JPH07113501B2 - Operation control device for ice maker - Google Patents

Description

Description: (a) Field of Industrial Application The present invention relates to an operation control device for an ice making machine that controls ice making operation, ice removing operation, and water supply to a water storage tank of the ice making machine.

(B) Conventional technology For example, in Japanese Utility Model Publication No. 60-27889, for example, when an ice making end thermostat detects that plate ice has grown on an ice making member, the ice removing operation by hot gas is started and A water supply control device of an ice maker is shown which supplies water required for ice making operation and water necessary for overflow to a water storage tank.

(C) Problems to be Solved by the Invention In the above-mentioned conventional technique, the ice making water and the overflow water supplied to the water storage tank during the ice removing operation are large in quantity, but the supplied water is only There is a problem that the water is simply supplied as ice making water and water for overflow and is not effectively used. Further, the conventional temperature-sensitive element for detecting the completion of ice making and the completion of ice-breaking are separately provided, so that the cost is high, and there are problems such as deterioration of product quality due to variations in characteristics of the temperature-sensitive element itself. There was also. Therefore, an object of the present invention is to solve the above problems.

(D) Means for Solving the Problems In order to solve the above problems, the present invention allows a plurality of ice-making water stored in a water storage tank to flow down along the surface of a plate body and to be provided in the plate body. By forming ice on the ice making nucleus cooled by heat conduction from the evaporation tube of the refrigeration cycle, after the end of the ice making operation, water is sprinkled with water on the back surface of the ice making nucleus and the evaporation tube, and the ice removing operation is performed, In an operation control device of an ice maker for supplying the sprinkled water to the water storage tank, a temperature sensitive element provided at a predetermined interval facing the ice making nucleus, and ice or the ice in the temperature sensitive element. Ice making completion signal for stopping the ice making operation based on the contact of water flowing on the surface of the ice, and ice falling from the ice making nucleus by the ice removing operation, and the ice in contact with the temperature sensitive element falls. The ice-breaking operation was stopped based on And an ice detection circuit for outputting an ice release signal for starting the water supply to the water storage tank after the ice making completion signal is output, and the water in the water storage tank overflows due to the water supply. An operation control device for an ice maker having a control circuit for terminating water supply to the water storage tank when receiving both signals of a water supply end signal output after a lapse of a predetermined time and the ice removal signal. Is.

(E) Action When ice grows gradually due to the ice making operation, and the temperature sensing element detects the growth of the ice and the ice making operation ends, the ice removing operation by supplying water to the water storage tank is started, and the ice removing operation is started. The used water is supplied to the water storage tank and overflows, and then a water supply stop signal is output from the water supply control circuit,
Further, when the temperature sensing element detects ice-freezing, an ice-freezing signal is output from the ice detecting circuit, and the tap water is output based on whichever of the output of the water supply stop signal and the output of the ice-freezing signal is delayed. The water supply to the water storage tank is stopped, and the ice removing operation and the overflow from the water storage tank due to the water supply are stopped.

(F) Embodiment Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 4 is a schematic vertical sectional view of the ice making machine according to the present invention.
(1) and (1) are plate bodies that are provided substantially in parallel with each other with a space therebetween, and are made of, for example, stainless steel. Further, (2) is a plate body (1), an ice making sprinkler pipe for ice making operation provided at the upper part of (1), and (P) is a water supply pipe, one end of which is connected to a water pipe (not shown). , The other end is an ice spraying pipe (P ₂ )
The water supply pipe (P) is provided with a solenoid valve (40) for controlling the supply of tap water. further,
(3) is a water tank provided below the plates (1) and (1), and (3P) is an overflow pipe. Here, the plate bodies (1), (1) are provided with a plurality of ice-making nuclei (4), (4), ... The ice-making nuclei (4), (4), ... Are tin-plated metal having good thermal conductivity such as copper. Further, the evaporation pipes (5) and (5) constituting the refrigeration cycle are sandwiched by heat conduction in the ice making nuclei (4) and (4) attached to the plate bodies (1) and (1), respectively. . or,
Reference numeral (6) is a water supply pipe extending between the water storage tank (3) and the water sprinkling pipe (2), and the water supply pipe (6) is provided with a water supply pump (7). Further, (S) is a temperature sensitive element such as a thermistor, and the temperature sensitive element (S) is provided with a space from the plate body (1) and facing the ice making nucleus (4).

In the refrigeration cycle, as shown in FIG. 5, the electric compressor (41), the condenser (43) forcibly air-cooled by the blower (42), and the expansion valve (44) provided as a current pressure device. When,
The evaporator (5) is connected in a ring shape.

Further, FIGS. 1 and 2 are schematic operation circuit diagrams of the operation control device of the ice making machine. (10) is a water supply control circuit, (11) is a power supply reset circuit, (12) is a timer circuit, and (13) is It is an ice detection circuit.

Here, the water supply control circuit (10) is an up oscillation circuit (14),
The down oscillation circuit (15), an up / down counter circuit (hereinafter referred to as a counter) (16), a flip-flop circuit (hereinafter referred to as an FF circuit) (17), and the like.
Also, (18) is a float switch, (R ₁ ) is a resistor, (19)
And (20) are a first AND circuit and a first diode connected between the up oscillator circuit (14) and the clock terminal of the counter (16). Further, (21) and (22) are a second AND circuit and a second diode connected between the down oscillation circuit (15) and the clock terminal of the counter (16).
Further, (23) is a first inverter circuit connected to one input terminal of the second AND circuit (21). The output terminal of the counter (16) and the reset terminal of the FF circuit (17) are connected. A second inverter circuit (24) is connected from the output terminal of the FF circuit (17) to the reset terminal of the counter (16).

Furthermore, the power supply reset circuit (11) consists of a series circuit of a capacitor (C ₁ ) and a resistor (R ₂ ), and the midpoint is connected to the input terminal of the FF circuit (17) via the diode (25). .

Further, the timer circuit (12) includes a timer element (26),
(R ₃ ) is a resistor, and the output terminal of the timer element (26) is connected to the input terminal of the FF circuit (17) via a differentiation circuit composed of a capacitor (C ₄ ) and a resistor (R ₈ ).

The ice detection circuit (13) is composed of a temperature sensitive element (S), a constant current diode (30), an amplifier (31), a comparator (32) which is a hysteresis comparator, a fourth inverter circuit (33) and the like. ing. Further, a resistor (R ₄ ) and a second capacitor (C ₂ ) are provided between the midpoint of the constant current diode (30) and the temperature sensitive element (S) and the positive side input terminal of the amplifier (31). It is connected.

The ice detection circuit (13) and the water supply control circuit (10) are connected by terminals (A) and (B), and the fourth inverter circuit (33) of the ice detection circuit (13) is connected to the third capacitor (C ₃ ). And is connected to the input terminal of the FF circuit (17) via the diode (34). Further, the fourth inverter circuit (33) is connected to the timer element (26) via the diode (35) and the resistor (R ₃ ).
It is connected to the reset terminal of. Further, (R ₅ ) is a resistor that forms a differentiating circuit together with the third capacitor (C ₃ ).

Further, (Tr) is a transistor for controlling the energization of the relay coil (RC), the fourth inverter circuit (33) is connected through the diodes (35) (36) and the resistor (R ₆ ) and the FF circuit ( The output terminal of 17) is a transistor via diodes (37), (36) and a resistor (R ₅ ), and the output terminal of the timer element (26) is a transistor via a diode (38) and a resistor (R ₆ ). It is connected to the base of (Tr).

FIG. 3 shows a circuit for controlling the operation of the water supply solenoid valve (40), water pump (7), electric compressor (41), etc.
The solenoid valve (40) is connected to the A side contact (50) of the relay switch (RS) that switches between energization and de-energization of the relay coil (RC), and the water pump (7) and electric compression are connected to the B side contact (51). Machine (41) is connected.

Hereinafter, the operation of the operation control device for the ice making machine of the present invention will be described.

First, the operation of the water supply control circuit (10) will be described. The water supply control circuit (10) operates when a single pulse is input to the input terminal of the FF circuit (17) and its output becomes a high level signal (hereinafter referred to as "H"). That is, when the output of the FF circuit (17) becomes "H", a low level signal (hereinafter referred to as "L") is given to the reset terminal of the counter (16) through the second inverter circuit (24), and the counter ( The reset in 16) is released and operation starts. Here, the water level switch (18) is on when the water in the water storage tank (3) is lower than the predetermined water level, and is off when the water is higher than the predetermined water level, and when the normal water supply control circuit (10) starts its operation for the first day. Only the water tank (3) is empty. Further, the up oscillator circuit (14) and the down oscillator circuit (15) each have an oscillation cycle (T
a) and (Tb) (Tb = nTa, n is a proportional constant and larger than 1), and the output of the up-oscillation circuit (14) is the first
It is given to the AND circuit (19), and the output of the down oscillation circuit (15) is given to the second AND circuit (21). Further, the counter (16) stops its operation when the input of its reset terminal is "H", outputs "L" at its output terminal, and starts its operation when the input of its reset terminal is "L". Then, the counter (16) starts operating, and the up / down input terminal (hereinafter
When the "U / D terminal" is inputting "H", the counter (16) is 1, 2,
Internal addition is sequentially performed as 3, ... Further, when the U / D terminal is inputting "L", the counter (16) calculates from the added number in accordance with the clock terminal input ...
Internal subtraction is sequentially performed as 2, 1, 0. Then, when the number in the counter (16) becomes zero due to the subtraction after the addition is performed once, a single pulse is output from the output terminal. The counter (16) also outputs a single pulse signal from the output terminal when the subtraction is started without performing the internal addition.

Therefore, when the water supply control circuit (10) starts to operate, if the water in the water storage tank (3) is lower than the predetermined water level, the water level switch (18) is turned on to perform water supply and the counter (16). "H" is input to the U / D terminal of, and "H" is also input to the first AND circuit (19) and the first inverter circuit (23). As a result, the counter (16) inputs the output of the up-oscillation circuit (14) to the clock terminal through the first AND circuit (19) and the diode (20), and the counter (1
6) performs internal addition in the cycle (Ta) of the up oscillator circuit (14). At this time, the output terminal does not output to the reset terminal of the FF circuit (17), the FF circuit (17) continuously outputs “H”, the transistor (Tr) is turned on, and the relay coil (RC ) Is energized. And relay switch (RS)
Is closed to the A side contact (50), the solenoid valve (40) is energized and opened, and water is supplied to the water storage tank (3). After that, when the water in the water storage tank (3) reaches a predetermined water level due to the water supply, the water level switch (18) detects the water level and turns off, and the U / D terminal of the counter (16) inputs “L”, First AND circuit (1
9) and the first inverter circuit (23) also input "L". As a result, the counter (16) causes the down oscillator circuit (1
The output of 5) is connected to the second AND circuit (21) and the diode (2
Input to the clock terminal via 2), counter (16)
Performs internal subtraction in the cycle (Tb) of the down oscillator circuit (15), and when the subtraction ends and becomes zero, the output terminal outputs a single pulse signal. During this time, by continuing the water supply to the water storage tank (3), the water in the water storage tank (3) overflows,
Impurities such as scales in the water storage tank are discharged together with the overflowed water. Therefore, the water storage tank (3)
Water supply time, that is, internal time at counter (16) The subtraction time is proportional to the change in the water pressure of the tap water supplied during the operation of the ice maker.

Then, when the reset terminal of the FF circuit (17) inputs the single pulse signal output from the counter (16), the output of the FF circuit (17) switches from "H" to "L". Therefore, the transistor (Tr) is turned off, the relay coil (RC) is de-energized, and the relay switch (RS) is switched from the A side contact (50) to the B side contact (51). For this reason, the solenoid valve (40) is sadly energized and closed, and the water supply to the water storage tank (3) is stopped.

As described above, the water supply control circuit (10) starts operation after inputting a single pulse to the set input terminal of the FF circuit (17) and reaches the predetermined water level (T ₁ ) and reaches the predetermined water level. After that, when the time until the value in the counter (16) becomes zero by subtraction, that is, the overflow time (T ₂ ) elapses, the operation ends.

Further, the ice detection circuit (13) includes a temperature sensing element (S) and an ice making core (4).
It operates by contact with the ice formed on the surface or water flowing on the surface of the ice. Here, a self-heating type thermistor or the like is used for the temperature sensing element (S), a constant current is passed through the constant current diode (30), and the temperature sensing element (S) is slightly heated below the ambient temperature due to self heating. The temperature is very high. When the temperature sensing element (S) is not in contact with ice or water, the temperature of the temperature sensing element (S) is rising due to self-heating, so the resistance value becomes small and the terminal voltage thereof drops. There is. Here, the output of the amplifier (31) is a change in which the change in the terminal voltage of the temperature sensor (S) is delayed by the resistor (R ₄ ) and the capacitor (C ₂ ). The comparator (32) is a hysteresis comparator that compares the positive input voltage with the negative input voltage and outputs "H" or "L".

Therefore, when the ice and the temperature sensitive element (S) are not in contact with each other, the terminal voltage becomes lower due to the temperature rise of the temperature sensitive element (S), so that the negative input voltage of the comparator (32) becomes lower than the positive input voltage. . Therefore, the comparator (32) outputs “H” and the fourth inverter circuit (33) outputs inverted “L”.
Further, as shown in FIGS. 6 and 7, when water or ice flowing on the surface of the ice (52) grown on the temperature sensing element (S) comes into contact with the temperature sensing element (S), the temperature sensing element (S) is It is cooled more rapidly than self-heating. Therefore, the resistance of the temperature sensitive element (S) becomes large and the terminal voltage rises. At this time, the output of the amplifier (31) rises later than the rise of the terminal voltage, and the negative input voltage of the comparator (32) becomes larger than the positive input voltage. Therefore, the output of the comparator (32) is “L”. The output of the fourth inverter circuit (33) becomes "H" which is the ice making completion signal.

Further, in the timer circuit (12), for example, when the ice detection circuit (13) outputs "H" and "H" is input to the reset terminal of the timer element (26), the timer operation is stopped and the reset terminal is reset. When "L" is input to, the timer element (26) starts its operation, outputs "L" during the preset ice making time, and thereafter outputs "H".

Further, the power supply reset circuit (11) outputs a single pulse by the differentiation circuit of the capacitor (C ₁ ) and the resistor (R ₂ ), and the set input terminal of the FF circuit (17) inputs this single pulse.

The operation after the power of the ice machine is turned on will be described below. When the power is turned on and the control circuit is energized, the power reset circuit (11) applies a single pulse to the input terminal of the FF circuit (17), and the FF circuit (17) outputs "H".
As a result, “H” is given to the base of the transistor (Tr) through the diodes (37), (36) and the resistor (R ₆ ), the relay coil (RC) is energized, and the relay switch (RS) is turned on. The A-side contact (50) is closed, the solenoid valve (40) is energized and opened, and water supply to the water storage tank (3) is started. At this time, the water supply control circuit (10) operates in the same manner as in the above-mentioned operation, and the water supply time is the time (T ₁ ) until the water level of the water storage tank (3) reaches a predetermined water level and the overflow time. It becomes the sum of (T ₂ ). At this time, since the timer element (26) of the timer circuit (12) inputs “H” from the FF circuit (17) to the reset terminal, the timer circuit (1
The operation of 2) is stopped and “L” is output.

When the counter (16) outputs a single pulse signal as time passes along with water supply to the water storage tank (3), the FF circuit (17) outputs "L" instead of "H" and the transistor (Tr) is turned off. To do. Therefore, the relay coil (RC) is de-energized, the relay switch (RS) is switched to the B-side contact (51), the solenoid valve (40) is de-energized and closed to stop the water supply. Further, the water supply pump (7) and the electric compressor (41) are energized to start the operation, and the ice making operation is started. At the same time, since the output of the timer element (26) of the timer circuit (12) outputs the "L" level signal, the ice making operation is started as described above. Further, the timer element (26) inputs "L" instead of "H" from the FF circuit (17) to the reset terminal and starts the operation.

By starting the operation of the water pump (7), the water in the water storage tank (3) falls from above the plate body (1) and is transmitted downward on the surface of this plate body (1). Further, the refrigerant is circulated in the refrigerant circuit by the operation of the electric compressor (41) to cool the ice making nuclei (4), and water flowing on the surface of the plate body (1) around these ice making nuclei (4). Freezes and gradually grows ice. Then, when the water flowing on the surface of the grown ice or the grown ice comes into contact with the temperature sensitive element (S) and the temperature sensitive element (S) is rapidly cooled, the ice detecting circuit (13) causes the above description. The same operation is performed and “H” is output instead of “L”. The "H" output diode (35), (36) and a resistor (R ₆₎
Is given to the base of the transistor (Tr) via the transistor (Tr) and the relay switch (RS) is switched from the B side contact (51) to the A side contact (50). Therefore,
The water supply pump (7) and the electric compressor (41) are both de-energized and stopped operating, and the solenoid valve (40) is opened so that the water spray pipe (P ₂ ) for deicing is connected to the plate body (1). ), Tap water is sprinkled in the space (1a) between (1), and the plate bodies (1), (1), the evaporation pipe (5) and the ice making core (4) are warmed by tap water to perform deicing operation. Be seen.

Further, when the output of the ice detection circuit (13) is in place "H" to "L", the reset input of the capacitor from the differentiating circuit by a (C ₃₎ and a resistor (R _5), a single pulse is FF circuit (17) Given to the terminal, the FF circuit (17) outputs “H” instead of “L”. This "H" output is given to the reset terminal of the timer element (26), whereby the timer element (26) is reset, and further becomes "L" via the second inverter circuit (24), and the counter (16) Reset terminal is "L"
Enter. Then, the counter (16) starts operating, and the counter (16) performs internal addition and internal subtraction based on the outputs of the up oscillator circuit (14) and the down oscillator circuit (15) as described above. Meanwhile, the water storage tank (3) is supplied with water. Here, the internal addition becomes zero by the internal subtraction in the counter (16), and when the water supply time set in the water supply control circuit (10) elapses, the counter (16) outputs a single pulse signal. When the reset terminal of the FF circuit (17) inputs this single pulse signal, the output of the FF circuit (17) switches from "H" to "L".

When the FF circuit (17) outputs "L", "H" is given to the reset terminal of the counter (16) through the second inverter circuit (24), and the counter (16) stops internal addition and internal subtraction. To do. And before this, ice nuclei (4)
When the ice formed on the surface of the temperature sensor falls and is separated from the temperature sensitive element (S), the temperature of the temperature sensitive element (S) rises in a short time due to self-heating, the terminal voltage decreases, and Detection circuit (13)
Outputs "L" instead of "H". Therefore, at this time, when the FF circuit (17) outputs "L", "L" is given to the base of the transistor (Tr), the relay switch (RS) switches to the B side contact (51), and the solenoid valve (40) is de-energized and closed. For this reason, the water spraying from the ice spraying pipe (P ₂ ) is stopped and the ice removing operation ends.

Further, when the water supply time set in the water supply control circuit (10) has elapsed, the ice formed in the ice making nucleus (4) has not yet fallen, and the temperature sensing element (S) is in contact with the ice. The ice detection circuit (13) continuously outputs the "H" signal. Therefore, the transistor (Tr) is on, and the ice removal operation continues. After that, when the ice falls due to the ice removing operation, the temperature of the temperature sensitive element (S) rises and the terminal voltage drops, and the ice detection circuit (13) outputs "L" instead of "H". As a result, the transistor (Tr) is turned off, the relay switch (RS) is switched to the B-side contact (51), and the solenoid valve (40) is de-energized and closed. For this reason, water spraying from the ice spraying water sprinkling pipe (P ₂ ) is stopped and the ice removing operation ends.

When the relay switch (RS) is switched to the B-side contact (51), the water pump (7) and the voltage compressor (41) are energized, respectively, and the water tank (3) is operated by the operation of the water pump (7).
The water falls from above the plate body (1) and travels down the surface of the plate body (1). Further, the refrigerant is circulated through the cooling pipe (5) by the operation of the electric compressor (41) to cool the ice making nuclei (4) ... And ice is gradually formed around these ice making nuclei (4). When the ice flowing on the surface of the grown ice or the surface of the ice comes into contact with the temperature sensitive element (S) and the temperature sensitive element (S) is rapidly cooled, the ice detection circuit (13) is the same as above. To output "H" instead of "L". For this reason,
The transistor (Tr) is turned on and the relay switch (RS) is switched from the B side contact (51) to the A side contact (50), and the ice making operation is finished and the ice removing operation is started in the same manner as the above operation. .

After that, during the operation of the ice making machine, the ice making operation and the ice removing operation are alternately repeated in the same manner as the above description of operation, and ice is formed.

Therefore, the water supply to the water storage tank (3) is performed by the plate body (1),
Water can be sprayed on the back surface of (1) and used for ice removal operation, and by the operation of the water supply control circuit (10), in proportion to the time until the water level of the water storage tank (3) reaches a predetermined water level,
The water supply time after reaching the predetermined water level is determined, and when the water pressure during water supply changes, the water supply time after reaching the predetermined water level also changes accordingly, so the water storage tank (3)
The overflow of water can be maintained substantially constant, and as a result, the impurities in the water storage tank (3) can be discharged by the overflow without being affected by the change in water pressure during water supply, and the water supply Waste can be prevented.
Further, when the ice making operation is switched to the ice removing operation, the ice removing operation is performed based on the delay between the detection of the ice removing by the temperature sensing element (S) and the passage of the water supply time by the operation of the water supply control circuit (10). Since the water supply at the time is stopped, even if the water supply time by the operation of the water supply control circuit (10) elapses before the ice removal operation ends,
Solenoid valve (4
0) is energized and open, tap water is the plate (1),
(1) The water can be sprinkled during the time period and the ice can be deiced by the deicing operation. Further, even when ice removal is performed before the water supply time by the operation of the water supply control circuit (10) elapses, the solenoid valve (40) is energized and opened during the water supply time, and the water storage tank (3 ), The water overflows and impurities such as scales mixed in the water in the water storage tank (3) can be discharged together with the overflowed water, and as a result, the water in the water storage tank (3) is always clean. Can be kept at

It should be noted that when the water supply control circuit (10) is preset with a sufficient water supply time for the water in the water storage tank (3) to overflow, and when deicing is performed before the water supply time elapses. Also, when the water supply time elapses and the water in the water storage tank (3) overflows, impurities are discharged, and then water supply is stopped by the operation of the water supply control circuit (10). Can be obtained.

(G) Effect of the Invention Since the present invention is the operation control device for the ice making machine configured as described above, when the ice making operation is switched to the ice removing operation and water is being supplied to the water storage tank, the temperature sensing element is provided. When ice-breaking is detected by the ice-breaker and the ice-breaking signal is output from the ice detecting circuit, and when the water supply control circuit operates to output the water-supply end signal, the water supply to the water storage tank is stopped. For both ice operation and overflow from the water storage tank,
Even if there is a time difference at the end of each, water can be reliably supplied regardless of the time difference.

In addition, when water is supplied to the water storage tank, it surely overflows, so impurities such as scales mixed in the water in the water storage tank can be reliably discharged, and the water in the water storage tank is always clean. Can be kept at Therefore, the ice made is always clean, and it is possible to improve hygiene.

Furthermore, since the completion of ice making and the completion of ice removal are detected by one temperature sensitive element, it is possible to reduce the cost, and the quality of the product deteriorates due to the variation in the characteristics of the temperature sensitive element itself. Can also be avoided.

[Brief description of drawings]

1 to 7 show an embodiment of the present invention, FIGS. 1 and 2 are schematic circuit diagrams of an operation control device of an ice making machine, FIG. 3 is an operation circuit diagram of an ice making machine, and FIG. Is a schematic vertical sectional view of an ice making machine, FIG. 5 is a schematic view of a refrigerating cycle, and FIGS. 6 and 7 are enlarged views of essential parts of the schematic vertical sectional view shown in FIG. (1) ... plate, (4) ... ice making core, (5) ... evaporation tube, (S) ... temperature sensing element, (10) ... water supply control circuit,
(13) …… Ice detection circuit.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Ryozo Iizuka 180 Sakata, Odaizumi-cho, Gunma-gun Ogura-gun, Toyokyosan Denki Co., Ltd. (56) References

Claims (1)

[Claims] 1. Ice-making nuclei stored in a water storage tank are made to flow down along the surface of a plate, and a plurality of ice-making nuclei are provided on the plate and cooled by heat conduction from an evaporation pipe of a refrigeration cycle. After the ice making operation is completed, water is sprinkled on the back surface of the ice making nucleus and the evaporation pipe to perform the ice removing operation,
In an operation control device of an ice maker for supplying the sprinkled water to the water storage tank, a temperature sensitive element provided at a predetermined interval facing the ice making nucleus, and ice or the ice in the temperature sensitive element. Ice making completion signal for stopping the ice making operation based on the contact of water flowing on the surface of the ice, and ice falling from the ice making nucleus by the ice removing operation, and the ice in contact with the temperature sensitive element falls. With an ice detection circuit that outputs an ice removal signal for stopping the ice removal operation based on the above, starting water supply to the water storage tank after the ice making completion signal is output, and by the water supply, A control circuit for terminating the water supply to the water storage tank when receiving both the water supply end signal output after a predetermined time sufficient for the water in the water storage tank to overflow and the ice removal signal is provided. Operation controller of the ice making machine, characterized in that the.