JPS646391B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to an operation control device for a refrigerator that forcibly operates a compressor of a cooling system for a certain period of time.

Conventional configuration and problems thereof Recently, refrigerators have been proposed that use a timer to force the compressor to operate for a certain period of time to quickly cool the freezer compartment. This refrigerator performs rapid cooling for a certain period of time, and even if the timer ends the rapid cooling, if a manual rapid cooling start signal is input immediately, the compressor is forced to operate again and the timer starts the rapid cooling. It was hot. This caused an unreasonable situation when rapid cooling was started again even though the freezer compartment was sufficiently cold. In addition, refrigerators cool the refrigerator compartment at the same time as the freezer compartment by sending cold air from the freezer compartment into the refrigerator compartment, so if the freezer compartment is rapidly cooled, the temperature in the refrigerator compartment also drops. Normally, the time for this rapid cooling of the freezer compartment is set to a time that will prevent the refrigerator compartment temperature from dropping below 0℃, but after the rapid cooling is completed,
If rapid cooling is started again, the temperature inside the refrigerator room will drop below 0°C, which has the disadvantage that the food in the refrigerator room will freeze.

Purpose of the Invention Therefore, an object of the present invention is to eliminate the unreasonableness of starting rapid cooling again when the freezer compartment or refrigerator compartment is sufficiently cold.

Structure of the Invention In order to achieve this object, the present invention provides a first timer in which a quenching operation time is set and a second tire that starts the timer operation based on the output of the first timer. Since the quenching operation is kept on standby for a certain period of time by a timer, it is possible to eliminate the need to start quenching again when the freezer and refrigerator compartments are sufficiently cold.

DESCRIPTION OF EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. In the figure, 1 is a temperature detection circuit that detects the temperature in the freezer compartment of the refrigerator, and it includes a thermistor TH and a resistor.
It is composed of R ₁ , R ₂ , R ₃ , R ₄ and a comparator 2. 3 is a holding circuit that inverts the output and holds the output, which includes resistor _R5 and J-K flip-flop 4.
It is composed of When the JK flip-flop 4 is powered on, the Q output is set to "L" and the output is set to "H". In addition, when the reset terminal R is "L", Q and output are switched each time a pulse is input to the input terminal T.
When reset terminal R is “H”, Q output is “L”,
The Q output is kept at "H". The output is input to a standby circuit 7 consisting of an OR gate. 5 is a switch circuit, which is composed of a resistor R ₆ and a switch 6. 8 is a NAND gate, the input of which is connected to the temperature detection circuit 1 and the OR gate 9, and the output of which is connected to the integration timer 10.
This integration timer 10 is for integrating the operating time of the compressor, and when the set time is reached, the output changes from the normal "L" to "H". Then, the output of the switch circuit 12 composed of the resistor _R7 and the switch 11 is maintained at "H" until it becomes "L", and when the output of the switch circuit 12 becomes "L", it is reset and the output becomes "L". change. This switch circuit 12 detects the temperature of the cooler, and outputs "L" when the temperature of the cooler rises. Also,
The output of NAND gate 8 is connected to the base of transistor 13. 14 is a relay, contact 1
4', and is connected to the collector of the transistor 13. 15 is a transistor,
The base is connected to the output of the integration timer 10. 16 is a relay, which has a contact 16',
It is connected to the collector of the transistor 15. In addition, compressor 1 is connected to the normally closed side of contact 16'.
7. A defrosting heater 18 is connected to the normally open side. Reference numeral 19 is an AC power source connected to the compressor 17 and the defrosting heater 18 via contacts 14' and 16'. A first timer 20 has a quenching time set in advance, and its input is connected to the output of the holding circuit 3. Also, the input of the first timer 20 is
Connected to the input of OR gate 9. Said first
The output of the timer 20 is input to a second timer 21 which sets a time during which no pulse is input to the holding circuit 3 after the rapid cooling is completed by this timer. Further, the output of the first timer 20 serves as the reset input of the holding circuit 3 and the input of the OR circuit 9.
Further, the output of the second timer 21 serves as an input to the standby circuit 7. The output of the first timer 20 is kept at "L" when the input is "H";
It starts the timer operation when the time changes to , and outputs "H" when the set time is reached. In addition, the second timer 21 outputs "L" when the input is "L", and when a pulse is input, it outputs "H", starts timer operation, and outputs "L" when the set time is reached. This is what is output.

Next, the operation will be explained. First, when the power is turned on, the output of the JK flip-flop 4 is "H" and the output of the OR gate 9 is "H".
At this time, if the temperature inside the refrigerator is high, the output of the temperature detection circuit 1 is "L", so the NAND gate 8 outputs "H", the transistor 13 is turned on, the relay 14 is activated, and the contact 14' is closed. It will be done. Also, since the output of the NAND gate 8 is "H", the integration timer 10 starts integration. Since the output of the integration timer 10 is "L", the transistor 1
5 is OFF and relay 16 does not operate, so contact 1
6' is on the normally closed side. AC power 19 is supplied to the compressor 17 through the contacts 14' and 16', and the compressor 17 operates. If the temperature inside the refrigerator falls from this state, the output of the temperature detection circuit 1 becomes "H", the output of the NAND gate 8 becomes "L", the transistor 13 is turned off, and the contact 14' is opened. By doing compressor 1
7 is OFF. In this case, the integration timer 10 stops the integration. The internal temperature of the refrigerator is maintained at a desired temperature by repeating the high and low internal temperature states. When the integration timer 10 reaches the set time, the output changes to "H", the transistor 15 turns on, and the relay 16 operates. Then, the contact 16' becomes normally open and the compressor 17
is turned off and the defrosting heater 18 is turned on. During this time,
The integration timer 10 continues to output "H", and when the temperature of the cooler increases by the defrosting heater 18, the switch circuit 12 outputs "L" and the integration timer 10 is reset. This type of operation is normally performed.

Next, we will discuss rapid cooling operation. When the power is turned on, the output of the JK flip-flop 4 is "H", so the first timer 20 outputs "L" and the second timer 21 outputs "L". At this time, when the switch 6 is pressed and a pulse is output from the switch circuit 5, the pulse is input to the JK flip-flop 4, and the output is inverted to "L" and the first timer 20 starts its timer operation. As a result, the output of OR gate 9 is “L”
Therefore, the output of the NAND gate 8 becomes "H", turning on the transistor 13 and closing the contact 14' to operate the compressor 17. Also, integration timer 1
0 also starts integration. During this rapid cooling operation, when the integration timer 10 reaches the set time and the output becomes "H", the transistor 15 turns on, the contact 16' becomes normally open, and defrosting begins. However, since this defrosting time is sufficiently shorter than the quenching time, the remaining time of the first timer 20 after the defrosting is completed is enough to cool the vehicle. Next, when the set time of the first timer 20 comes, the output of the first timer 20 becomes "H". As a result, the output of the OR gate 9 becomes "H" and the output of the NAND gate 8 comes to be controlled by the output of the temperature detection circuit 1. Normally, after the rapid cooling operation ends, the temperature inside the refrigerator is low, so the output of the temperature detection circuit 1 is "H" and the output of the NAND gate 8 is "L". As a result, the transistor 13 is turned off, the contact 14' is opened, and the compressor 17 is turned off. The integration timer 10 also stops integrating. Further, when the output of the first timer 20 becomes "H", "H" is input to the reset terminal of the JK flip-flop 4, and at the same time, the output becomes "H". As a result, the output of the first timer 20 becomes "L". Then, in the second timer 21, “L” → “H” →
The "L" pulse will be input, and the output of the second timer 21 will become "H" and start timer operation. During this time, even if the switch 6 is pressed and the switch circuit 5 outputs a pulse to the holding circuit 3 and the Q output is set to "L", the output of the second timer 21 is "H", so the standby circuit 7 outputs a pulse. is “H”
Since the output of OR gate 9 is “H”,
Since the output of the AND gate 8 is "L", the compressor 17 is turned off. From this state, the second
When the set time of the timer 21 is reached, the output becomes "L", so the output of the standby circuit 7 becomes "L" and the rapid cooling operation is started.

Effects of the Invention As is clear from the above embodiments, the present invention includes a first timer that sets the operation time for forced operation of the compressor, and a second timer that starts the timer operation based on the output of the first timer. When the time set by the first timer is reached, the second timer is activated and the forced operation is put on standby in the standby circuit, so the forced operation is performed for a certain period of time and then the operation is terminated by the first timer. In this case, even if the forced operation start signal is input immediately, the forced operation will be on standby, so there is no unreasonable need to cool down the sufficiently cold freezer compartment again, and the second timer will prevent the temperature inside the refrigerator compartment from dropping unnecessarily. This can be prevented by setting the value of .

[Brief explanation of drawings]

The figure shows an operation control circuit for a refrigerator, which is an embodiment of the present invention. 1...Temperature detection circuit, 3...Holding circuit, 7...
Standby circuit, 20...first timer, 21...second
timer.

Claims (1)

[Claims] 1. A temperature detection circuit that detects the temperature inside the refrigerator and operates the compressor of the cooling system, an operation holding circuit that forcibly operates the compressor, an integration timer that totals the operating time of the compressor, and a cooler of the cooling system. a defrosting end detection means for detecting removal of accumulated frost; a switch for operating a holding circuit for forcibly operating the compressor; and a first timer for setting a time for forcibly operating the compressor. , a second timer that starts timer operation based on the first timer output;
A refrigerator operation control device comprising: a standby circuit that operates a second timer to standby forced operation when the first timer reaches a set time.