JPH0989437A - Electric refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure the number of revolutions at the time of lowering the temperature drop of a cooling fan motor by supplying a current for heating the motor without rotating to the fan motor during stopping of the motor. SOLUTION: When a compressor 2 and a cooling fan motor 3 are stopping, a switch SW1 and a switch SW2 are opened. At this time, the voltage of a commercial AC power source from a plug 1 is divided to a cooling fan motor 3 and a cold air duct antifreezing motor 4 and the current from the commercial power source is rectifier by a rectifier 5. Accordingly, an infinitesimal rectified current is supplied to the motor 3. Thus, the motor 3 is heated by the infinitesimal current conducted during stopping, the temperature drop during the stopping is avoided, and the increase in the viscosity of bearing oil is prevented. Therefore, when the motor 3 is transferred from the stopping state to the operating state, the number of revolutions is not lowered. In this case, the current for not rotating the motor 3 is an infinitesimal current.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling device for a domestic electric refrigerator.

[0002]

2. Description of the Related Art The main circuit of a general household electric refrigerator is shown in FIG. In the figure, 1 is a plug to be plugged into a commercial AC power outlet, 2 is a compressor, 3 is a cooling fan motor, 4 is a heater for preventing cold air duct freeze, SW13 is a switch for operating the compressor 2, and SW14 is a cooling fan. A switch for operating the motor 3, 16 is a switch SW1
3, a switch circuit having a switch SW14.
The switches SW13 and SW14 are relay switches.

Generally, in a domestic electric refrigerator, the cooling fan motor 3 is disposed near the evaporator due to its structure and is placed at a low ambient temperature. for that reason,
When the cooling fan motor 3 is at rest, the temperature of the cooling fan motor 3 decreases, the viscosity of the bearing oil increases, and the rotation speed of the cooling fan motor 3 tends to decrease when the cooling fan motor 3 operates.

In order to prevent the above-mentioned problems, conventionally, in a domestic electric refrigerator, the cooling fan motor 3 is covered with a box of resin or the like to reduce the temperature drop of the cooling fan motor 3 and to reduce the bearing oil. The viscosity of the cooling fan motor 3 is prevented from increasing and the rotation speed of the cooling fan motor 3 is secured. Alternatively, by increasing the rotational force of the cooling fan motor 3 alone, it is possible to cope with the increase in the viscosity of the bearing oil due to the temperature decrease of the cooling fan motor 3.

[0005]

However, if the circumference of the cooling fan motor is covered with a box made of resin or the like, the cost and space need to be increased, and if the cooling force of the cooling fan motor is strengthened. However, the cost and the mass are increased accordingly.

The present invention provides an electric refrigerator which has a simple and inexpensive structure to reduce the temperature drop of the cooling fan motor during the suspension of the cooling fan motor and to secure the rotation speed of the cooling fan motor during the operation of the cooling fan motor. The purpose is to

[0007]

In order to achieve the above object, according to the present invention, a current that does not rotate the cooling fan motor is supplied to the cooling fan motor while the cooling fan motor is at rest, or the cooling fan motor is attached to the cooling fan motor. By energizing the supplied heater, that is, while the cooling fan motor is stopped, the cooling fan motor itself is made to generate heat, or heat is applied to the cooling fan motor from the outside.

[0008] With this configuration, the cooling fan motor is stopped while the cooling fan motor is not covered with a box of resin or the like, or the rotation force of the cooling fan motor is not strengthened. Reduce the temperature drop of
It is possible to prevent a decrease in the rotation speed of the cooling fan motor during operation of the cooling fan motor.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Six embodiments of the present invention will be shown below. First, a first embodiment is shown in FIG. In the figure,
1 is a plug to be plugged into a 100V commercial AC power outlet, 2 is a compressor, 3 is a cooling fan motor, 4 is a cool air duct freeze prevention heater, 5 is a rectifier, SW1 is a switch for operating the compressor 2, and SW2 is Cooling fan motor 3
To switch the current to the switch, 6 is the switch SW1,
A switch circuit having a switch SW2. A cold air duct freeze prevention heater 4 and a rectifier 5 are connected in series to both ends of the switch SW2. The switch SW1, the switch SW2, and the switches that appear thereafter are relay switches.

In the first embodiment, the compressor 2
When the cooling fan motor 3 is at rest, as shown in FIG. 1, the switches SW1 and SW2 are turned off. At this time, the voltage of the commercial AC power source from the plug 1 is divided into the cooling fan motor 3 and the cool air duct freeze prevention heater 4, and the current from the commercial AC power source is rectified by the rectifier 5. A minute rectified current is supplied to the motor 3. The cooling fan motor 3 generates heat due to the minute rectified current that is supplied during the rest, so that the temperature drop during the rest is avoided and the viscosity of the bearing oil is prevented from increasing. Therefore, when the cooling fan motor shifts from the idle state to the operating state, its rotation speed does not decrease.

Next, a second embodiment is shown in FIG. In the figure, 7 is a full-wave rectifier circuit composed of four rectifiers D1, D2, D3, D4, whose input points P, Q are connected to both ends of the plug 1. SW3 is a switch for operating the compressor 2, and SW4 and SW5 are cooling fan motors 3, respectively.
To switch the current to the switch, 8 is the switch SW3
It is a switch circuit having a switch SW4 and a switch SW5. And the cooling fan motor 3 is a switch SW
4, the contact point C of the switch SW5 is connected, and the output points T and S of the full-wave rectifier circuit 7 are connected to the contact point b of the switch SW4 and the contact point a of the switch SW5, respectively.

In the second embodiment, the compressor 2
When the cooling fan motor 3 is at rest, as shown in FIG. 2, the switch SW3 is OFF and the switch SW3 is OFF.
4 is connected to the contact b side, and the switch SW5 is connected to the contact a side. Therefore, when the potential of the input point P of the full-wave rectifier circuit 7 is positive and the potential of the input point Q is negative, the plug 1 → the input point P
→ rectifier D1 → rectification current flows through a path of the output point S → switch SW5 → cooling fan motor 3 → switch SW4 → output point T → rectifier D3 → the input point Q → plug 1, on the _contrary, the potential of the input point Q positive , When the potential at the input point P is negative, the plug 1 → the input point Q → the rectifier D2 → the output point S → the switch SW5
The rectification current flows through the path of the cooling fan motor 3, the switch SW4, the output point T, the rectifier D4, the input point P, and the plug 1. In this case, by increasing the threshold voltage of the rectifiers D1 to D4, the current flowing through each of the routes becomes a minute current.

Next, a third embodiment is shown in FIG. In the figure, 9 is a DC power supply provided separately from the commercial AC power supply, SW6 is a switch for operating the compressor 2, SW7,
SW8 is a switch for switching the current to the cooling fan motor 3, 10 is a switch SW6, and a switch SW.
7, a switch circuit having a switch SW8. The cooling fan motor 3 has switches SW7 and S.
It is connected to each contact C of W8, and DC power supply 9
Is the contact b of the switch SW7 and the contact a of the switch SW8
It is connected to the.

In the third embodiment, the compressor 2
When the cooling fan motor 3 is at rest, as shown in FIG. 3, the switch SW6 is off and the switch SW6 is off.
7 is connected to the contact b side, and the switch SW8 is connected to the contact a side. Therefore, a minute DC current flows through the path of DC power supply 9 → switch SW7 → cooling fan motor 3 → switch SW8 → DC power supply 9.

Next, a fourth embodiment is shown in FIG. In the figure, 11 is a transformer for transforming the voltage from the commercial AC power source into a low voltage, and its secondary coil L2 is connected to the cooling fan motor 3 via a switch. The transformer 11 is a step-down transformer in which the number of turns of the secondary coil L2 is smaller than that of the primary coil L1. SW9 is a switch for operating the compressor 2, SW
Reference numeral 10 is a switch for switching the current to the cooling fan motor 3. 12 is a switch SW9 and a switch SW10
Is a switch circuit having.

In the fourth embodiment, the compressor 2
When the cooling fan motor 3 is at rest, the switch SW9 is OFF and the switch SW1 is OFF, as shown in FIG.
0 is connected to the contact b side. Therefore, transformer 1
Since the low voltage stepped down by 1 is applied to the cooling fan motor 3, a minute alternating current is supplied to the cooling fan motor 3.

Next, a fifth embodiment is shown in FIG. 13 is a thyristor, SW11 is a switch for operating the compressor 2, SW12 is a switch for switching the current to the cooling fan motor 3, and 14 is a switch SW11 and a switch SW1.
2 is a switch circuit having 2. And thyristor 1
3 is connected to both ends of the switch SW12.

In the fifth embodiment, the compressor 2
When the cooling fan motor 3 is at rest, the switches SW11 and SW12 are turned off as shown in FIG. Therefore, the current from the commercial AC power supply is rectified and reduced by the thyristor 13, so that a small rectified current is supplied to the cooling fan motor 3.

According to the above-described embodiments, the cooling fan motor 3 can be heated by supplying the cooling fan motor 3 with a current that does not rotate the cooling fan motor 3 while the cooling fan motor 3 is at rest. Therefore, it is possible to reduce the temperature drop of the cooling fan motor 3 during the suspension of the cooling fan motor 3. Here, the cooling fan motor 3
Current that does not rotate the DC current (including rectified current)
Or a very small alternating current. However, even if it is a direct current, if it is a large current, the heat generation in the cooling fan motor will be large, so a small current is desirable.

Finally, a sixth embodiment is shown in FIG. In the figure, 15 is a heater, which is a cooling fan motor 3
Is pasted on. The cooling fan motor 3 is controlled so that the heater 15 is energized while the motor 3 is at rest. Therefore, when the cooling fan motor 3 is at rest, the heater 15 generates heat and heats the cooling fan motor 3, so that the temperature drop of the cooling fan motor during the suspension of the cooling fan motor 3 can be reduced.

[0021]

According to the present invention, when the cooling fan motor is at rest, the cooling fan motor itself is heated, or heat is externally applied to the cooling fan motor, so that the cooling fan motor is at rest. It is possible to reduce the temperature drop, prevent the rotation speed of the cooling fan motor from decreasing when the cooling fan motor is operating, and secure the cooling power.

Further, unlike the prior art, it is not necessary to cover the periphery of the cooling fan motor with a box made of resin or the like or to enhance the rotational force of the cooling fan motor alone in order to reduce the temperature drop of the cooling fan motor. There are cost advantages,
Further, the structure around the cooling fan motor can be reduced in size and weight.

[Brief description of drawings]

FIG. 1 is a conceptual diagram of electric refrigerator wiring that supplies a minute rectified current to a cooling fan motor during a period when the cooling fan motor is idle in the first embodiment of the present invention.

FIG. 2 is a conceptual diagram of electric refrigerator wiring that supplies a rectified current to a cooling fan motor during a suspension of the cooling fan motor in the second embodiment of the present invention.

FIG. 3 is a conceptual diagram of electric refrigerator wiring that supplies a direct current to a cooling fan motor during a cooling fan motor suspension in a third embodiment of the present invention.

FIG. 4 is a conceptual diagram of electric refrigerator wiring for supplying a minute AC current to a cooling fan motor during a cooling fan motor suspension in a fourth embodiment of the present invention.

FIG. 5 is a conceptual diagram of electric refrigerator wiring for supplying a minute rectified current to a cooling fan motor during a cooling fan motor suspension in a fifth embodiment of the present invention.

FIG. 6 is a diagram showing a sixth embodiment of the present invention.

FIG. 7 is a conceptual diagram of conventional general electric refrigerator wiring.

[Explanation of symbols]

1 Commercial AC Power Outlet Plug 2 Compressor 3 Cooling Fan Motor 4 Heater for Cold Air Duct Freezing 5 Rectifier 6 Switch Circuit with Switch SW1 and Switch SW2 7 Full Wave Rectifier Circuit 8 Switch SW3, Switch SW4, Switch SW5
Switch circuit having 9 DC power supply 10 Switch SW6, switch SW7, switch SW
8 switch circuit 11 transformer 12 switch SW9, switch SW10 switch circuit 13 thyristor 14 switch SW11, switch SW12 switch circuit 15 heater 16 switch SW13, switch SW14 switch circuit SW1 compressor 2 switch SW2 Switch for switching current to the cooling fan motor 3 SW3 Switch for operating the compressor 2 SW4 Switch for switching current to the cooling fan motor 3 SW5 Switch for switching current to the cooling fan motor 3 SW6 Switch for operating the compressor SW7 Cooling Switch for switching current to fan motor 3 SW8 Switch for switching current to cooling fan motor 3 SW9 Switch for operating compressor 2 SW10 Cooling fan Switch for switching the current to the motor 3 SW11 Switch for operating the compressor 2 SW12 Switch for switching the current to the cooling fan motor 3 SW13 Switch for operating the compressor SW14 Switch for operating the cooling fan motor D1, D2, D3 , D4 Rectifier P, Q Input point of full wave rectifier circuit S, T Output point of full wave rectifier circuit 7

Claims (5)

[Claims] 1. An electric refrigerator for home use, comprising a cooling fan motor, wherein the cooling fan motor is intermittently energized, and a current for generating heat without rotating the cooling fan motor while the cooling fan motor is at rest is provided. An electric refrigerator characterized by being supplied to the cooling fan motor. 2. The electric refrigerator according to claim 1, wherein a rectified current obtained by rectifying a current from a commercial AC power source is used as the current. 3. The electric refrigerator according to claim 1, wherein a direct current from a direct current power source provided separately from a commercial alternating current power source is used as the current. 4. The electric refrigerator according to claim 1, wherein a micro AC current is used as the power supply by transforming or dividing the voltage of a commercial AC power supply. 5. An electric refrigerator comprising a cooling fan motor, wherein the cooling fan motor is intermittently energized, wherein a heater attached to the cooling fan motor is energized while the cooling fan motor is stopped. Electric refrigerator.