KR100213924B1 - Heater pipe - Google Patents

Abstract

The present invention relates to a defrosting heater pipe, and to prevent defrost water from freezing on the surface of the heater pipe and the defrosting water receiving abnormality so that the heat dissipated from the defrosting heater pipe can be transferred to the defrosting water receiving in a short time. It is an object of the present invention to provide a defrost heater pipe that can prevent defects and improve the cooling performance of the evaporator and the reliability of the product.

In the present invention for achieving the above object is located in the lower part of the evaporator, the drain hole is drilled to one side installed in the defrost heater pipe for collecting and discharging the defrost water falling from the evaporator, the drain A portion of the heater pipe positioned at an artificial upward bend to prevent the heater pipe from contacting the defrosting water receiver.

In the present invention configured as described above, when the defrost water moves along the contact surface of the defrost water receiver and the heater pipe and is located in the bending part, the defrost water is dropped toward the drain hole by gravity, and the defrost water does not accumulate around the heater pipe. No more defrost than defrost.

Description

Defrost Heater Pipe

The present invention relates to a defrosting heater pipe, and more particularly to a fixing structure of the defrosting heater pipe so that the heater pipe does not flow over the defrost water receiving when the heater pipe is installed.

Generally, as shown in FIG. 1, the refrigerator cools by the heat of evaporation which is taken from the surroundings when the liquid refrigerant in the evaporator 100 evaporates. In this case, the surface of the evaporator 100 is included in the surrounding hot air. The frost is frozen and the frost is generated. In such a castle, the efficiency of the evaporator is greatly reduced, thereby lowering the cooling power and increasing the operation rate of the compressor. Therefore, it is necessary to appropriately remove frost frozen on the surface of the evaporator 100.

Accordingly, the refrigerator is provided with a so-called defrosting device for removing frost frozen in the evaporator 100.

Meanwhile, as shown in FIGS. 1 and 2, when the frost frozen in the surface of the evaporator 100 is melted by the defrosting device, the defrost water falls to the lower part of the evaporator 100. When the freezing again, the normal cooling action may not be achieved, so the drain hole 1a is drilled in the lower portion of the evaporator 100 so that the defrosting water receiver 1 for collecting and discharging the defrosting water is installed. Here, the defrosting water receiver 1 is inclined downward toward both sides of the drain hole 1a so as to smoothly drain the defrosting water.

The heater pipe 2, which is one type of the defrosting device, is bent to be positioned in front of and behind the defrosting water receiver 1, which is composed of one pipe, and a heating wire (not shown) is provided therein.

Since the heater pipe 2 is to remove the defrost of the evaporator 100 by the radiant heat of the defrost receiver 1, the heater pipe 2 has the same inclination as the defrost receiver 1 in order to increase the thermal conductivity. It is fixed while being in contact with the upper surface of the constant receiving (1).

The conventional heater pipe 2 detects the surface temperature of the evaporator 100, and when the detected temperature is higher than the set value, when the power is supplied to the heater pipe 2 by the control means, the heating wire embedded in the heater pipe 2 is provided. In the heat dissipation, the heat is transmitted to the defrost water receiver (1), the radiant heat is dissipated to the evaporator 100 side to remove the frost frozen in the evaporator (100).

The defrosted water melted by heat falls to the bottom of the evaporator 100 and is collected in the defrost water receiver 1, and the collected defrost water flows along the defrost water receiver 1 toward the drain hole 1a and at the same time, the defrost water receiver. 1 is discharged through the drain hole 1a while flowing along the surface of the heater pipe 2 in a state of being in contact with the contact surface of the heater pipe 2.

When the frost frozen in the evaporator 100 is removed in this manner and the surface temperature of the evaporator 100 is lower than the set value, the power supplied to the heater pipe 2 is cut off by the control means.

Such defrosting and cooling operations are continuously circulated according to the temperature of the evaporator 100.

However, in the conventional heater pipe, as described above, when the heater pipe 2 is stopped and the evaporator is operated, water droplets formed on the contact surface of the defrost water receiver 1 and the heater pipe 2 are frozen again. In particular, the defrost water concentrated on the heater pipe 2 located in the perforated portion of the drain hole 1a in accordance with the inclination of the heater pipe 2. Accordingly, when the heater pipe 2 is operated while the defrost water is frozen around the heater pipe 2, it takes a long time for the heat dissipated from the heater pipe 2 to be transferred to the defrost water receiver 1. As a result, there was a problem that takes a long time for the defrost of the evaporator (100).

In addition, a phenomenon in which the drain hole 1a is clogged due to defrost water frozen on the surface of the heater pipe 2, in which case the heater pipe 2 is operated to discharge defrost water falling from the evaporator 100. In this case, since the drain hole 1a is blocked, the defrost water cannot be discharged immediately, but after a predetermined time elapses, that is, only after the defrost water frozen in the drain hole 1a is melted.

The present invention has been made to solve the above problems, the defrost water is not frozen on the surface of the heater pipe and more than the defrost water receiving, so that the heat dissipated from the defrost heater pipe can be transferred to the defrost water receiving in a short time. The purpose of the present invention is to prevent defrosting and improve the cooling performance of the evaporator and the reliability of the product.

In addition, the defrosting water on the surface of the heater pipe located in the drain hole is formed by allowing the dewatering water flowing along the surface of the heater pipe to fall toward the drain hole by preventing the heater pipe from contacting the drain hole of the defrost receiver. It is an object of the present invention to provide a defrost heater pipe that can prevent the freezing phenomenon.

1 is a front view showing an installation state of a general heater pipe.

Figure 2 is a plan view of a defrost receiver showing an installation state of a conventional heater pipe.

Figure 3 is a front view showing a state in which the embodiment according to the present invention is installed.

4 is a perspective view of an embodiment according to the present invention.

<Description of Codes for Main Parts of Drawings>

10: heater pipe 11: bending part

20: defrost water receiving 21: drain hole

100: evaporator

In the present invention for achieving the above object is located in the lower part of the evaporator, the drain hole is drilled in one side installed in the defrost heater pipe for collecting and discharging the defrost water falling from the evaporator,

A portion located in the drain hole is bent upward to prevent the heater pipe from contacting the defrosting water receiver.

In the present invention configured as described above, when the defrost water moves along the contact surface of the defrost water receiver and the heater pipe and is located in the bending part, the defrost water is dropped toward the drain hole by gravity, and the defrost water does not accumulate around the heater pipe. No more defrost than defrost.

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

As shown in FIG. 3 and FIG. 4, the heater pipe 10 of the present invention has a drain hole 21 drilled at one side thereof and is disposed on an upper surface of the defrosting water receiver 20 which is inclined downward with respect to the drain hole 21. It is formed in the same inclination as the defrosting water receiver 20 so that the drain hole 21 bends a part which is in contact with a portion of the perforated defrosting water receiver 20 upwards, the bending portion 11 and the defrosting water The upper surface of the receiving 20 is not in contact.

The heater pipe 10 according to the present invention is installed in the defrost water receiver 20 having a predetermined width, so that one pipe is horizontally bent so as to be positioned in front and rear of the defrost water receiver 20.

A heating wire (not shown) is installed inside the heater pipe 10 to remove frost frozen in the evaporator 100 by using heat emitted from the heating wire, and the heater pipe 10 receives the defrost water receiver 20. ) Is bolted through a plurality of fixing brackets (not shown).

Referring to the operation according to the embodiment of the present invention configured as described above are as follows.

As shown in FIG. 3, when power is supplied to the heater pipe 10 by the control means when frost is frozen on the surface of the evaporator 100 and the temperature of the surface of the evaporator 100 is greater than or equal to a predetermined value, it is embedded in the heater pipe 10. Heat is dissipated from the heated wire and transferred to the defrosting water receiver 20, and the frost frozen in the evaporator 100 is melted by the radiant heat, and the defrosting water falls into the defrost water receiving 20.

The defrost water dropped on the defrost receiver 20 flows down along the surface of the defrost receiver 20 and flows down to the contact surface between the defrost receiver 20 and the heater pipe 10. When the defrost water flows down along the heater pipe 10 and is located in the bending part 11, the defrost water is discharged while falling toward the drain hole 21 by gravity.

In this state, when power is supplied to the heater pipe 10 for defrosting as described above, heat is radiated from the heating wire and transferred to the defrosting water receiver 20 to melt frost frozen in the evaporator 100 by the radiant heat. This will be.

Therefore, according to the present invention, since the defrost water flowing down the surface of the heater pipe in the defrost water falling after melting in the evaporator due to the defrost of the heater pipe is discharged without accumulated around the heater pipe, the surface of the heater pipe and the The defrost water does not freeze in the water receiver.

In addition, since the defrosting water is not accumulated above the defrosting water receiver, the phenomenon in which the drain hole is clogged due to freezing of the defrosting water remaining in the defrosting water receiver as in the prior art does not occur.

As described above, since the defrosting water does not freeze on the surface of the heater pipe according to the present invention, the heat generated from the heater pipe during the defrosting of the evaporator is transferred to the defrosting water receiver in a short time so that the defrosting action by the radiant heat is normally performed. It offers the advantage of improving cooling performance and product reliability.

Claims (1)

In the defrost heater pipe which is located in the lower part of the evaporator is installed in the defrost water receiver for collecting or discharging the defrost water falling from the evaporator by drilling a drain hole to one side, The defrost heater pipe, characterized in that the portion is located in the drain hole upward bending so as not to contact the defrost water receiver.

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