KR0183480B1 - Freezer - Google Patents

Abstract

An object of the present invention is to provide a refrigerating device for reducing pulsation of a refrigerant in a disper heater circuit, and the refrigerating device includes a compressor (11) having a discharge side (9) and a suction side (10) of the refrigerant, A condenser 12 connected to the discharge side 9 of the compressor 11 and a cooler connected to the suction side 10 of the compressor 11 while being connected to the discharge side of the condenser 12 via a capillary tube 13. 14, the disper pipe outlet 16 and return unit 17 formed in the compressor 11, and the disper pipe outlet 16 and the return unit 17 are connected to the condenser 12. The disper heater which is provided in the inserted disper pipe 18 and the muffler 20 which is provided in the disper pipe outlet 16 side of the said compressor 11, and is installed in the longitudinal direction in the vicinity of the outlet of the said disper pipe 18. The circuit 15 is provided.

Description

Freezer

1 is a front view of a commercial refrigerator having a refrigerating device R of the present invention.

2 is a refrigerant circuit diagram of the refrigerator R of the present invention.

3 is a perspective view of the muffler provided in the refrigerating device R.

* Explanation of symbols for main parts of the drawings

9: discharge side 10: suction side

11: compressor 12: condenser

13 capillary 14 cooler

15: disper heater circuit 16: disper pipe outlet

17: disper pipe return unit 18: disper pipe

20: muffler R: freezer

The present invention relates to a refrigerating device comprising a disper heater circuit for cooling a high-temperature, high-pressure gas refrigerant discharged from a compressor, and then cooling the compressor by returning it to the compressor once.

Conventionally, a refrigerant having a low specific heat ratio such as R-12 is used as a refrigerant circuit constituting a refrigeration apparatus of a low temperature showcase installed as a food refrigeration and refrigeration facility such as a supermarket. In the refrigerating device using such a refrigerant, the temperature of the compressor is not a problem because the discharge temperature of the refrigerant is relatively low, but it is not possible to use a specific refrigerant (such as R-12) in connection with the problem of destruction of the ozone layer surrounding the global environment. It became.

Therefore, in recent years, a refrigerant having a low risk of destroying an ozone layer such as R-22 is used as an alternative refrigerant. However, R-22 has a higher specific heat ratio than R-12, and the discharge temperature of the refrigerant rises, so that the temperature of the compressor is very high and the winding of the drive motor is damaged.

In order to solve this problem, the liquid injection method and the disper heater method are conventionally considered as a means of lowering the temperature of a compressor. The liquid spray method condenses and liquefies the refrigerant discharged from the compressor and returns a portion of the condensed refrigerant through a capillary tube to the low temperature side of the compressor to evaporate it inside the compressor to cool the compressor. 40 ° C. or the like) is preferable, but it is difficult to select a capillary tube and to complicate the structure of the compressor.

On the other hand, in the disper heater method, the high temperature and high pressure gas refrigerant discharged from the compressor is externally cooled by the disper heater circuit, and once the temperature is lowered, the refrigerant is returned to the rotating shaft portion of the compressor, and the compressor is passed through the inside of the compressor. After cooling, the pump is discharged from the discharge side of the compressor and supplied to the cooler at the next stage. In this way, the structure of the compressor is simplified, and the design of the refrigerant circuit is easy. For example, it is widely used in refrigeration equipment.

However, in the case of the disper heater method, problems such as noise increase due to pulsation of the refrigerant discharged from the compressor in the disper heater circuit, or cracks in the connection part of the pipe, cause gas leakage.

An object of the present invention is to solve the above-mentioned conventional technical problem and to provide a refrigerating device that reduces pulsation of a refrigerant in a disper heater circuit.

A refrigeration apparatus of the present invention includes a compressor having a discharge side and a suction side of a refrigerant, a condenser connected to the discharge side of the compressor, a cooler connected to the suction shaft of the compressor and connected to the discharge side of the compressor via a capillary tube, A disper pipe outlet and a return portion formed in the disper pipe outlet connected to the condenser and inserted between the disper pipe outlet and the return portion, and installed at a disper pipe outlet side of the compressor, near the outlet of the disper pipe. It consists of the disper heater circuit which consists of a muffler provided in the longitudinal direction.

The gas refrigerant having a high temperature and high pressure discharged from the outlet of the disper pipe of the compressor passes through a muffler installed near the outlet, and the sound is muted and then flows into the disper pipe of the disper heater circuit. Since the disper pipe is cooled by the condenser, the temperature of the gas refrigerant decreases in the course of passing through the disper pipe, but most of them return to the compressor as it is in the gas state. The gas refrigerant having such a lowered temperature cools the compressor in the process of passing through the inside of the compressor, is discharged from the discharge side, and is supplied to the condenser.

Next, an embodiment of the present invention will be described based on the drawings. 1 is a front view of a commercial refrigerator provided with the refrigerating device R of the present invention, FIG. 2 is a refrigerant circuit diagram of the refrigerating device R of the present invention, and FIG. 3 is a perspective view of a muffler provided in the refrigerating device R. As shown in FIG.

In FIG. 1, 1 is a main body of a business refrigerator, referred to as an undercounter refrigerator, and a pair of opening and closing doors 2 are installed on the front and a cooling chamber having a cooler 14 inside as a storage compartment is installed. have.

Moreover, the machine room 5 which has the machine room door 4 which can be opened and closed on the front side is provided in the side part. 6 is a drainage device for draining condensation water or defrost water of the cooler 14 in the storage chamber, 7 a leg portion for supporting the main body, and 8 a control panel for controlling the refrigerating device R.

The refrigerating device R of the present invention has a compressor 11 having a cold air discharge side 9 and a suction side 10 as shown in FIG. 2, and a condenser 12 connected to the discharge side 9 of the compressor 11. And a cooler 14 connected to the discharge side of the condenser 12 via a capillary tube 13 and connected to the suction side 10 of the compressor 11, and as a disper heater circuit 15. The disper pipe outlet 16 and return part 17 formed in the compressor 11, the disper pipe 18 connected between these outlet 16 and return part 17 and inserted into the condenser 12, the compressor The circuit which consists of the muffler 19 provided in the longitudinal direction near the disper pipe outlet 16 of (11), ie, almost vertically, is also provided.

Here, the muffler 19 will be described with reference to FIG. The muffler 19 has a negative reflection caused by the cross-sectional area change and the sound is attenuated when the refrigerant flows from the muffler main body 20 to the muffler main body 20 and from the muffler main body 20 to the muffler main body 20B. It is supposed to be. This negative attenuation amount is S2 / S1 = m, 2π / λ = k (λ: negative wavelength),

Is displayed.

The maximum amount of attenuation is that L is an odd multiple of 1/4 (λ), that is, {L = 1/4 (λ), 3/4 (λ), 5/4 (λ),... }, And the larger the S2 / S1, the larger the amount of attenuation.

The position of the muffler 19 is such that the shorter the distance l from the disper pipe outlet 16 of the compressor 11 shown in FIG. 2 to the center position of the muffler main body 20 is attached, the shorter the disper pipe 18. The stress over the connecting portion of the and muffler 19 can be reduced.

In addition, by attaching the muffler 19 in the longitudinal direction, it is possible to prevent the oil from remaining in the muffler 19 together with the refrigerant.

The operation of the refrigerating device R having the above-described configuration will be described. In the refrigerating device R, a predetermined amount of R-22 refrigerant is sealed as the refrigerant.

When the compressor 11 is operated, the refrigerant of a high temperature and high pressure gas state of about 85 ° C is first discharged from the disper pipe outlet 16 via the disper pipe 18A, the muffler 20, and the disper pipe 18B. The refrigerant flows into the disper pipe 18 and is cooled by a blower (not shown) together with the condenser 12 to condense the refrigerant. Since cooling in this case is air-cooled by a part of the condenser 12, the refrigerant is not yet condensed and the temperature is lowered from 85 ° C. to about 55 ° C. as described above in almost all or all of the gas state. In this way, the low temperature gas refrigerant is returned to the disper pipe return unit 17 of the compressor 11.

Here, the condenser 12 accumulates dust on the front surface of the condenser 12 due to the outside air being sucked in and flowed from the front by the blower. This dust builds up slowly from the front lower part of the condenser 12 so that the air flow in the condenser 12 is worsened from the lower part and the disper pipe 18 is disposed above the rear of the condenser 12 so that at least the disper pipe ( The cooling action of 18) is secured preferentially to the end.

The refrigerant returned from the disper pipe return unit 17 into the compressor 11 flows into the rotating shaft portion inside the compressor 11. Here, the compressor 11 compresses the refrigerant sucked from the suction side 10 in a compression unit (not shown) and discharges it at a high pressure from the disper pipe 16, and the disper pipe outlet 16 inside the compressor 11. The compression and suction side 10 portions and the other portions are isolated.

Therefore, the low temperature gas refrigerant returned to the rotating shaft portion from the disper pipe return portion 17 is discharged from the discharge side 9 through the rotating shaft by the pressure difference.

In this passage, the compressor 11 is cooled by the sensible heat of the low temperature gas refrigerant, so the temperature of the compressor 11 is about 90 ° C.

In this case, when the disper heater circuit 15 is absent, the temperature of the compressor 11 is increased to 120 ° C. or higher, but it is possible to lower the temperature to about 30 ° C. by cooling with the return refrigerant to the low temperature as described above. As a result, damage to the winding portion can be prevented.

In addition, since most of the refrigerant passing through the rotating shaft portion is a gas refrigerant, there is no inconvenience of washing away the lubricating oil.

The refrigerant discharged from the discharge side 9 of the compressor 11 rises to about 70 ° C. to cool the compressor 11 and flows into the condenser 12 from the high pressure pipe.

Since the condenser 12 is cooled by a blower not shown as described above, the refrigerant introduced therein rapidly decreases in temperature and condenses, and the temperature decreases to about 45 to 50 ° C. to condensate.

The refrigerant condensed in the condenser 12 as described above exits from the condenser 12, passes through a capillary tube 13, enters the cooler 14, and evaporates therein.

At this time, the temperature of the cooler 14 is about -10 ° C. The refrigerant exiting the cooler 14 is again sucked into the compressor 11 from the suction side 10 and compressed to be discharged again from the disper pipe outlet 16.

According to the present invention as described above, the pulsation of the refrigerant in the disper heater circuit is suppressed by providing a muffler in the longitudinal direction at the outlet of the disper pipe of the compressor, and in particular, since the oil circulated with the refrigerant is installed in the longitudinal direction, Staying in this muffler can be prevented.

In addition, since the muffler is provided near the outlet of the disper pipe, vibration caused by pulsation of the refrigerant is generated, and cracks are generated at the connection portion between the muffler and the disper pipe, thereby preventing gas leakage. Therefore, according to the present invention, even in a refrigerating device using a refrigerant such as R-22, it is possible to have sufficient cooling capacity and to improve the reliability of the refrigerating device itself.

Claims (1)

A compressor having a discharge side and a suction side of the refrigerant, a condenser connected to the discharge side of the compressor, a cooler connected to the suction side of the compressor and connected to a discharge side of the compressor via a capillary tube, and a discharge pipe outlet formed in the compressor. And a return portion, a disper pipe connected between the outlet of the disper pipe and the return portion and inserted into the condenser, a muffler installed at a disper pipe outlet side of the compressor and installed in a longitudinal direction near the outlet of the disper pipe. And a compressor unit comprising a compression unit and a motor unit, wherein the disper pipe outlet is connected to the compression unit of the compressor, and the disper pipe return unit is in communication with the motor unit side of the compressor. Refrigerating apparatus, characterized in that.