KR200146302Y1 - Defrosting structure for drain pipe of showcase - Google Patents

Abstract

The present invention has been made to solve this problem, and more particularly, to the defrost structure of the drain pipe of the showcase to achieve a stable defrost of the drain pipe by using the heat of condensation heat exchanged in the refrigerant cycle, which is a defrost water from the evaporator of the refrigerant circuit In the defrost means of a showcase having a pair of refrigerant circuits for draining to the outside through the drain pipe installed on the drain plate, the condensation pipe of one refrigerant circuit to the other side to be defrosted by using the heat of condensation heat exchanged with the outside of the refrigerant cycle It extends to the drain pipe so that the end surface of the condensation pipe and the drain pipe is in contact with each other to allow heat exchange.

Description

Drain pipe defrost structure of showcase

1 is a cross-sectional view showing the opening degree of the present invention.

2 is a main portion of the present invention.

* Explanation of symbols for main parts of the drawings

10: showcase 30: drain plate

40: drain pipe 100: compressor

200: condenser 210: condensation pipe

220: insulation

The present invention relates to a drain pipe defrost for discharging the defrost water introduced to the drain plate of the showcase to the outside, in particular, the drain pipe defrost of the showcase to transfer the condensation heat generated by heat exchange in the refrigeration cycle to the drain pipe to prevent freezing of the defrost water It's about structure.

In general, the principle of freezing and cooling is obtained by changing the thermal energy of a refrigerant having a low boiling point by a mechanical method. The principle is to increase the pressure and temperature of a refrigerant by applying a constant pressure through a compressor to a gaseous refrigerant at room temperature. After that, the condenser radiates heat of condensation and converts it into a liquefied refrigerant, where the refrigerant undergoes primary thermal energy conversion.

After that, the refrigerant in the liquefied state rapidly decreases as it passes through the expansion valve, and is cooled by evaporating to a gas state of low temperature and low pressure. The cooled refrigerant undergoes heat exchange with external air heat through an evaporator. The temperature rises while inhaling, and the outside air temperature decreases. At this time, the exchanged heat becomes the temperature in the freezer and the cooler.

As described above, two heat exchanges are performed during the cycle of a refrigerant cycle. The main purpose of refrigeration and cooling is to use low-temperature evaporative heat, and the heat of condensation in the refrigerant cycle is irrelevant for the purpose of refrigeration and cooling. The situation is neglected.

Therefore, if the neglected heat energy is recycled, it is possible not only to prevent waste of energy but also to reduce the installation cost and reduce the installation cost even more, especially when used in a drain pipe that requires dissipated heat energy. You will be able to expect it.

Looking at the defrost structure of a general drain pipe from this point of view, the evaporation heater is installed inside the drain pipe to drive it when the refrigerant cycle is stopped, thereby melting the frost frozen in the drain pipe to smoothly drain water.

However, in such a structure, when the evaporation heater is poor, a frost gradually forms in a double layer from the inner circumferential surface of the drain pipe, which leads to a serious situation in which the drainage does not occur and eventually becomes a problem that lowers the cooling power. The problem was inherent in the repair because it was not easy.

The present invention has been made to solve the above problems, and the object of the present invention is to provide a drain pipe defrost structure of the showcase to achieve a stable defrost of the drain pipe by using the heat of condensation heat exchanged in the refrigerant cycle.

Another object of the present invention is to provide a drainage defrost structure of a showcase to reduce the installation and cost presented to provide the heat source necessary for defrosting by recycling unnecessary heat energy.

This purpose is achieved by using the heat of condensation of a pair of refrigerant cycles provided in an open flat showcase, which is a pair of refrigerants which drains depleted water from the evaporator of the refrigerant circuit to the outside through a drain pipe installed on the drain plate. In the defrost means of a showcase having a circuit, the condensation pipe of one refrigerant circuit is extended to the other drain pipe so that the defrost pipe can be defrosted by using condensation heat that exchanges heat with the outside of the refrigerant cycle. It is made to be.

According to this configuration, when the defrost is made after a predetermined time has elapsed in a state where the refrigerant cycle of one side is stopped, the condensation heat of the other refrigerant cycle is able to defrost frozen frost while exchanging heat with one side of the drain pipe.

This can achieve the purpose required in the present invention because a pair of refrigerant circuits are driven while alternating with each other, and this configuration does not need to defrost by providing a separate heat source to the drain pipe to simplify the facility as well as conventionally It is also desirable in terms of energy recycling to recycle the heat of condensation.

Next, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view schematically showing the configuration of the present invention, the reference numeral 10 in the drawings shows a showcase. The showcase 100 has a drain plate for installing a pair of evaporators 400 on the upper side in the storage compartment 20 having an open top surface, and collecting defrost water generated during defrosting of the evaporators on the bottom of the evaporator 400. 30) and the drainage pipe 40 is provided at a suitable place on one side of the drainage plate 30 to drain the defrost water.

In addition, a lower portion of the showcase 100 is provided with a pair of refrigerant circuits for freezing and cooling in the storage compartment 20, and the refrigerant circuit includes a compressor 100, a condenser 200, an expansion valve (not shown), and an evaporator. Arrange the 400 in order via the refrigerant pipe, the outside air temperature is sucked through the evaporator 400 provided in the storage chamber 20 to maintain the desired temperature, and the refrigerant is machined through a medium called a compressor. It is forcedly circulated by the conventional method, and the desired air conditioning is achieved while continuously and repeatedly performing the compression-condensation-expansion-evaporation process.

Here, all of the components are provided in the showcase 10 in pairs left and right.

As described above, each element of the refrigerant circuit is connected through a refrigerant pipe, and in the present invention, the refrigerant pipe between the compressor 100 and the condenser 200, that is, the condensation pipe 210 extends to the other drain pipe 40 to condense the condensation pipe. The pipe 210 and the drain pipe 40 are to be connected in parallel to the condenser 200 after making a parallel junction.

In other words, as shown in FIG. 2, the contact surfaces of the drain pipe 40 and the condensation pipe 210 may be joined by soldering or other joining means, and the outer circumference may be wrapped with a heat insulating material 220 having a high thermal insulation effect to achieve efficient heat exchange. will be.

At this time, the condensation pipe 210 extending to the drain pipe 40 should be connected to the condenser 200 by connecting the structure is preferably a structure that is laminated on the center of the drain pipe (40).

The refrigerant used in the present invention is a freon gas, and its heat of compression rises to 80 ° C.-90 ° C., so that even if the heat loss of the condensation pipe is slightly reduced, the frozen drain pipe 40 can be sufficiently defrosted. Will be.

This structure can achieve the same defrosting effect as the conventional evaporation heater in the inside for the defrost of the drain pipe.

In addition, since the joint surface of the condensation pipe 210 and the drain pipe 40 is made of a circular pipe, the joint surface is pre-bonded, so the heat exchange efficiency may be low. Therefore, the heat exchange efficiency is increased by increasing the area of the joint surface, that is, the heat transfer area. It would be most desirable to increase it.

As described above, the present invention uses a wasteless heat source, ie, condensation heat as a defrosting means of the drain pipe, which eliminates the need for a separate heater for defrosting the drain pipe, thereby reducing the cost and always providing a stable heat source. It is a useful design that has the advantage that the failure rate is extremely low because it is provided, and it is easy to disassemble even in the case of failure.

Claims (1)

In the defrosting means of the showcase having a pair of refrigerant circuit to drain the defrost water from the evaporator of the refrigerant circuit to the outside through the drain pipe installed on the drainage plate, the defrosting heat of one refrigerant circuit is transferred to the other drain pipe The dehydration structure of the showcase drainage pipe of the showcase characterized in that the condensation pipe on one side is extended to the other side of the drain pipe so as to be in contact.