate room temperature through the waste heat recovery coil 30, so that the temperature of the air becomes an appropriate temperature, and the humidity in the air is low relative humidity. Since it is changed to a very comfortable air it is possible to provide a dehumidifying and fresh air.

As described above, the electric energy-saving constant temperature dehumidifier of the present invention uses the heat of compression (waste heat) generated by the compression of the refrigerant of the compressor 12 by the waste heat recovery coil 30, thereby eliminating the use of an electric heater. The economic burden could be eliminated.

In addition, by adopting the refrigerant pipe refrigerant mixture three-way discharger 100, the separate solenoid valve or 3-way valve constituting the two refrigerant circuits in the refrigerant pipe is not required, which is lowered by the operation of the individual solenoid valve or 3-way valve. Electric energy consumed for room temperature compensation can be reduced.

While the present invention has been described as a preferred embodiment, the present invention is not limited thereto and can be variously modified and implemented within the scope not departing from the gist of the invention.

10 filter 11: evaporator
12 Compressor 13 Air or Water Cooled Condenser
14 blower 15 expansion valve
16: receiver tank 20: refrigerant branch pipe
30: waste heat recovery coil 40: refrigerant exhaust pipe
50: automatic control valve 100: refrigerant mixing triangulator
101: tube 101a, 101b: tip opening
101c: side opening 101d: inner cylindrical tube
102: first inlet pipe 103: outlet pipe
104: second entrance tube

Claims (4)

The filter 10 and the evaporator 11, the compressor 12, the air-cooled condenser or water-cooled condenser 13, the blower 14, the receiver tank 16 is provided, the expansion is installed before the inlet end of the evaporator 11 A valve branch, a refrigerant branch pipe (20) which separates and supplies a part of the compressed refrigerant branched from the refrigerant connection pipe between the compressor (12) and the condenser (13), and the outlet of the refrigerant branch pipe (20). A waste heat recovery coil 30 formed of a heat exchanger disposed at a rear end of the evaporator 11 on the basis of an inlet air passage that is connected to an inlet end thereof, and an outlet end of the waste heat recovery coil 30 and the air-cooled condenser or Refrigerant engine (40) for connecting the water-cooled condenser (13), an automatic control valve (50) installed before the inlet end of the waste heat recovery coil (30) to regulate the flow rate of the incoming refrigerant, and the refrigerant engine (40) ) And air-cooled condensate by mixing refrigerant from the compressor 12 And a check valve 60 'or 65 installed on the refrigerant mixer 60 to be sent to the 13, the refrigerant pipe 40, and allowing the refrigerant to flow only to the air-cooled condenser or the water-cooled condenser 13. 12) and an air-cooled or water-cooled dehumidifier comprising a manual control valve (70) installed on a refrigerant circulation pipe connected between the air-cooled condenser or the water-cooled condenser (13);
An electric energy-saving constant temperature dehumidifier, characterized in that the refrigerant mixing triangulator (100) is installed in place of the refrigerant mixer (60), the check valve (60 'or 65) and the manual control valve (70). According to claim 1, wherein the refrigerant mixing triangular chamber 100 is a tubular body (101) having a front end opening (101a, 101b) and side opening (101c) and an inner cylindrical tube (101d) extending from the inner side in the central portion; ; A first inlet pipe 102 on the cylindrical pipe body inserted into the tip opening 101a and fixed by welding; An outlet tube 103 on the cylindrical tube body inserted into the tip opening portion 101b and fixed by welding; And a second inlet tube 104 on the cylindrical tube body fixedly connected to the side opening 101c, wherein the second inlet tube 104 is connected between the tube body 101 and the inner cylindrical tube 101d. 101) is an electric energy-saving constant temperature dehumidifier in communication with. According to claim 2, The refrigerant mixing triangulator 100 is an electric energy-saving constant temperature dehumidifier, characterized in that the outer peripheral surface of the central portion forms a cube. The method of claim 2, wherein the first inlet pipe 102 is connected to the outlet end of the waste heat recovery coil 30, the second inlet pipe 104 is connected to the outlet end of the compressor 12, The outlet tube 103 is an electric energy-saving constant temperature dehumidifier, characterized in that connected to the inlet end of the air-cooled condenser or water-cooled condenser (13).

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