KR20000008566U - Heater Fixture for Evaporator in Refrigerator - Google Patents

Abstract

The present invention relates to a heater fixing device for completely removing the frost attached to the evaporator by strengthening the coupling force of the evaporator and the heater.

The present invention attaches a heater fixing support 100 to the lower end of the evaporator 20 in order to strengthen the coupling force of the evaporator 20 and the heater 26 'and fix the heater 26' to the support 100. Letting is the point. The heater fixing support 100 has a plurality of refrigerant pipe fixing grooves 120 for inserting the refrigerant pipe 22 'of the evaporator on one side and a plurality of heaters 26' for inserting the heater 26 'on the other side. The heater fixing groove 160 and the heater fixing groove 160 for fixing the inserted heater 26 'is characterized in that it comprises a fixing protrusion 140 of the upper and lower sides.

Description

Heater Fixture for Evaporator in Refrigerator

The present invention relates to a heater fixing device installed in the evaporator of the refrigerator, and more particularly to a heater fixing device for efficiently removing the frost of the evaporator by strengthening the coupling force of the evaporator and the heater.

First, the cold air supply principle of the refrigerator will be briefly described with reference to the drawings.

1 and 2, the gaseous refrigerant compressed in the compressor 10 of the machine room located at the bottom of the refrigerator is introduced into the condenser 11 connected to the compressor 10 to be liquefied. In addition, the refrigerant is lowered in pressure through the capillary tube 12 connected to the condenser 11 to reach the refrigerant tube 22 (see FIG. 3) of the evaporator 20 in the freezer at a low temperature and low pressure.

The low temperature liquid refrigerant exchanges heat with air around the evaporator 20 while passing through the refrigerant pipe 22 inside the evaporator 20. The air cooled by heat exchange with the refrigerant is supplied into the freezing compartment and the refrigerating compartment by the fan 13 attached to the evaporator 20. At this time, the fan 13 is driven by the motor 14. As described above, the evaporator 20 plays a key role in forming cold air to be supplied to the freezer compartment and the refrigerating compartment.

The structure of the evaporator 20 which serves this function is shown in FIG. 3. That is, the evaporator 20 installed in the rear surface heat exchange chamber 15 of the freezer compartment is on the refrigerant pipe 22 through which the refrigerant passes, and on the refrigerant pipe 22 to increase the heat exchange efficiency of the refrigerant pipe 22. A fitting pin 24.

And a heater 26 is installed around the evaporator 20 for the purpose of removing frost attached to the evaporator 20. The evaporator 20 and heater 26 are also supported by an evaporator holder 28.

The heater 26 is installed in the evaporator 20 as described above, and looks at the reason for installing the heater 26 in the evaporator 20 performing the cooling function in detail.

As described in the cold air supply principle, the cold air generated in the heat exchange chamber 15 in which the evaporator 20 is installed is supplied to the freezing compartment and the refrigerating compartment to circulate. The cold air introduced into the refrigerating chamber cools the food inside through heat exchange as it circulates inside, and is converted into relatively high temperature, high humidity air. The air rises through the convection to the upper part of the refrigerating compartment and returns to the evaporator 20 through a return duct (not shown) inside the barrier located between the freezer compartment and the refrigerating compartment. The air circulated in the refrigerating compartment contains a lot of moisture by heat exchange with food of high temperature and high humidity.

However, since the temperature of the evaporator 20 through which the refrigerant pipe 22 passes during operation of the refrigerator is about -30 ° C and the temperature of the cold air circulated in the freezer is about -18 ° C, the moisture contained in the circulated cold air It is attached to a relatively low temperature evaporator 20. Since the surface temperature of the evaporator 20 is below zero, moisture attached to the evaporator 20 freezes and grows into frost. This prevents the evaporator 20 from exchanging heat with the surrounding air.

Therefore, in order to smoothly perform the function of the evaporator 20, the frost attached to the evaporator 20 should be removed at regular time intervals. In order to remove the frost attached to the evaporator 20, the heater 26 is installed in the evaporator 20. There are various structures in which the heater 26 is attached to the evaporator 20.

In one embodiment, the heater 26 is fitted between the fins 24. Referring to Figure 3 looks at in detail the manufacturing procedure of the evaporator 20 by this structure. First, the fins 24 are inserted at predetermined intervals on the coolant tube 22, and the coolant tube 22 having the pins 24 inserted therein is bent in a U shape at a predetermined length to form several layers. In addition, the heater 26 is bent at a predetermined length in the same manner as the refrigerant pipe 22 and installed between the pins 24 and 24. The heaters are installed at both the front and rear sides of the evaporator 20. Next, the right and left ends of the refrigerant pipe 22 and the heater 26 are inserted into the refrigerant pipe insertion hole (not shown) and the heater insertion hole (not shown) of the evaporator holder 28 to cool the refrigerant pipe 22 and the heater 26. ).

By the way, when both ends of the refrigerant pipe 22 and the heater 26 in the refrigerant pipe insertion hole (not shown) and the heater insertion hole (not shown) of the evaporator holder 28, as shown in FIG. Since a large force is given in the F direction, the refrigerant pipe 22 and the heater 26 in the middle portion are bent.

In addition, the evaporator 20 having the coolant tube 22 through which the coolant passes has a wide range of temperature change because it exchanges heat with the surrounding air, and accordingly, the coolant tube constituting the evaporator 20 ( 22 and the heater 26 repeat the contraction and expansion. However, the left and right ends of the refrigerant pipe 22 and the heater 26 are fixed by the evaporator holder 28 so that the refrigerant pipe 22 and the heater 26 cannot absorb the expansion and contraction of the refrigerant pipe 22 and the heater 26. Therefore, the refrigerant pipe 22 and the heater 26 of the evaporator are warped and deformed.

By the way, since the coolant pipe 22 is inserted into the hole of the pin 24, the degree of deformation is insignificant.

With this variant of the heater 26, the heater 26 exits from the fin 24 in the middle part of the evaporator 20, which is not directly fixed by the evaporator holder 28, in particular the fin 24 is not tightly installed. Departure of the heater 26 is severe in the part (lower side).

FIG. 4 is a cross-sectional view of AA of FIG. 3, when the heater 26 sandwiched between the fins 24 and 24 as shown in FIG. ) Can not melt the frost formed in the center. Therefore, since the state in which the frost is attached to the evaporator 20 continues to prevent the refrigerant from exchanging heat with the surrounding air, there is a problem that the supply of cold air into the refrigerator is disrupted.

However, as the size of the refrigerator increases, the evaporator also grows, and the problems caused by deformation and departure of the heater become more serious.

The present invention is devised to solve the above problems, the object of the present invention is to strengthen the coupling force of the heater and the evaporator installed in the evaporator for refrigerator, fixing the heater for the evaporator that can efficiently remove the frost attached to the evaporator To provide a device.

1 is a cold air supply principle of the refrigerator.

2 is a cold air circulation principle of the freezing chamber.

3 is an installation diagram of a conventional evaporator.

4 is a cross-sectional view taken along the line A-A of FIG.

Figure 5 is a side view of the heater support according to the present invention.

Figure 6 is a side view of the installation state of the heater support according to the present invention.

Figure 7 is a side view of another embodiment of the heater support according to the present invention.

Explanation of symbols on the main parts of the drawings

10 compressor 11 condenser

12 capillary 13 fan

14 fan motor 15 heat exchange chamber

20: evaporator 22,22 ': refrigerant pipe

24,24 ': Pin 26,26': Heater

28: evaporator holder 100, 100 ': heater support

120,120 ', 160,160': Fixed groove 121: Entrance

122,122 ', 180,180': Flange

140, 140 ': Fixed protrusion 150,150': Groove forming groove

In order to achieve the above object, the heater fixing support according to the present invention is provided with a refrigerant pipe fixing groove for inserting and fixing the refrigerant pipe of the evaporator on one side, the heater fixing that can insert and fix the heater on the other side And a fixing protrusion for fixing the heater inserted into the upper and lower side surfaces of the groove and the heater fixing groove.

When the heater fixing support having the structure is inserted into the lower end of the evaporator which is frequently removed from the heater and then inserts the heater into the heater fixing groove to fix the heater, the coupling force of the evaporator and the heater is strengthened than the conventional method, so that the deformation of the heater, By preventing the separation, even the frost inside the evaporator can be efficiently removed.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 5 to 7.

As shown in FIG. 5, the heater supporter 100 according to the present invention includes a refrigerant pipe fixing groove 120 and a heater fixing groove 160.

The refrigerant pipe fixing groove 120 serves to fix the inserted refrigerant pipe 22, and the width of the inlet 121 in a U shape is slightly wider than the inside so that the refrigerant pipe in the refrigerant pipe fixing groove 120 is fixed. It is molded so that the 22 'can be easily inserted.

In addition, the heater fixing groove 160 is located on the other side corresponding between the refrigerant pipe fixing groove 120, and is also formed in a U-shape to serve to fix the inserted heater 26 '.

And by forming a protrusion forming groove 150 in the heater fixing groove 160 upper and lower sides of the heater supporter 100 can make a pair of heater fixing protrusion 140, the fixing protrusion 140 is fixed to the heater After the heater is inserted into the groove 160, the entrance of the heater fixing groove 160 is blocked to prevent the heater 26 ′ from being separated from the groove 160.

The refrigerant pipe fixing groove 120 and the heater fixing groove 160 of the heater support 100 have a refrigerant pipe fixing groove flange 122 and a heater fixing groove flange of a predetermined height in the vertical direction of the heater support 100 ( 180 may be formed. The flanges 122 and 180 extend the contact area between the support 100, the refrigerant pipe 22 ', and the heater 26', so that the refrigerant pipe 22 'is supported on the support 100. ) And the heater 26 'more strongly.

The refrigerant pipe fixing groove 120 and the heater fixing groove 160 may be molded in an appropriate number according to the size of the evaporator 20.

Figure 6 is a side view of the installation state of the heater support according to the present invention. Referring to this, through the process of fixing the heater 26 'to the evaporator 20 by using the heater support 100, the operation of the heater fixing support 100 according to the present invention will be described in detail. .

First, as in the conventional evaporator installation method, the pins 24 'are inserted into the refrigerant pipe 22' at regular intervals, and then the left and right ends of the refrigerant pipe 22 'are bent in a U-shape at a predetermined length.

Then, the refrigerant pipe 22 ′ of the lower center portion of the evaporator 20 where the heater 26 ′ is frequently removed is inserted into the refrigerant pipe fixing groove 120 of the supporter 100. Supporting device 100 according to the present invention can be fitted by an appropriate number depending on the horizontal length of the evaporator (20).

Then, the heater 26 'is bent from the top in the same manner as the refrigerant pipe 22' and sandwiched between the fins 24 'and descends to the place where the heater support 100 is installed. Where the heater support 100 according to the present invention is fitted, the heater 26 ′ is inserted into the heater fixing groove 160 of the support 100.

And, as shown in Figure 6, the heater fixing protrusion 140 in the upper and lower side of the heater fixing groove 160 is bent toward the inserted heater 26 '. At this time, the material of the heater support 100 is to be bent at an appropriate thickness.

After fixing the heater 26 'to the heater support 100 according to the present invention, the refrigerant pipe 22' and the left and right ends of the heater 26 'are connected to the refrigerant pipe of the conventional evaporator holder 28. Installation of the evaporator 20 is completed by fixing the insertion hole (not shown) and the heater insertion hole (not shown).

When the heater 26 'is fixed between the fins 24' according to the conventional method, the heater support 100 according to the present invention is placed on the lower end of the evaporator 20 which is severely deformed and detached from the heater 26 '. Insert the heater 26 'into the heater fixing groove 160 of the supporter 100, and then bend the heater fixing protrusion 140 toward the heater 26' so that the heater 26 'is firmly fixed. do.

Accordingly, when both ends of the heater 26 'are inserted into the heater insertion hole of the evaporator holder 28 by the conventional method, deformation of the heater 26' in the middle portion of the evaporator 20 due to the fastening force can be prevented, and the temperature It is also possible to prevent deformation and separation of the heater 26 'due to shrinkage and expansion due to the change.

Another embodiment of the present invention will be described below with reference to FIG. 7. 7 is similar to the embodiment shown in FIG. 5, but the inlet of the heater fixing groove 160 ′ of the heater fixing support 100 ′ is smaller than the diameter of the heater 26 ′. It is done.

In this case, since the upper and lower side fixing protrusions 140 'of the heater fixing grooves 160' have some elasticity, the heaters 26 'are slightly removed by the heater fixing grooves 160' between the fixing protrusions 140 '. It can be inserted by force. However, once the heater 26 'is inserted, the inlet of the heater fixing groove 160' is smaller than the diameter of the heater 26 ', so it is fixed and does not easily escape outward. Therefore, since the heater 26 'is not separated from the evaporator 20, the frost formed in the fin 24 can be efficiently removed.

In addition, the refrigerant pipe fixing groove 120 'and the heater fixing groove 160' of the present embodiment may also be formed by forming the refrigerant pipe fixing groove flange 122 'and the heater fixing groove flange 160', thereby supporting the support 100 '. The fastening force of the refrigerant pipe and the heater can be strengthened.

As described above, in order to prevent deformation and detachment of the heater by strengthening the coupling force between the evaporator and the heater, the main idea is to attach a heater fixing support to the lower end of the evaporator and to fix the heater to the support. have.

Although the present invention has been described through the illustrated embodiment, the shape of the refrigerant pipe fixing groove 120 and the heater fixing groove 160 of the heater fixing support 100 may be variously modified.

Therefore, the specific embodiments described above are intended to clarify the technical contents of the present invention, and should not be construed narrowly to the present invention limited to the specific embodiments, and various changes within the scope described in the spirit and utility model registration claims of the present invention. Examples are possible.

According to the present invention made as described above, by the heater support which formed the refrigerant pipe fixing groove on one side, the heater fixing groove and the fixing projection on the other side, it is possible to strongly fix the heater to the evaporator, deformation and separation of the heater There is an effect that can prevent. Therefore, the efficiency of elimination of evaporator defrosting by the heater can be increased, thereby facilitating the cold air supply function of the evaporator.

Claims (5)

A refrigerant pipe fixing groove capable of inserting a refrigerant pipe of the evaporator on one side; It is provided with a heater fixing groove for inserting the heater on the other side; A heater support characterized in that the heater is fixed to the evaporator. The heater support according to claim 1, wherein the refrigerant pipe fixing groove or the heater fixing groove is formed in a U shape. The heater support according to claim 1 or 2, wherein fixing heaters which are bent toward the heater fixing grooves are provided on upper and lower sides of the heater fixing grooves. The heater support according to claim 1 or 2, wherein an inlet of the heater fixing groove is molded smaller than a diameter of the heater. The heater support according to claim 1 or 2, wherein a flange having a predetermined height in the vertical direction of the heater support is provided in the refrigerant pipe fixing groove or the heater fixing groove.