JP3649100B2 - refrigerator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a refrigerator provided with a tubular heater for melting frost attached to the cooler below the cooler.
[0002]
[Prior art]
In the conventional refrigerator, the cooler for cooling the inside of the refrigerator is arrange | positioned in the store | warehouse | chamber. The cooler is a heat exchanger that exchanges heat with the air outside the cooler by the refrigerant flowing inside. In the conventional refrigerator, there is a means for circulating the air inside the refrigerator, and it is supplied around this cooler. Then, the cooled air is supplied again into the cabinet and circulated.
[0003]
On the other hand, water vapor contained in the air in the warehouse adheres to the surface of the cooler as frost by heat exchange with the cooler (hereinafter referred to as frost formation). When the amount of frost formed on the surface of the cooler increases, the area of the cooler surface that comes into contact with air decreases, and the performance of the cooler for heat exchange decreases, so that this is removed. In a conventional refrigerator, frost is melted by heating a cooler to which frost has adhered. In particular, a tubular heater is provided below the cooler, and the frost formed on the cooler is melted (hereinafter referred to as defrosting) by supplying heat from the heater to the upper cooler. Yes. An example of such a prior art is described in JP-A-8-105680.
[0004]
In this prior art, a freezer compartment and a refrigerator compartment are provided in the refrigerator, and air from each compartment is sucked into the cool air passage from the refrigerator compartment and refrigerator compartment and sent to a cooler installed at the back of the freezer compartment. A defrosting tube heater is provided below the cooler, and cylindrical caps formed of insulating members having protrusions for preventing rotation of the heater are provided at both ends of the heater. The anti-rotation protrusions are provided so as to protrude from both sides of the cylindrical cap, and are formed so as to extend in the tube heater axial direction of the cylindrical cap.
[0005]
Moreover, the hook which receives the water defrosted (defrost water) is provided under the tubular heater. Further, a support body for supporting the heater is provided from the side of the tubular heater, and the heater is held by inserting the cylindrical cap into the support body from above. In addition, by storing the rotation-preventing protrusion in the storage portion provided on the support, the protrusion and the storage portion engage with each other to suppress the rotation of the tubular heater. That is, the engagement relationship between the support and the cylindrical cap is performed by the rotation-preventing protrusion of the cylindrical cap being fitted into the opening formed in the support.
[0006]
Further, an upper surface cover (hereinafter referred to as a ceiling cover) is provided above the defrosting tubular heater so as to cover the heater, and this ceiling cover is provided with defrost water dripping from the cooler for defrosting. The contact with the defrosting tubular heater which has become high temperature is suppressed.
[0007]
The tubular heater is provided with a heating element such as a coiled nichrome wire inside, and electricity is supplied through a lead wire for energizing the heating element. The lead-out portion of the lead wire is provided on the lower side of the cylindrical cap in a state of being attached to the support for the defrosting tubular heater. This is because the defrosting water from above does not directly hit this lead-out portion. If a lead-out part is provided at a position where the defrost water directly hits, the defrost water reaches the heating element along the lead wire from the lead-out part and contacts the heating element of the heater and breaks it. There is a risk of causing it to leak or causing electric leakage.
[0008]
[Problems to be solved by the invention]
However, in the refrigerator described in the above-described conventional example, after the defrost water dripping from the cooler hits the upper surface or side surface of the cylindrical cap and reaches the lower surface of the cap, it does not drip while adhering to the lower surface due to surface tension There is a risk of adhering to the lead-out portion of the lead wire along the lower surface.
[0009]
In this case, when the tubular heater is intermittently energized and a large pressure difference is generated between the inside and outside of the tubular heater, the defrost water adhering to the outlet portion is sucked into the tubular heater, and the heater is turned off. In this conventional technique, there is a possibility that damage or electric leakage may occur and the reliability of the refrigerator is lowered.
[0010]
Also, if there is not enough margin in the length of the lead wire, the lead wire will immediately extend upward or horizontally from the lead-out portion with the heater attached to the support portion. Even in the lower side of the cylindrical cap, the problem that the defrosted water adhering to the lead wire is guided to the lead-out portion has not been considered in the above-described prior art.
[0011]
The objective of this invention is providing the refrigerator which improved the reliability of the refrigerator.
[0012]
[Means for Solving the Problems]
The object is to provide a cooler provided in the cabinet, a tube heater disposed below the cooler, an insulating member provided at an end of the tube heater, and the tube heater provided on the insulating member. a deriving unit which leads out from the insulating member to be supplied to said insulating member and not covering the outlet portion upwardly has a sloped surface that is provided integrally from the side of the tube heater body beyond the outlet portion A member that reaches the end of the insulating member on the opposite side, an upper and lower portion that is provided integrally with the insulating member, extends in the vertical direction continuously to the inclined surface, and extends to a position below the lead-out portion; This is achieved by a refrigerator that includes the lead wire that is held in a state of being extended in the vertical direction outside the lead-out portion and extends below the lower end of the vertical portion .
[0013]
Wherein further, it provided a plate portion extending in the vertical direction is provided on the lower side of the member or the insulating member and the inclined surface integral with the front Symbol slope, the inclination of the lower side of the inclined surface from the plate portion This is achieved by providing the derivation unit .
[0014]
According to the said structure, the defrost water dripped from a cooler falls to the cage | basket located under a pipe | tube heater before reaching from the insulation member of a heater end part to the lead-out part of a lead wire. In addition, even if water droplets transmitted from the insulating member to the lead wire, or water droplets that have fallen and adhered directly to the lead wire from the cooler, move along the lead wire, they will not reach the lead wire lead-out portion of the insulating member. Fall into the cage.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
A first embodiment of the present invention will be described below with reference to FIGS.
FIG. 1 is a longitudinal sectional view showing the structure of a first embodiment of the refrigerator of the present invention. FIG. 2 is a perspective view showing the structure of the end of the tube heater of the refrigerator shown in FIG. FIG. 3 is a diagram showing the structure of the end portion of the tube heater shown in FIG. 2 from below. 4 is a side view of the structure of the end of the tube heater shown in FIG.
[0016]
In FIG. 1, 1 is a refrigerator main body, 20 is a refrigerator compartment, 2 is a vegetable compartment, 3 is a freezer compartment, 4 is a cooler. A gutter 7 is provided below the cooler. Reference numeral 5 denotes a defrosting tube heater that is installed in the lower part of the cooler 4 and melts frost adhering to the cooler. 9 is a fan that sends the air cooled by the cooler 4 to the freezer compartment 3, and 10 is a drain that discharges defrost water dripped from the cooler 4 and the like to the outside of the refrigerator during defrosting.
[0017]
The structure of the defrosting tube heater 5 will be described below with reference to FIGS.
2, 3, and 4, a cylindrical rubber cap 6 a according to an insulating member having a rotation-preventing protrusion 6 b is provided below the tube heater 7. As shown in FIG. 1, the rotation-preventing protrusion 6b protrudes vertically below the cylindrical rubber cap 6a and is formed along the heater tube axis direction of the cylindrical rubber cap.
[0018]
Reference numeral 7 a denotes a support body provided on the side of the flange 7 of the tube heater 5, and this support body is provided so as to extend upward from the lower flange 7 side with respect to the tube heater 7. The cylindrical rubber cap 6a is sandwiched by being inserted into the support 7a from above. That is, the support 7a has an opening 7c opened upward so that it can be engaged with the cylindrical rubber cap 6a inserted from above.
[0019]
Further, the support 7a shown in FIG. 1 has a rotation-preventing groove 7b below the support 7a, and when the cylindrical rubber cap 6a is held between the openings 7c, the cylindrical rubber cap 6a. The anti-rotation protrusion 6b is formed to engage with the groove 7b of the support 7a. Thus, in this embodiment, the engaging relationship between the support 7a and the cylindrical rubber cap 6a is that the rotation preventing projection 6b of the cylindrical rubber cap 6a fits into the groove 7b formed in the support 7a. Done.
[0020]
Reference numeral 8 denotes an upper surface cover (hereinafter referred to as a ceiling cover) attached so as to cover the upper portion of the defrosting tube heater 5, and this ceiling cover 8 is piped by defrosted water dripped from the cooler 4 at the time of defrosting. The contact with the heater 5 is prevented. When the defrost water comes into contact with the defrosting tube heater 5 having a high temperature, a large evaporating sound is generated, so that the noise generated from the refrigerator is reduced by the ceiling cover. Further, the defrost water that has contacted the tube heater 5 is instantly evaporated, and the tube heater is prevented from being damaged by an impact at that time. The mounting leg 8a formed on the side surface of the ceiling cover 8 is held in the circular groove 6c on the cylindrical rubber cap side so that the ceiling cover 8 does not rotate.
[0021]
Reference numeral 11 denotes a lead wire that supplies electricity to the heating element of the defrosting tube heater 5 (the electrical heating element such as a coiled nichrome wire is contained in a glass tube). The cylindrical rubber cap 6a is provided with a lead-out portion S of the lead wire 11, and is provided below the cylindrical rubber cap 6a when the defrosting tube heater 5 is attached to the support 7a. The position of the lead-out portion S of the cylindrical rubber cap 6a is clearly shown in FIGS.
[0022]
Reference numeral 6d denotes a cap cover (saddle) that is formed integrally with the cylindrical rubber cap 6a and is provided above the rubber cap 6a and the lead-out portion S so as to cover them. The cap cover 6d is provided obliquely with respect to the upper surface of the cylindrical rubber cap 6a. In particular, in the present embodiment, the upper surface of the tube heater 5 is formed so as to descend from the main body side toward the end of the rubber cap 6a on the opposite side. The water drops that have fallen or adhered to the upper surface of the cap cover 6d move downward along the inclined surface and flow. For this reason, it is suppressed that a water droplet stays on the upper surface of the cap cover 6d, and the water droplet is prevented from moving downward from the end portion of the cap cover 6d and approaching the lead-out portion S of the lead wire 11.
[0023]
The direction of the inclination of the cap cover 6d is not limited to the direction of the present embodiment, and it is possible to prevent water droplets from staying on the upper surface of the cap cover 6d or moving to the lower side of the cap cover 6d. 5 or the inclination should just be formed so that a water droplet can be kept away from the derivation | leading-out part S. FIG. Of course, it is possible to prevent leakage and breakage of the tube heater 5 by preventing the tube heater 5 from flowing in the direction of the tube heater 5.
[0024]
Further, below the cap cover 6d, there is provided a plate-like member 6e provided integrally with the lower surface of the cap cover 6d and the main body of the rubber cap 6a and extending in the vertical direction. The plate-like member 6e is arranged in the middle of the cap cover 6d in the tube axis direction of the tube heater 5, and the lead-out portion S is positioned below the inclination of the cap cover 6d with respect to the plate 6e. . According to this configuration, for example, even if water drops move or adhere to the lower side of the cap cover 6d, the water drops flow along the inclination of the lower surface of the cap cover 6d, or the lead-out portion S along the rubber cap 6a. Even if it flows in the direction, the movement of the water droplets is prevented by the plate 6e, and the water droplets are prevented from approaching in the direction of the outlet portion S.
[0025]
Further, from the end surface of the cap cover 6d, a cap cover upper and lower portion 21 extending in the vertical direction is provided so as to be continuous with the upper surface of the cap cover 6d. The width of the cap cover upper and lower portion 21 is wider than the side surface of the main body of the rubber cap 6a. Furthermore, in the present embodiment, the cap cover upper and lower portions 21 have a shape extending downward from the position of the lead wire lead-out portion S below the rubber cap 6a.
[0026]
A convex portion 22 is provided from the lower end portion of the upper and lower portions 21 to the back surface side (side closer to the derivation portion S). Water droplets flowing on the surface of the upper and lower portions 21 are also on the derivation portion S side. It works to prevent you from approaching. Alternatively, a gap may be provided between the surface of the upper and lower portions 21 on the rubber cap 6 main body side and the rubber cap 6a so that water droplets flowing on this surface can be prevented from moving to the rubber cap 6 main body side.
[0027]
Moreover, you may provide the notch part formed in the recessed part in the lower side edge part of this cap cover up-and-down part 21. As shown in FIG. The notch and the lead wire 11 led out from the lead-out portion S are engaged, and the lead wire 11 is positioned and held with respect to the rubber cap 6a. That is, the upper and lower portions 21 are provided with a portion for positioning and holding the lead wire 11.
[0028]
In such a configuration, the lead wire 11 is led out downward from the lead-out portion S provided above the lower end portion of the cap cover upper and lower portion 21, and extends through the lower end portion. For this reason, the lead wire derived | led-out from the derivation | leading-out part S is once provided with the part extended from the derivation | leading-out part S to an up-down direction. Further, since the lead wire 11 is held and positioned from the end of the upper and lower portions 21 to the lead-out portion S, the portion extending in the vertical direction is displaced due to vibration, impact, etc. The entry into the derivation unit S can be suppressed.
[0029]
Further, according to the present embodiment, the cap cover 6d receives the defrost water dripped from the cooler 4, and the defrost water is directly extended from the flange 7 or the lead-out portion S by the inclination of the cap cover. It will fall towards 11. In this way, water droplets are prevented from moving and approaching the lead-out portion S of the lead wire 11. Further, the water droplets moved to the lower side of the cap cover 6d are also prevented from moving in the direction of the lead-out portion S by the plate 6e extending in the vertical direction. Moreover, when defrost water adheres to the lead wire 11, since the lead wire 11 is always held in the state of extending vertically from the lead-out portion S as described above, the defrost water follows the lead wire. Therefore, it cannot move upward and does not reach the derivation unit S.
[0030]
Thereby, even if a large pressure difference arises inside the defrosting tube heater 5 by intermittently energizing the defrosting tube heater 5, it is possible to suppress inhalation of defrosting water from the lead wire outlet portion S. For this reason, the occurrence of electric leakage or breakage of the tube heater 5 is reduced, and the reliability of the refrigerator is improved. In the present embodiment, the cover 6d and the upper and lower portions 21 are formed of the same member as the rubber cap 6a. With this configuration, the number of parts and the assembly process are reduced and the production cost is reduced as compared with the case of using another member. Can be improved.
[0031]
In the above-described embodiment, the support 7a holding the cylindrical rubber cap 6a is raised from the flange side. However, the cylindrical rubber cap 6a is prevented from rotating and the lead wire lead-out portion S is positioned downward. The support may be provided at a position such as the side of the heel as long as the structure is suitable for the side.
[0032]
In this embodiment, the upper and lower portions 21 are provided so as to extend in the vertical direction continuously to the cap cover 6d. However, the present invention is not limited to such a structure, and the upper and lower portions 21 are vertical. Even if it is not a direction, what is necessary is just to provide the surface provided in the angle which a water droplet flows toward a lower end. Further, the same effect can be obtained even when the surface of the upper and lower portions 21 and the upper surface of the cap cover 6d have the same angle and the same surface.
[0033]
Next, an embodiment in which the shape of the cap cover 6d according to the embodiment of the present invention is modified will be described with reference to FIGS.
FIG. 5 is a perspective view showing a structure of an end portion of a tube heater according to a modified example of the refrigerator shown in FIG. 6 is a view showing the structure of the end portion of the tube heater shown in FIG. 5 from below. FIG. 7 is a side view showing the structure of the end of the tube heater shown in FIG.
[0034]
In this embodiment, the shape of the cap cover 6d is inclined with respect to the upper surface of the cylindrical rubber cap 6a, and the width of the cap cover is narrowed in the middle. In addition, description of members having the same structure as the above-described embodiment is omitted. In this embodiment, at the location where the width of the cap cover is narrowed, the upper and lower portions 23 are provided with a cap cover extending in the vertical direction toward the lower side of the cylindrical rubber cap 6. The cap cover upper and lower portions 23 are arranged so as to surround the lead-out portion S of the lead wire 11 and extend to the lower side of the lead-out portion S. Further, the lead wire 11 is once extended in the vertical direction from the lead-out portion S and extended through the lower side of the vertical portion 23. You may provide the notch which engages with a lead wire also in this edge part.
[0035]
According to such a configuration, water droplets on the upper surface of the cap cover 6d flow along the inclination of the cap cover 6d, and are applied to the lead wire 11 extending from the end of the cap cover upper / lower portion 23 or the ridge 7 or the lead-out portion S. It falls down. In this way, water droplets are prevented from moving and approaching the lead-out portion S of the lead wire 11. Further, the water droplets moved to the lower side of the cap cover 6d are also prevented from moving in the direction of the lead-out portion S by the plate 6e extending in the vertical direction. Similarly to the case described above, even if the defrost water adheres to the lead wire 11, the defrost water cannot move upward along the lead wire and does not reach the lead-out portion S.
[0036]
Thereby, even if a large pressure difference arises inside the defrosting tube heater 5 by intermittently energizing the defrosting tube heater 5, it is possible to suppress inhalation of defrosting water from the lead wire outlet portion S. For this reason, the occurrence of electric leakage or breakage of the tube heater 5 is reduced, and the reliability of the refrigerator is improved.
[0037]
【The invention's effect】
As described above, according to the present invention, a refrigerator with improved refrigerator reliability can be provided.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing the structure of a first embodiment of a refrigerator according to the present invention.
2 is a perspective view showing a structure of an end portion of a tube heater of the refrigerator shown in FIG. 1. FIG.
FIG. 3 is a view showing the structure of the end portion of the tube heater shown in FIG. 2 from below.
4 is a side view of the structure of the end portion of the tube heater shown in FIG. 3; FIG.
FIG. 5 is a perspective view showing a structure of an end portion of a tube heater according to a modification of the refrigerator shown in FIG.
6 is a view showing the structure of the end of the tube heater shown in FIG. 5 from below. FIG.
7 is a side view showing the structure of the end portion of the tube heater shown in FIG. 5. FIG.
[Explanation of symbols]
1 .. Refrigerator body 2 .... Vegetable room 3 .... Freezer room 4 .... Cooler 5 ... Defrost tube heater 6a ... Cylindrical rubber cap 6b ... Anti-rotation protrusion 6c · Ceiling cover holding grooves, 6d · · Hushi, integrally formed on the cylindrical rubber cap, 7 · · 桶, 7a · · Support, 7b · · groove, 8 · · Ceiling cover, 8a · · Ceiling cover mounting legs, 9 .. Cooler fan, 10 .. Drain for drain, 11 .. Lead wire, S .. Outlet section, 12 .. Refrigerator body, 13 .. Freezer room, 14 .. Refrigerator room, 15. Mouth, 15 '·· Freezer compartment passage, 16 ·· Refrigerator compartment suction inlet, 16' ·· Refrigerator compartment passage, 17 ·· Cooler, 18 ·· Defrost tube heater, 19a · Cylindrical rubber cap, 19b · · Anti-rotation protrusion, 20 ·· 桶, 20a ·· Support, 20b ·· Opening opening, 21 ·· Ceiling cover, 1a ... ceiling cover - mounting leg, 22 ... cooler fan, 23 ... water drainage drain, 24 ... lead wire.

Claims (2)

A cooler provided in the chamber, a tube heater disposed below the cooler, an insulating member provided at an end of the tube heater, and a lead provided in the insulating member and energizing the tube heater a deriving unit that line exits from the insulating member, wherein the insulating member and not covering the outlet portion upwardly has a sloped surface that is provided integrally from the side of the tube heater body opposite beyond the outlet portion A member that reaches the end of the insulating member, an upper and lower portion that is provided integrally with the insulating member, extends in the vertical direction continuously to the inclined surface, and extends to a position below the derivation portion; A refrigerator comprising the lead wire that is held in a state of being extended in the vertical direction and extends below the lower end of the upper and lower portions . A plate portion provided on the lower side of the slope integrally with the member having the slope or the insulating member and extending in the vertical direction, and the lead-out portion provided on the side of the slope lower than the plate portion. the refrigerator according to claim 1 comprising.

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