JPH01300178A - Cold storage - Google Patents

Abstract

PURPOSE:To quickly cool a cold storage while improving handiness by automatically beginning rapidly cooling operations when the temperature of the cold storage is equal to or higher than the fixed temperature at which the cold storage temperature is set in normal cooling operation, or when a continuous operation time of a compressor has become equal to or more than the fixed time. CONSTITUTION:When the temperature of a freezing chamber is heightened up to compressor-on temperature (for example, -18 deg.C), a compressor 4 and a fan motor 5 are switched on to drive at the time t1. When the temperature of the freezing chamber is lowered down to compressor-off temperature (for example, -21 deg.C), the compressor 4 and the fan motor 5 are driven at the time t2 intermittently. When the freezing chamber is overloaded, the temperature is rapidly heightened at the time t3 and a relay switch 6 is turned on at the time t4 and the compressor 4 and the fan motor 5 are switched on to drive. When the temperature is heightened up to rapidly cooling operation beginning temperature (for example, -10 deg.C) of the fixed temperature set higher than the compressor-on temperature, at the time t5 the rapidly cooling operation of the fan motor 5 is started at rotating speed which is more than normal cooling rotating speed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a refrigerator that performs a normal cooling operation and a rapid cooling operation with a larger cooling capacity than the normal cooling operation.

(Prior Art) In this type of refrigerator, for example, a fan-cooled refrigerator, during normal cooling operation, the internal temperature is detected and the temperature is set approximately within the set temperature range between the compressor-on temperature and the compressor-off temperature. On the other hand, in rapid cooling operation, when the rapid cooling switch is operated, the refrigerant supply capacity of the compressor is increased using a so-called inverter, or the blowing performance of the fan is increased. The system is operated to increase the amount of cold air blown into the refrigerator.

(Problems to be Solved by the Invention) In the conventional configuration described above, the user manually operates the rapid cooling switch to start the rapid cooling operation. For this reason, when a large amount of items to be cooled are stored in the refrigerator (1) or when the door is opened and closed frequently in the summer, the interior of the refrigerator becomes overloaded and the interior needs to be cooled rapidly. In such cases, the user must operate the rapid cooling switch to start the rapid cooling operation each time, which poses a problem of poor usability.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a refrigerator that can quickly cool the inside of the refrigerator when the inside of the refrigerator becomes overloaded 6;f, and that can improve usability.

[Structure of the Invention] (Means for Solving the Problems) The refrigerator of the present invention performs a normal cooling operation and a rapid cooling operation with a larger cooling capacity than the normal cooling operation, and the refrigerator has an internal temperature that is lower than that in the normal cooling operation. Control that automatically starts the rapid cooling operation when the temperature reaches a predetermined temperature set higher than the compressor-on temperature, or when the continuous operation time of the compressor in the normal cooling operation exceeds a predetermined time. It is characterized by the provision of means.

(Function) In the normal cooling operation, the compressor is operated intermittently so that the temperature inside the refrigerator fluctuates between the preset compressor-on temperature and the compressor-off temperature. If the inside of the refrigerator becomes overloaded, the temperature inside the refrigerator may rise abnormally if only the compressor is operated in the normal cooling mode, or it may take a long time for the temperature inside the refrigerator to decrease even if the compressor is operated. This may increase the continuous operation time of the compressor. In such a case, when the internal temperature of the refrigerator reaches a predetermined temperature set higher than the compressor-on temperature during normal cooling operation by the control means, or when the continuous operation time of the compressor during normal cooling operation exceeds a predetermined time, Since the rapid cooling operation is automatically started when the above conditions are reached, the interior of the refrigerator is quickly cooled, and since manual operation is no longer required, usability is improved.

(Example) An example of the present invention will be described below with reference to the drawings.

First, in FIG. 2 showing the electrical configuration, 1 is a commercial AC power supply, and a compressor 4 and a fan motor 5 are connected in parallel between power supply buses 2 and 3 of this. 6 is power bus 2
The compressor 4 and the fan motor 5 are controlled to be energized or de-energized by a relay switch interposed therebetween. The fan motor 5 is made of, for example, a capacitor induction motor, and has a main winding 7 and an auxiliary winding 8, and a parallel circuit of capacitors 9 and 1o is connected between the auxiliary winding 8 and the power supply bus 2. has been done. Here, a relay switch 11 is interposed in the current-carrying path of the capacitor 10 in the parallel circuit. On the other hand, 12 is a microcomputer serving as a control means, which receives a temperature detection signal Sa from a freezer compartment temperature sensor 13 that detects the internal temperature of a freezer compartment (not shown), and generates a compressor on signal sb and a capacitor capacity switching signal Sc. It is designed to output . 14 is a transistor array serving as a switching means, and this receives the compressor on signal sb from the microcomputer 12.
and capacitor capacity switching signal SC, and when receiving the compressor on signal sb, the excitation coil 15 is energized, the relay switch 6 is turned on, and the compressor 4 and fan motor 5 are energized and driven. When receiving the capacitor capacity switching signal Sc, the excitation coil 16 is energized, the relay switch 11 is turned on, and the capacitors 9 and 10 are connected in parallel to the auxiliary winding 8 of the fan motor 5. Note that 17 and 18 are DC output terminals.

Next, the effect of the above configuration will be explained using the first
Figure 3 shows the control function of the microcomputer 12.
This will be explained with reference to the drawings.

First, during normal cooling operation, the freezer compartment temperature sensor 1
When the temperature inside the freezer rises to the compressor-on temperature (for example, -18°C) based on the temperature detection signal Sa from step 3, at time t1, YES is determined in judgment step d, "Is the compressor-on temperature or higher?" Then, the process step e is executed to "start the compressor operation timer" and "set the compressor on flag".

Thereafter, as the control proceeds to an execution processing routine (not shown), the compressor on signal sb is applied from the microcomputer 12 to the transistor array 14, the excitation coil 15 is energized, and the relay switch 6 is turned on, so that the compressor 4 and The fan motor 5 is energized and the inside of the freezer compartment is cooled. In this case, the relay switch 11 is turned off, only the capacitor 9 is connected to the auxiliary winding 8 of the fan motor 5, and the fan motor 5 rotates at the normal cooling rotation speed. After this, the temperature of the freezer compartment will be the compressor off temperature (for example -21℃)
At time t2, the determination step B goes to "Is the compressor off temperature or lower?" YES, and processing step C is executed to "reset the compressor operation timer,""clear the compressor on flag," and Perform "quick cooling operation flag clear". Thereafter, as the control proceeds to an execution processing routine (not shown), the compressor on signal sb is no longer applied from the microcomputer 12 to the transistor array 14, the excitation coil 15 is cut off, the relay switch 6 is turned off, and the compressor 4 and The fan motor 5 is stopped due to power cut. From then on, the compressor 4 and the fan motor 5 are driven intermittently as described above so that the temperature of the freezer compartment varies between the compressor-on temperature and the compressor-off temperature.

However, when the above-mentioned normal cooling operation is performed, if the freezer compartment becomes overloaded (for example, when a large number of objects to be cooled with high temperature are stored), time t occurs.

The temperature rises rapidly at time t4, and as mentioned above, the relay switch 6 is turned on and the compressor 4 and fan motor 5 are turned on.
is driven with electricity, but in this case, the temperature may further rise due to insufficient cooling capacity against overload. In such a case, when the temperature rises to a rapid cooling operation start temperature (for example, -10°C), which is a predetermined temperature set higher than the compressor-on temperature, at time t, the "rapid cooling operation" of judgment step f is started. Is the temperature higher than the start temperature?", the process advances to YES and executes processing step g to "set the rapid cooling operation flag." Thereafter, control proceeds to an execution processing routine (not shown), and a capacitor capacitance switching signal Sc is applied from the microcomputer 12 to the transistor array 14.
When the excitation coil 16 is energized, the relay switch 11 is turned on, and the capacitors 9 and 10 are connected in parallel to the auxiliary winding 8 of the fan motor 5, so that the fan motor 5 rotates at a speed higher than the normal cooling rotation speed. A rapid cooling operation is started in which the engine rotates at a high rapid cooling rotational speed. As a result, the amount of cold air blown by a fan (not shown) increases and the cooling capacity within the freezer compartment increases, so that the temperature quickly drops. Then, when the temperature falls to the compressor-off temperature, at time t8, judgment step b is performed.
Is it below the compressor off temperature? ”, go to YES and execute processing step C to “reset compressor operation timer” and “clear compressor on flag”
and "clear the rapid cooling operation flag". After this,
As control proceeds to an execution processing routine (not shown),
Compressor on signal s from microcomputer 12
b and capacitor capacity switching signal Sc are no longer applied to transistor array 14, excitation coils 15 and 16 are cut off, relay switches 6 and 11 are turned off, and compressor 4. While the fan motor 5 is stopped due to power cut,
Only the capacitor 9 is connected to the auxiliary winding 8 of the fan motor 5. From then on, the normal cooling operation described above is performed.

On the other hand, if the freezer compartment becomes overloaded during normal cooling operation, the temperature rises depending on the degree of overload, and at time t7, the relay switch 6 is turned on as described above and the compressor 4 is turned on. After the fan motor 5 is energized and driven, the temperature may slowly drop because the cooling capacity is insufficient in response to an overload. In such a case, the microcomputer 12 controls the compressor 4.
When the continuous operation time is measured and the continuous operation time exceeds a predetermined time T (for example, 90 minutes), at time t8, the determination of "Is the compressor operation timer counting up?" in decision step a is made YES. The program then proceeds to process step g to set the "rapid cooling operation flag." Thereafter, as the control proceeds to an execution processing routine (not shown), a capacitor capacity switching signal Sc is given from the microcomputer 12 to the transistor array 14, and the fan motor 5 rotates at the rapid cooling speed in the same manner as described above. Driving begins.

This increases the cooling capacity of the freezer compartment, so the temperature drops quickly. Then, when the temperature falls to the compressor off temperature, time t occurs.

In the same manner as described above, the compressor on signal sb and the capacitor capacity switching signal Sc are sent from the microcomputer 12.
is no longer provided to transistor array 14, compressor 4. While the fan motor 5 is stopped due to power cut,
Only the capacitor 9 is connected to the auxiliary winding 8 of the fan motor 5. From then on, the normal cooling operation described above is performed.

According to this embodiment having such a configuration, the microcomputer 12 determines when the temperature of the freezing compartment reaches or exceeds the rapid cooling operation start temperature, or when the continuous operation time of the compressor 4 in the normal cooling operation exceeds a predetermined time. Since the system automatically starts the rapid cooling operation when the temperature of Usability can be improved.

In the above embodiment, the rapid cooling operation is performed by increasing the rotational speed of the fan motor 5 to increase the air blowing performance of the fan. Alternatively, the operation may be performed to increase the value.

[Effects of the Invention] As is clear from the above description, the present invention is effective when the temperature inside the refrigerator reaches a predetermined temperature set higher than the compressor-on temperature in the normal cooling operation, or The structure is equipped with a control means that automatically starts the rapid cooling operation when the continuous operation time of the compressor exceeds a predetermined time, so when the inside of the refrigerator becomes overloaded, the inside of the refrigerator can be quickly cooled down. This has the excellent effect of improving usability.

[Brief explanation of the drawing]

The drawings show one embodiment of the present invention; FIG. 1 is a diagram showing temperature changes, FIG. 2 is an electrical configuration diagram, and FIG. 3 is a flowchart for explaining the control function of the microcomputer. In the drawings, numeral 4 represents a compressor, and numeral 12 represents a microcomputer (control means). Applicant: Toshiba Corporation 1st Unit No. 22

Claims (1)

[Claims] 1. In a normal cooling operation and a rapid cooling operation with a larger cooling capacity than the normal cooling operation, when the internal temperature reaches a predetermined temperature set higher than the compressor-on temperature in the normal cooling operation, Alternatively, the refrigerator is further provided with a control means for automatically starting the rapid cooling operation when the continuous operation time of the compressor in the normal cooling operation exceeds a predetermined time.