JPH04313662A - Icemaker for refrigerator - Google Patents

Abstract

PURPOSE:To effectively manufacture transparent ice without previously freezing water of surface part at the time of quick cooling temperature. CONSTITUTION:Icemaking is conducted by heating an upper part of an icemaking tray 12 by a heater 22 while bringing chilled gas to a lower part. The heater 22 is energized simultaneously upon starting of icemaking. The heater 22 is interrupted at the time of normal cooling operation when a temperature sensor 19 for an icemaking tray detects -5 deg.C, and interrupted at the time of quick cooling operation when the sensor 19 detects -13.5 deg.C. Thus, quantity of heat of the heater 22 is larger at the time of the quick cooling than that at the time of the normal operation, and water of a surface part is not previously frozen.

Description

[Detailed description of the invention]

[Object of the invention]

0002

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ice-making device for a refrigerator that can produce transparent ice by sequentially freezing water stored in an ice-making tray from the bottom.

0003

[Prior Art] In fan-cooled refrigerators, the compressor is started and stopped based on the temperature of the freezing compartment, and when the temperature of the freezing compartment reaches a predetermined temperature or higher, the compressor starts operating and the fan is activated. When the temperature of the freezer compartment falls below a predetermined temperature due to the supply of cold air, the compressor and fan are stopped. In addition, some recent fan-cooled refrigerators allow you to select rapid cooling operation so that food stored in the freezer compartment can be frozen quickly. The compressor and fan are operated continuously for, for example, 90 minutes regardless of the time.

As an ice making device installed in such a fan-cooled refrigerator capable of rapid cooling operation, the top of the ice tray is covered with a cover equipped with a heater, and the heater heats the top of the ice tray while blowing cold air through the ice tray. Some devices are configured to make ice by blowing air onto the bottom of the ice. With this ice tray, the water stored in the ice cube tray freezes from the bottom to the top, so air bubbles generated during the freezing process can freely escape from the unfrozen water surface, making it transparent. This means that ice can be produced.

[0005] In this ice-making device, a temperature sensor is provided at a predetermined position of the ice-making tray, and when the detected temperature of this ice-making tray temperature sensor reaches, for example, about -5°C, the unfrozen portion is in a state where only the water surface portion remains. At that point, the heater is turned off and the water surface is finally frozen. Once the water stored in the ice tray is completely frozen, the temperature of the ice tray will drop rapidly, so when the ice tray temperature sensor detects a predetermined low temperature, for example -13.5°C, ice making is complete. The system then moves on to the next ice removal operation.

[0006]

However, when the rapid cooling operation is selected, cold air is continuously blown onto the ice tray during the rapid cooling operation. For this reason, the ice tray temperature sensor detects -5℃ earlier, and the ice tray temperature sensor detects -5℃ when not only the water surface but also the water at a considerable depth is unfrozen. Sometimes I end up doing it. When this happens, a film of ice forms on the water surface, leaving no place for air bubbles to escape, resulting in opaque ice containing air bubbles.

The present invention has been made in view of the above circumstances, and its purpose is to
To provide an ice making device for a refrigerator capable of producing transparent ice.

[Configuration of the invention]

[0009]

[Means for Solving the Problems] The present invention is an ice making device that is incorporated in a refrigerator and makes ice by blowing cold air onto the bottom of an ice tray while heating the top with a heater, and which completes ice making from the start of ice making. When a rapid cooling operation for rapidly freezing food stored in the refrigerator is selected, the total calorific value of the heater is made larger than during normal cooling operation.

0010

[Operation] When the rapid cooling operation is selected, since cold air is continuously blown onto the ice tray, the temperature of the ice tray tends to decrease first. However, during rapid cooling operation, the total amount of heat generated by the heater until ice making is completed is greater than during normal operation, so there is no risk of an ice film forming on the water surface.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings as applied to an ice making device for a fan-cooled refrigerator.

First, in FIG. 3, a freezer compartment 2, a refrigerator compartment 3, and an ice-making compartment 4 are formed inside a refrigerator body 1, and air cooled by a cooler 5 is sent to each of these compartments by a fan 6. It is now being supplied. An ice making device 7 according to the present invention is provided in the ice making chamber 4, and the ice making device 7 will be described in detail below with reference to FIGS. 1 and 2.

That is, a machine body 8 is provided in the upper front side of the ice making compartment 4, and a motor 9 (FIG. 4) is installed in the machine body 8.
A gear reduction mechanism (not shown) whose driving source is a gear reduction mechanism (see FIG. 4) and a vibration imparting mechanism (see FIG. 4) whose driving source is an electromagnet 10 (see FIG.
(also not shown) are stored. Further, a support frame 11 is provided on the rear side of the body 8, and an ice tray 12 is arranged inside this support frame 11. This ice tray 12 has a rear center portion rotatably supported by the support frame 11 via a shaft 12a, and a front center portion connected to the output shaft of the gear reduction mechanism and the output child of the vibration imparting mechanism. has been done. Then, when the motor 9 rotates in the forward or reverse direction,
The ice tray 12 is inverted so that it is upside down, or returns to its original horizontal position from the inverted position. Also,
When the electromagnet 10 is driven and its iron core reciprocates, the ice tray 12 vibrates back and forth.

Although not shown, a protrusion is provided at the rear of the ice tray 12, and the protrusion comes into contact with the support frame 11 just before the end of the reversing operation. Even after this protrusion comes into contact with the support frame 11, the motor 9 continues to rotate for a while to rotate the front part of the ice tray 12 to the normal inverted position, which causes the ice tray 12 to be twisted. is peeled off from the ice tray 12 and dropped into the ice storage box 13 below and stored there.

Water is supplied to the ice tray 12 by a water supply device 14. This water supply device 14
A water tank 15 disposed in the refrigerator compartment 3, a water tray 16 for receiving water from the water tank 15, and a water tray 1
It consists of a water supply pump 18 that pumps up water in the ice tray 12 through a water supply pipe 17. In order to detect that the water supplied to the ice tray 12 has turned into ice, an ice tray temperature sensor 19 is attached to the ice tray 12 at a position where it can detect the temperature near the water surface. .

On the other hand, a cold air duct 20 is provided in the rear wall of the ice making compartment 4 for guiding cold air sent by the fan 6 into the ice making compartment 4. The outlet 20a of the cold air duct 20 faces diagonally upward, and the cold air discharged from the outlet 20a is blown onto the lower surface of the ice tray 12. In addition, in order to prevent the cold air discharged from the outlet 20a from entering the upper surface of the water stored in the ice tray 12, the ice tray 12 is rotatably provided with a heat insulating cover 21 that covers the upper surface thereof. has been done. A heater 22 for heating the ice tray 12 from above and a heater temperature sensor 23 for detecting the temperature near the heater 22 are provided inside the heat insulating cover 21. The heat insulating cover 21 is supported by the support rod 24 as shown by the two-dot chain line in FIG. 1 when the ice tray 12 is inverted, so that it does not get in the way of ice falling.

The refrigerator equipped with the ice making device 7 constructed as described above is controlled by a microcomputer 25 shown in FIG. Signals from a freezer compartment temperature sensor 26 that detects the temperature inside the freezer compartment 2 and a rapid cooling operation switch 27 are input to the microcomputer 25 . The microcomputer 25 then controls the compressor 29 and the fan motor 6a via the cooling device drive circuit 28 based on these input signals and a control program stored in advance. In this case, normally, the microcomputer 25 starts operating the compressor 29 and the fan motor 6a when the temperature detected by the freezer temperature sensor 26 reaches a predetermined temperature or higher, and stops the operation when the temperature falls below a predetermined temperature. . When the rapid cooling operation is selected, the compressor 29 and the fan motor 6a are continuously operated for 90 hours, for example, regardless of the temperature detected by the freezer compartment temperature sensor 26.

The microcomputer 25 also includes the ice tray temperature sensor 19 and the heater temperature sensor 2.
3 is input, and at the same time, a signal from a switch circuit 30 for detecting the inverted position and horizontal position of the ice tray 12 is input. Based on these input signals and the control program stored in advance, the microcomputer 25 controls the motor 9 of the gear reduction mechanism, the electromagnet 10 of the vibration imparting mechanism, the water supply pump 18, and the heater 22 via the ice making device drive circuit 31. control.

Here, the microcomputer 25 determines the ice making start time and the ice making completion time using the ice tray temperature sensor 1.
The determination is made based on the detected temperature of 9. That is, when water is supplied into the ice tray 12, the ice tray 1
2 is heated by the water (positive temperature) that had been in the refrigerator compartment 3 until then, so its temperature rises, and when ice making is completed, the temperature of the ice tray 12 falls. Therefore, the microcomputer 25 determines that ice making is started when the ice tray temperature sensor 19 detects a predetermined positive temperature, and determines that ice making is completed when a predetermined negative temperature (for example, -13.5°C) is detected. It has come to be judged that. The microcomputer 25 sets the start point of the energization period to the heater 22 as the ice-making start judgment point regardless of the type of operation, and sets the end point of the energization period to the ice making tray temperature sensor 19 during normal cooling operation.
This is the point when a predetermined temperature higher than the ice-making completion detection temperature, for example, -5° C., is detected, and in the case of rapid cooling operation, the ice-making completion is determined.

Note that during the energization period of the heater 22,
The microcomputer 25 controls the temperature of the heater 22 by turning on electricity when the temperature detected by the heater temperature sensor 23 falls below 8°C, and turning off the electricity when it rises above 8°C.

Next, to specifically explain the control contents of the microcomputer 25 regarding ice making, the ice making tray 12
Suppose that it returns to the horizontal position from the inverted position. Then, a return signal is output from the switch circuit 30, which causes the microcomputer 25 to start the water supply pump 18 and supply a predetermined amount of water to the ice tray 12. When the water supply ends, the temperature of the ice tray 12 rises, and the ice tray temperature sensor 19
When the microcomputer 25 detects a predetermined plus temperature, the microcomputer 25 determines that point as the time to start making ice, and energizes the heater 22 and the electromagnet 10 of the vibration imparting mechanism, thereby warming the ice tray 12 from the top side and starting the ice making tray 12. Vibrate back and forth.

On the other hand, the cold air discharged from the outlet 20a of the cold air duct 20 blows against the lower surface of the ice tray 12, cooling the water in the ice tray 12 from the lower surface side. In addition to the cold air cooling the ice tray 12 from the bottom side, the heater 22 warms the ice tray 12 from the top side, so water starts to freeze from the bottom side.

Assume that the compressor 29 is currently in a normal cooling operation state in which the compressor 29 is controlled to be turned on and off based on the temperature detected by the freezer temperature sensor 26. During this normal cooling operation, ice making is started as described above, and when most of the water in the ice tray 12 freezes, leaving only the unfrozen portion on the water surface, the temperature of the ice tray 12 increases. is decreasing. Then, when the ice tray temperature sensor 19 detects -5°C, the microcomputer 25 turns off the heater 22. When the water on the water surface freezes due to the heater 22 being cut off, the temperature of the ice tray 12 rapidly decreases, and when the ice tray temperature sensor 19 detects -13.5°C, the microcomputer 25 It is determined that ice making is complete, and the electromagnet 10 of the vibration imparting mechanism is cut off.

It is also assumed that the rapid cooling operation switch 27 has been operated and the rapid cooling operation is in progress. During this rapid cooling operation, cold air is continuously blown onto the ice tray 12, resulting in a strong cooling state, so that the temperature sensor 19 for the ice tray reaches -5.
The temperature sensor 19 for the ice tray detects -5 degrees Celsius earlier than before, even if not only the water at the surface but also the considerably deeper portions are unfrozen. However, in this embodiment, in the case of rapid cooling operation, even if the ice tray temperature sensor 19 detects -5°C, the microcomputer 25 does not turn off the power to the heater 22 at that point and continues to energize it. maintain the condition. Therefore, during rapid cooling operation, cold air is continuously supplied to the ice tray 12 for 90 minutes.
Even if air is blown onto the air, the heater 22 remains energized, so the problem that the unfrozen surface of the water freezes and there is no place for air bubbles to escape will not occur. When the water is completely frozen, the ice cube tray 12
The temperature of the ice tray temperature sensor 19 drops rapidly, and the ice tray temperature sensor 19 indicates -1.
When the temperature of 3.5° C. is detected, the microcomputer 25 determines that ice making is complete and turns off the electromagnet 10 and heater 22 of the vibration applying mechanism.

Now, as described above, when the ice tray temperature sensor 19 detects -13.5°C and the microcomputer 25 determines that ice making is complete, the microcomputer 25 then starts the motor 9 of the gear reduction mechanism. Rotate in the forward direction to turn the ice cube tray 12 upside down. Just before the end of this reversing operation, the ice tray 12 is twisted, and as a result of this twisting, the ice is peeled off from the ice tray 12 and falls into the ice storage box 13 and stored therein. When the ice tray 12 rotates to the reverse position, the switch circuit 30 outputs a reversal completion signal, and the microcomputer 25 then rotates the motor 9 in the reverse direction to return the ice tray 12 to its original horizontal position. return. When the ice making tray 12 returns to the horizontal position, a return signal is output from the switch circuit 30, so the microcomputer 25 drives the water supply pump 18 to supply water to the ice making tray 12, thus performing the ice making operation described above. repeat. Note that when the ice storage box 13 is filled with ice, a detection switch (not shown) is activated, so that ice making is stopped thereafter.

As described above, in this embodiment, the heater 22 is cut off when the ice tray temperature sensor 19 detects -5° C. during the normal cooling operation, but the ice tray temperature sensor 19 is turned off during the rapid cooling operation. Since the heater 22 continues to be energized until the temperature of -13.5° C. is detected, the total amount of heat generated by the heater 22 from the start to the end of ice making is larger during the rapid cooling operation than during the normal cooling operation. Therefore, during the rapid cooling operation, even if cold air is continuously blown onto the ice tray 12 for 90 minutes, there is no risk that the water surface portion will freeze first, and transparent ice can be reliably produced.

In the above embodiment, during the rapid cooling operation, the heater 22 is cut off at the completion of ice making, but this means that the temperature sensor 19 for the ice tray is at a lower temperature than during the normal cooling operation, for example - The heater 22 may be cut off when the temperature is detected to be 9°C. Even in this case, the total calorific value of the heater 22 from the start to the end of ice making is larger during the rapid cooling operation than during the normal cooling operation, so there is no fear that the water surface portion will freeze first.

[0028]

Effects of the Invention As explained above, according to the present invention, the total calorific value of the heater from the start to the end of ice making is made larger during rapid cooling operation than during normal cooling operation. Even if there are times when cold air is continuously blown onto the ice tray for a long period of time, there is no risk of the water on the surface freezing first, and it is possible to reliably produce clear ice. It has the following effects.

[Brief explanation of the drawing]

[Fig. 1] A longitudinal sectional front view of essential parts showing one embodiment of the present invention.

[Figure 2] Same side view

[Figure 3] Longitudinal side view of the refrigerator with a portion removed

[Figure 4]
Block diagram showing electrical control configuration

[Explanation of symbols]

12 is an ice tray, 14 is a water supply device, 19 is a temperature sensor for the ice tray, 20 is a cold air duct, 21 is a heat insulating cover, 22 is a heater, 23 is a temperature sensor for the heater, 25 is a microcomputer, and 26 is for the same as the example. A temperature sensor, 27 a rapid cooling operation switch, and 29 a compressor.

Claims (1)

[Claims] 1. An ice making device that is built into a refrigerator and makes ice by blowing cold air onto the bottom of an ice tray while heating the top with a heater, the total heat generation amount of the heater from the start of ice making to the completion of ice making. When the rapid cooling operation is selected, which rapidly freezes the food stored in the refrigerator,
A refrigerator ice making device characterized by being larger than during normal cooling operation.