JPH024385Y2 - - Google Patents

Description

[Detailed description of the invention] [Field of industrial application] This invention relates to an electric refrigerator, and more specifically, to an electric refrigerator equipped with a food storage chamber that can be used for multiple purposes, such as a thawing chamber for frozen foods. be.

[Technical background of the invention] Thawing frozen foods using the heat released from the refrigeration cycle is known, for example, as described in Japanese Patent Application Laid-Open No. 57-28965.
This method is already known from Japanese Utility Model Publication No. 59-174585 and the like. That is, in this prior example, a thawing chamber with a relatively small volume is formed on the upper wall side of the refrigerator compartment, and heat generated from, for example, a compressor in the refrigeration cycle is guided into the thawing chamber by a heat pipe to achieve a predetermined thawing. I'm trying to get the temperature. According to this method, since the heat that would otherwise have been wasted is used, there is no need to install an electric heater for defrosting, which is advantageous from the viewpoint of cost and energy saving. I can say that. However, in the case of the preceding example, a part of the refrigerator compartment is separated to form a thawing chamber, which reduces the internal volume of the refrigerator compartment and makes it less convenient to store food. . Further, since this thawing chamber is used only for thawing and cannot be used for any other purpose, it becomes a nuisance for households that do not use frozen foods much.

[Purpose of the invention] This invention was devised in view of the above-mentioned drawbacks of the conventional technology.The purpose of this invention is to make it possible to control the temperature from around 0 degrees Celsius to several tens of degrees Celsius, and to be versatile depending on the type of food being stored. An object of the present invention is to provide an electric refrigerator with a usable food storage chamber.

[Examples] Hereinafter, this invention will be described in detail with reference to embodiments shown in the accompanying drawings.

FIG. 1 shows, for example, a four-door type electric refrigerator to which this invention is applied. That is,
This electric refrigerator has partition walls 1a to 1 having heat insulating properties.
A freezer compartment 2, a refrigerator compartment 3, an ice room 4, and a vegetable storage compartment 5 are formed to be independent from each other by c, and each food storage compartment is provided with doors 2a to 5a, respectively. Furthermore, door 4a of icehouse 4
A food storage box is actually attached to the back side of the door 5a of the vegetable storage room 5, but it is not shown in this drawing for convenience of drawing.

A cold air circulation means including an evaporator 6 and a blower fan 7 is provided on the back side of the freezer compartment 2. In this case, the freezer compartment 2 is provided with a partition wall 9 that forms a cold air distribution chamber 8 between it and a back wall thereof.
A cold air blowing grill 10 that opens toward the interior of the freezer compartment 1 is formed on the partition wall 9, and a duct 11 is communicated with the cold air distribution chamber 8. This duct 11 penetrates the insulation material filled between the inner box and the outer box and extends downward, and connects the refrigerator compartment 3, the ice room 4, and the vegetable storage compartment via branch ducts 11a, 11b, and 11c. 5. In connection with this, a damper thermostat 12a, which adjusts the amount of cold air supplied to the refrigerator room 3 and the ice room 4 through each branch duct 11a, 11b to maintain the inside of the room at a predetermined temperature;
12b are provided respectively. Although this type of damper thermostat is not shown in the drawing, the duct leading to the vegetable storage room 5 is actually provided with, for example, a manually operated throttle valve.

In the above configuration, when the blower fan 7 is operated continuously, a part of the cold air generated in the evaporator 6 is blown out from the cold air blowing grill 10 into the freezer compartment 2, cools the compartment, and then passes through the return passage 13. It is returned to the lower part of the evaporator 6. In addition, the cold air distributed in the cold air distribution chamber 8 is transferred to the duct 11 and each branch duct 11a to
It is supplied to each of the refrigerator compartment 3, ice room 4, and vegetable storage compartment 5 through the passage 11c, and cools each compartment to an optimal temperature. After that, the cold air from the ice room 4 and the vegetable storage compartment 5 flows into the refrigerator compartment 3 through the communication holes 14, 14 formed on the door side of the partition walls 1b, 1c, and the cold air inside the refrigerator compartment 3 At the same time, it is returned to the lower part of the evaporator 6 via the return passage 15.

According to this invention, the ice room 4 is made into a multipurpose food storage room that can also be used as a thawing room or a greenhouse room. That is, a heat sink 20 made of aluminum, for example, is provided inside the ice chamber 4, and one end 21a of a heat pipe 21, which is made of a small amount of evaporative working fluid, is attached to the heat sink 20. ing. And this heat pipe 21
The other end 21b is immersed in a heat generating part of the refrigeration cycle, for example, an oil cooler of the compressor 22. Note that, unlike this embodiment, the other end 21b of the heat pipe 21 may be brought into thermal contact with a condenser (not shown).

As best shown in FIG.
A front edge portion disposed on the door 4a side and a rear edge portion disposed on the back wall side of the ice chamber 4 are provided with through holes 20, respectively.
a..., 20b... are bored, and this heat sink 2
0 is arranged with an appropriate inclination angle so that its leading edge is high and its trailing edge is low. Therefore, according to this, warm air on the lower surface side of the heat dissipation plate 20 flows upward along the slope and escapes through the through holes 20a in the front edge, while cold air flows along the slope. The warm air then flows downward and enters the through holes 20b in the rear edge, thereby effectively circulating the warm air. Further, in this embodiment, the through hole 20a
. . , 20b . . . are punched out, cut and raised pieces 24 are left behind so that these cut and raised pieces 24 also contribute to heat exchange.

A solenoid valve 23 is attached to the heat pipe 21, which operates to open when energized and close when de-energized.
3 is placed in an ice chamber 4, so that the heat generated from this electromagnetic valve 23 when energized can also be effectively used as heat for defrosting frozen foods, for example.
In addition, by arranging the solenoid valve 23 in the ice room 4 in this way, it is possible to reduce the operating noise that occurs when turning on and off, and the solenoid valve 23 can be viewed from the front side of the refrigerator.
We can also perform the maintenance etc. of 3.
It is also convenient in terms of workability.

Further, according to this embodiment, the heat pipe 21
As shown in the figure, one end 21a is branched into a plurality of branches, three branches in this example, and each of these branch pipes 21a ₁ to 21a ₃ distributes heat evenly to the heat sink 20. I try to give. Regarding this point, there is a method of arranging heat pipes in a loop to uniformly heat the heat pipe, but according to this method, it is necessary to provide check valves in addition to electromagnetic valves at predetermined locations within the loop. On the other hand, if the valve is branched as described above, only one solenoid valve is required, which is preferable in terms of ease of assembly and cost.

In the above-described configuration, when storing food at freezing temperature in the ice room 4, the solenoid valve 23 may be de-energized. As a result, the inside of the ice room 4 is controlled to a predetermined optimum temperature by the damper thermostat 12b. On the other hand, when thawing frozen food in the ice chamber 4, for example, the damper thermometer 12
b is forcibly closed by manual operation or the like, and the solenoid valve 23 is energized to open the valve. This results in
Heat from the compressor 22 is applied to the heat sink 20 via the working fluid in the heat pipe 21, and the ice chamber 4
The inside is heated to a predetermined thawing temperature. Although not shown, there are communication holes 14, 1 for returning cold air.
4 is provided with a shutter plate that can be opened and closed, and when thawing frozen food as mentioned above, the communication hole 1
4 and 14 are closed by this shutter plate.

[Effect] As is clear from the explanation of the above embodiment, according to this invention, the temperature of the ice chamber can be lowered from around 0°C to several degrees.
Since it can be controlled over a range of up to 10℃, this ice room can be used for multiple purposes, such as freezing food storage or as a thawing room for frozen foods or as a greenhouse, making it extremely convenient. be.

In addition, according to this invention, by placing the solenoid valve of the heat pipe inside the ice chamber, the heat generated by the solenoid valve can be used effectively, and the operating noise of the solenoid valve can be reduced. I can figure it out. Furthermore, the effects are remarkable, such as being able to perform assembly and maintenance work from the front side of the refrigerator.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view schematically showing the internal structure of an embodiment of an electric refrigerator according to this invention, and FIG. 2 is a perspective view showing the heat sink and one end of the heat pipe in FIG. 1 separated. be. In the figure, 2 is a freezing room, 3 is a refrigerator room, 4 is an ice room,
5 is a vegetable storage room, 6 is an evaporator, 7 is a ventilation fan,
11 is a duct, 12a and 12b are damper thermoses, 20 is a heat sink, 21 is a heat pipe, 22 is a compressor, and 23 is a solenoid valve.

Claims (1)

[Claims for Utility Model Registration] (1) At least three food storage compartments, a freezing compartment, a refrigerator compartment, and an ice compartment, which are formed independently from each other by partition walls with heat insulation properties, and the food is produced by an evaporator. In the electric refrigerator, the cooled air is supplied to each of the food storage compartments by a cold air circulation means including a blower fan, a heat sink is provided in the ice chamber, one end of a heat pipe is attached to the heat sink, The other end of the heat pipe is connected to a heat generating section of a refrigeration cycle, so that the ice chamber can be used for multiple purposes such as a thawing chamber, and the working fluid sealed in the heat pipe can flow. An electric refrigerator characterized in that a solenoid valve for controlling the temperature is disposed within the ice chamber. (2) The electric refrigerator according to claim (1), wherein the other end of the heat pipe is connected to an oil cooler of a compressor. (3) The electric refrigerator according to claim (1) for utility model registration, characterized in that the other end of the heat pipe is connected to a condenser. (4) In claim (1) for utility model registration, the solenoid valve operates to open when energized and close when not energized, and the heat generated in the solenoid valve when energized is also used as a heating source for the ice chamber. An electric refrigerator characterized by being used as an electric refrigerator.