KR950004394Y1 - Removing frost by hot fluid - Google Patents

Abstract

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Description

Cooling dehumidifier

1 is a schematic diagram showing a preferred embodiment of the present invention.

Figure 2 is a schematic diagram showing in more detail the configuration of the subject innovation.

3 is a schematic diagram showing a case where the first cooler is operated as an operational state diagram of the present invention.

Figure 4 is a schematic diagram showing a case of operating the second cooler as an operating state of the present invention.

* Explanation of symbols for main parts of the drawings

1, 2: 1st, 2nd expansion valve 3: condenser

4: compressor 10, 20: first and second cooler

12, 22: 1st, 2nd check valve 15, 25: 1st, 2nd solenoid valve

16, 26: 3rd, 4th check valve 17, 27: 1st, 2nd direct connection refrigerant pipe

30, 40: 1, 2-4 port 4-way control valve

The present invention can achieve the temperature of the outlet air below a predetermined temperature, but efficiently improves the refrigerant circuit formed between the compressor and the condenser, the condenser and the expansion valve, the expansion valve and the cooler and the cooler and the compressor, and between the compressor and the cooler and The present invention relates to a cooling dehumidifying apparatus having a four-port four-way control valve installed between a condenser and an expansion valve to improve defrost efficiency.

In general, the cooling dehumidifier has an advantage in terms of performance or price compared to other conventional dehumidification method, but the efficiency is reduced due to the accumulation (적) generated in the cooler during operation. Thus, various techniques have been developed to improve the phenomenon of in-operation during the operation. A typical example is two or more coolers installed so that when one of the coolers increases, the operation switch is made to automatically operate the other cooler. In the meantime, the stacked cooler may be defrosted by a spraying method or a hot gas defrosting device to allow continuous cooling and dehumidification.

Similarly, Korean Patent Publication No. 84-852 "Low Dew Point Cooling Dehumidifier" is disclosed, in which case two compressors are continuously operated in a refrigeration apparatus below 0 ° C having two cooling coils of the same capacity. One side of the cooler continues to cool for a certain period of time and the air is passed through to lower the temperature. When the frost is attached, the other side of the cooler immediately operates the other cooler to maintain the cooling action. The cooling coil with frost and the defrosting cooling coil are defrosted, so that the opposite operation can be continued to easily obtain an outlet air of 0 ° C or less.

However, in this device, a plurality of refrigerant lines are formed between the condenser and each cooler, and between each cooler and the compressor, and a plurality of valves for controlling them are also installed, which makes the structure complicated and enlarges the size of the device. It is uneconomical.

In addition, it is possible to install and operate a separate refrigeration cycle structure and a defrosting facility having a separate heat exchanger coil, a cooler, and an indoor condenser, so that the overall efficiency can be improved. The result is that the price of the device is too large and the overall size of the device is too large.

Also, although not directly related to the present invention, Japanese Utility Model Publication No. 62-149761 is disclosed as a related technology, which simultaneously uses two evaporators to meet the operation required for initial quenching in a refrigerated showcase. Although it can be used as a cooling mode, when two evaporators are operated simultaneously, both sides generate a red phenomena at the same time, which leads to difficulties in using for a long time and has a problem of defrost, and one of the two evaporators is in a cooling mode. For the other one, even when operating in the defrost mode, the evaporator is defrosted only after the refrigerant passes through the condenser, not the compressor, so that the defrosting efficiency is lowered and the evaporator is continuously defrosted even after the defrost is completed. Has been exposed to unrealistic problems It is not suitable for application to cooling dehumidifiers.

The present invention has been researched and developed to solve the above-described problems of the prior art, and any one of the first expansion valve, the first cooler, the second expansion valve, and the second cooler in which the refrigerant is installed in parallel via the condenser from the compressor And a refrigerant circuit from the compressor to the compressor, and between the compressor and the first and second coolers, and between the first and second expansion valves and the condenser, respectively, the first and second four-port four-way control valves are installed. Between the 4-port 4-way control valve and the 1st and 2nd expansion valves, the 1st and 2nd direct connection refrigerant pipes which connected the 1st, 2nd solenoid valves, and the 3rd and 4th check valves in series are provided for cooling and dehumidification. By providing a device, it is possible to defrost the cooler by using a high-temperature refrigerant in the case of a compressor to improve the defrosting efficiency and to move the refrigerant directly without passing through the cooler after the defrost is completed. And it is an object to enable the overall simplicity, the efficient utilization of the refrigerant line, and cost-effective utilization of the structure.

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

As shown in FIG. 1 and FIG. 2, the cooling dehumidifying device of the present invention has a first expansion valve 1, a first cooler 10, and a second case when the refrigerant passes from the compressor 4 to the condenser 3. The expansion valve 2 and the second cooler 20 are connected in parallel, respectively, and have a refrigerant circuit passing through any one of them to the compressor 4 again, and any one of the first and second coolers 10 and 20. When the cooling operation is performed on one side, the other side of the first and second check valves 12, in which the refrigerant is connected in parallel with the first and second coolers 10 and 20 and the first and second expansion valves from the compressor 4, respectively, In a conventional refrigeration cycle in which a defrost can be achieved by reaching the condenser 3 through any one of the sides 22, the first to fourth ports between the compressor 4 and the first and second coolers 10 and 20. A conduit is connected through the 4-way control valve 40, and the 2-4 port 4-way control valve 30 is connected between the condenser 3 and the first and second expansion valves 1 and 2. A pipe is connected through the first and second four-way 4-way control valves (40) and the refrigerant inlet pipes of the first and second expansion valves (1, 2) between the first and second solenoid valves (15, 25) The 3 and 4 check valves 16 and 26 are connected to the first and second direct connection refrigerant pipes 17 and 18 respectively connected in series.

In this case, the first and second solenoid valves 15 and 25 serve to open and close the first and second direct connection refrigerant pipes 17 and 27, and the third and fourth check valves 16 and 26 are configured to reverse the flow of refrigerant. Is installed to prevent.

In addition, the first, 2-4 port 4-way control valve (40, 30) is preferably using a 4-port 4-way solenoid valve (4 Port-4Way Solenoid Valve).

11 and 21 are common refrigerant pipes, 13 and 23 are refrigerant pipes having first and second check valves 12 and 22 and 14 and 24 are refrigerants having first and second expansion valves 1 and 2, respectively. Conduit, 31 air inlet duct, 32 air outlet duct, 33 low pressure gauge. 34 accumulator, 35 high pressure gauge, 36 oil separator, 37 safety valve, 38 solenoid valve, 39 filter drier, 41, 45 condensing pressure regulator, 42 receiver tank, 46 condensing pressure regulator A hot gas bypass pipe, in which 45 is provided, denotes dampers for adjusting the air feeding direction.

Next will be described with respect to the action and effect of the present invention, the dehumidifying device made as described above.

First, a case in which the cooling dehumidifier is operated using the first cooler 10, as shown in FIG. 3, the refrigerant is supplied from the compressor (4) to the oil separator (36) to the 1-4 port 4-way control valve ( 40) → common refrigerant line (21) → 2-4 port 4-way control valve (30) → condenser (3) → receiver tank (42) → control valve (30) → first expansion valve (1) Installed refrigerant line 14 → first cooler 10 → refrigerant outlet line 18 of the first cooler 10 → common refrigerant line 11 → 1-4 port 4-way control valve 40 → accumulator ( 34) The cycle from the compressor (4) is made.

At this time, when the defrost of the second cooler 20 is necessary, the refrigerant that maintains a high temperature while passing through the compressor 4 that blocks the second solenoid valve 25 is a common refrigerant pipe passage 21 → the second cooler 20. The second cooler 20 is defrosted by the heat of the refrigerant while being moved through the refrigerant pipe 23 having the second check valve 22 installed thereinto, and then passing through the second four-port four-way control valve 30. If the defrost of the second cooler 20 is completed while the coolant passes through the second cooler 20 as described above, the second solenoid valve 25 is opened so that the high temperature coolant does not pass through the second cooler 20. The second solenoid valve 25 and the fourth check valve 26 are directly connected to the second through 4-port 4-way control valve 30 via the second direct connection refrigerant pipe 27 installed therein.

Thus, as shown in FIG. 1, the air introduced from the air inlet duct 31 while the first cooler 10 operates is changed into a cooled state through the first cooler 10, and the air outlet duct ( 32) is supplied to a conventional dehumidification chamber provided separately.

At this time, if an accumulation phenomenon occurs in the first cooler 10 by continuing the operation for a certain degree, the first and second four-port four-way control valves 40 and 30 are operated to change the refrigerant line and the second cooler 20 In this case, as shown in FIG. 4, the compressor (4) → the 1-4 port 4-way control valve 40 → the common refrigerant pipe (11) → the 2-4 port 4-way Control valve 30 → condenser 3 → receiver tank 42 → 2-4 port Four-way control valve 30 → second expansion valve 2 with a refrigerant path 24 therein → second cooler The cycle from (20) to the coolant outlet pipe 28 of the second cooler 2 to the first to four port four-way control valve 40 to the accumulator 34 to the compressor 4 is performed.

At this time, since the defrost of the first cooler 10 is required, when the first solenoid valve 15 is blocked, the refrigerant that maintains a high temperature while passing through the compressor 4 is a common refrigerant pipe path 11 → the first cooler 10. → The first cooler 10 is defrosted by the heat of the coolant while the first check valve 12 is moved through the coolant pipe 13 to the 2-4 port 4-way control valve 30.

If the defrost of the first cooler 10 is completed while the coolant passes through the first cooler 10 as described above, the first solenoid valve 15 is opened so that the high temperature coolant does not pass through the first cooler 10. The first solenoid valve 15 and the third check valve 16 reach the condenser 3 via the first direct connection refrigerant path 17 installed in series and directly through the control valve 30.

In this case, as in the operation of the first cooler 10 described above, the air introduced from the air inlet duct 31 as shown in FIG. The cooler 20 changes to a cooled state and is supplied to a conventional dehumidification chamber separately provided through an air discharge duct 32.

Thus, if the phenomena occur in the second cooler 20 continuously while operating, the first and second four-port four-way control valves 40 and 30 are operated to change the refrigerant line and again the first cooler 10. In this case, the frost formed in the first cooler 10 may be defrosted while the second cooler 20 is operated to prepare for the next operation time.

That is, by continuously operating the first cooler 10 and the second cooler 20 it is possible to continuously cool the dehumidification.

Therefore, the present invention dehumidifier can directly defrost the first and second coolers 10 and 20 by using a high-temperature refrigerant via the compressor 4 to increase the defrosting efficiency. The first and second direct connection refrigerant paths 17 and 27 can be used to directly move refrigerants without passing through the first and second coolers 10 and 20 so that they can be used more efficiently and more economically. Have

Claims (1)

The refrigerant flows from the compressor (4) via the condenser (3), and the first expansion valve (1) and the first cooler (10) and the second expansion valve (2) and the second cooler (20) are connected in parallel, respectively. Has a refrigerant circuit passing through any one side to the compressor (4) again, and if any one of the first and second coolers (10, 20) has a cooling operation, the other side of the refrigerant is the first from the compressor (4) Defrost can be achieved by reaching the condenser (3) via any one of the two coolers (10, 20) and the first and second check valves (12, 22) connected in parallel with the first and second expansion valves, respectively. In the conventional refrigeration cycle, the compressor (4) and the first and second coolers (10, 20) between the conduit (3) and the conduit (3) is connected to the conduit through the four-way 4-way control valve (40) A pipe is connected between the first and second expansion valves 1 and 2 through a 2-4 port 4-way control valve 30, and the 1-4 port 4-way control valve 40 And first and second solenoid valves 15 and 25 and third and fourth check valves 16 and 26 connected in series between the refrigerant inlet pipes of the first and second expansion valves 1 and 2, respectively. Cooling dehumidifier characterized in that the refrigeration cycle by connecting the direct connection refrigerant pipe (17, 18), respectively.