KR890000689B1 - Auto-ice making machine control circuit - Google Patents

Abstract

The control circuit provides for recovering operation of an ice machine after its interruption from power cut-off. Upon return of power supply, the signal from an automatic return signal generator automatically returns ice vessels to their original positions for normal operation and the amount of water in the vessels is sensed to refill the short-age. The circuit is characterized in that a water tank switch for supplying water to ice vessels and an ice switch for removing ices from the vessels are incorporated in an independent circuit separate from the control circuit to improve the functional reliability of the machine.

Description

Control circuit of automatic ice maker

1 is a conventional circuit diagram.

2 is a circuit diagram of the present invention.

3 (a) and 3 (b) are operation equivalent circuit diagrams of the automatic return signal generation circuit portion.

* Explanation of symbols for main parts of the drawings

H: Ice temperature sensing unit I: Ice tray motor driving unit

J: water supply control unit S: ice temperature detection unit

T: Ice Tray Motor Drive Unit U: Water Supply Control Unit

W: Circuit test and operation start signal part V: Water tank presence / absence detection part

X: Ice making amount control unit Y: Automatic return signal generating circuit unit

M ₁ : ice tray driving motor M ₂ : water supply motor

R _TH : Temperature sensing element SW _w : Water tank switch

SW _v : De-icing control switch 10, 20, 30, 40: Comparator

E: Inverter C ₁ , C ₂ , C ₃ , C ₄ : Condenser

The present invention relates to an automatic ice maker widely used in a general business, and in particular, in case of power failure recovery, the ice tray is automatically returned to its original position and water is supplied to the ice tray to automatically control the amount of ice making of the ice tray. It relates to a control circuit of an automatic ice maker which makes it easy to check the nothing.

In the conventional automatic ice maker circuit, when the power is turned on again, especially if the power is turned off for a long time while the ice tray is rotated more than 90 degrees, all the melted water is removed from the ice tray. It had to be returned to its original state or had to be operated separately from the outside. In addition, if the power outage in a state rotated to some extent (60 degrees to 70 degrees) and the time elapsed for a long time, the molten water flowed down and only a small amount left, even if the power was turned on, only a little ice could be frozen.

Accordingly, the present invention solves the conventional problems and improves reliability, and adds a separate circuit for automatically returning the ice making container and also provides a water tank presence detection unit (V) and an ice making control unit (X). By separating from the control unit J and separating the circuit test and operation start signal unit W from the conventional ice temperature detection unit H, the function of the ice maker is improved and the ice tray is automatically defrosted when the power failure returns. It is to be in the working position, water is supplied, and ice making is easily performed.

This will be described based on the accompanying drawings.

In FIG. 1, the circuit of the conventional automatic ice maker has a power supply unit K connected to a temperature sensing unit H including a temperature sensing element and a test switch, and the output signal thereof is connected to the ice tray motor driving unit I. A vessel (not shown) is operated at an ice making position or a position where ice is iced. When the ice making vessel motor driving unit I brings the ice making vessel to its original position, the water supply control unit J connected thereto is operated to supply water to the ice making vessel. The water supply operation is performed, and this operation is made possible by including an ice switch and a tank switch in the water supply control unit (J).

On the other hand, the present invention is to return the ice tray to its original position by the automatic return signal generation circuit of the ice tray to restore the ice maker to normal operation of the ice maker in the recovery of the blackout, and the tank switch to supply water to the ice tray and ice after completion The ice switch to be removed from the ice tray is separated from the ice maker control circuit and configured as a separate circuit to increase the reliability of the ice maker operating performance.

Specifically, referring to FIG. 2, the temperature sensing unit S has a connection point (a) connected to the non-inverting terminal (+) of the comparator 10 via a resistor R ₁ . It is connected to V _c ) and at the same time is connected to the ground via the resistor (R ₂ ), the other branch line is connected to the water tank presence detection unit (V) and the ice making amount control unit (X) described in detail later. On the other hand, the connection point b connected to the inverting terminal (-) of the comparator 10 is connected to the temperature sensing unit R _TH and is grounded through the resistor R ₃ . The output of the comparator 10 is connected to the non-inverting terminal + by the resistor R _{10 while} being connected to the base of the transistor Q ₁ via the resistor R ₁₂ . On the other hand, either side of both sides of the connection point (g) to which the resistor (R ₁₀ ) is connected is connected to the power supply (V _C ) via the resistor (R ₁₁ ) and the other side is connected to the ground via the capacitor (C ₅ ). do. In addition, the emitter of transistor Q ₁ , which takes the output of comparator 10 as an input, is connected to the base of transistor Q ₂ , and its collector is connected to a power supply V _C. Transistor Q ₂ , whose base is connected to the emitter of transistor Q ₁ , has its collector connected to the collector of transistor Q ₁ , and its emitter is connected to switches SW ₁ , SW ₂ and relay Ry. It is connected to one terminal of). In the ice making motor driving unit T, the other terminal of the relay Ry is connected to the anode terminal of the diode D ₁ , and at the same time, it is grounded through the switch SW ₄ (here, the cam switch installed in the motor). have.

The cathode side of the diode D _{1 is} connected to the ice making drive motor M ₁ and to the switch SW ₂ , and the motor M ₁ is connected to the switch SW ₃ .

The connection point C connected to the non-inverting terminal + of the comparator 20 in the rapid control unit U is connected to the contact point A of the switch SW ₁ via the resistor R ₄ and the resistor R ₅ . The contact point D of the switch SW ₁ is connected to the cathode side of the diode D ₁ via, and the connection point d connected to the inverting terminal (-) of the comparator 20 via the resistor R ₁₃ . ) Is connected to the cathode side of the diode (D ₁ ) via the capacitor (C ₁ ).

The output of the comparator 20 is connected to the base of the transistor Q ₃ via the connection point h and the resistor R ₁₄ , and at the connection point h, the switch SW ₁ via the resistor R ₁₅ . Is connected to the contact (A) of the circuit) and is connected to the cathode side of the diode (D ₁ ) via the capacitor (C ₆ ). The transistor Q ₃ has its collector connected to the contact point A of the switch SW ₁ , and its emitter connected to the base of the transistor Q ₄ . Soon as the collector of the transistor (Q ₄₎ is connected to the contact point (A) of the switch (SW ₁₎ via a water supply motor (M ₂₎ and PTH at the same time is connected to the cathode of the diode (D _4), of the transistor (Q ₄₎ The emitter is connected to the cathode side of the diode D ₁ . In addition, the contact B of the switch SW _{1 is} connected to the contact B of the switch SW ₃ .

)에 접속된다. 플립플롭회로(FF₁)의 단자(CK)에는 비교기 (40)의 출력이 접속되는데, 이 비교기(40)에서는 비반전 단자(+)에 접속된 접속점(j)에서 저항(R₁₇)을 경유하여 전원(V_C)에 연결됨과 동시에 충전 콘덴서(C₃)를 경유하여 접지되며, 반전 단자(-)가 접속된 접속점(K)에서 저항(R₈)을 겨유하여 전원(B_C)에 연결됨과 동시에 저항(R₉)을 경유하여 접지된다. 또한 비교기(40)의 출력 단자측의 접속점(1)에서는 저항(R₁₈)을 경유하여 전원(V_C)에 접속됨과 동시에 콘덴서(C₇)를 경유하여 접지되어 있다. 이와 같이 비교기(40)를 중심으로 구성시킨 회로는 정전 복구시 제빙그릇 모타를 이후 상세히 기술되는 바와 같은 작동으로 원래 위치로 복구시키는 작동을 한다.In the automatic return signal generating circuit portion Y configured as the main portion of the present invention, the flip-flop circuit FF ₁ has a switch SW ₁ whose terminal C _P is connected via an inverter E and a capacitor C ₄ . It is connected to the contact point (i) of the contact point (B) of the switch (B) and the contact point (B) of the switch (SW ₃ ). The resistor R ₁₆ is connected through the midpoint between the positive terminal side of the capacitor C ₄ and the input side of the inverter E. The terminal D of the flip-flop circuit FF ₁ has its terminal (

) Is connected. The output of the comparator 40 is connected to the terminal CK of the flip-flop circuit FF ₁ , in which the comparator 40 is connected via the resistor R ₁₇ at the connection point j connected to the non-inverting terminal (+). Is connected to the power supply (V _C ) and grounded via the charging capacitor (C ₃ ), and is connected to the power supply (B _C ) via the resistor (R ₈ ) at the connection point (K) to which the inverting terminal (-) is connected. And grounded via resistor R ₉ at the same time. In addition, at the connection point 1 on the output terminal side of the comparator 40, it is connected to the power supply V _C via a resistor R ₁₈ and is grounded via a capacitor C ₇ . As such, the circuit constructed around the comparator 40 operates to restore the ice tray motor to its original position in an operation as described in detail later, in the event of power failure recovery.

)에서는 다이오드(D₂)의 캐소드에 접속되고 동시에 다이오드(D₂)의 에노드는 온도 감지부(S)의 접속점(b)에 연결된다.Terminal of Flip-Flop Circuit (FF ₁ )

) Is connected to the connection point (b) of the diode (which is connected to the cathode of D ₂₎ at the same time the diode (D ₂₎ lifting enoic temperature sensing portion (S) of.

On the other hand, the circuit test and operation start signal part W having the test switch SW _{5 is} connected to the connection point b of the temperature sensing part S and the intermediate point O of the diode D ₂ .

In the ice making control unit X, the circuit centering on the comparator 30 is configured in the same way as the peripheral circuit of the comparator 40 configured as a part of the automatic return signal generating circuit unit Y. The inverting terminal of the comparator 30 is used. The connection point f connected to (-) is connected to the power supply terminal V _C via a resistor R ₁₉ and to ground via a charging capacitor C ₂ , and an ice making control switch SW _6. Connected to ground via). In addition, the non-inverting terminal (+) of the comparator 30 is connected to the connection point (e) is connected to the power supply terminal (V _C ) via a resistor (R ₆ ) and at the same time connected to ground via a resistor (R ₇ ) have. The output of the comparator 30 is connected to the connection point a of the temperature sensing unit S via the diode D ₃ , and the connection point m on the output side thereof is connected to the power supply terminal V via the resistor R ₂₀ . via a capacitor (C ₈₎ and at the same time connected to the _C) are connected to ground.

The water tank presence detection unit (V) is configured as a water tank switch (SW ₇ ), the anode of the diode (D ₃ ) connected to the connection point (a) of the temperature sensing unit (S) and the output side of the ice making amount control unit (X). It is connected to the connection point n in the middle of.

The present invention configured as described above operates as follows. The temperature sensing element R _TH of the ice temperature sensing unit S is located under the ice making vessel and senses the temperature. When the temperature rises, the resistance decreases, and when the temperature falls, the resistance increases.

The potentials of the connection points (a) and (b) are expressed as follows.

When the ice is sufficiently frozen to lower the temperature, the resistance of the temperature sensing element R _TH increases, and when the potential of the connection point b becomes lower than the potential of the connection point a, the output of the comparator 10 becomes high (H). By driving the transistors Q ₁ and Q ₂ , power is supplied to the ice making motor driver T and the motor M ₁ rotates. That is, the ice tray driving motor (M ₁ ) starts to spill the ice in the ice box.

When the ice tray motor M ₁ starts to operate, the switch SW ₃ switches from the contact point A to the contact point B. That is, when power is supplied to the ice maker motor driving unit T, the ice maker driving motor M ₁ connected with the ice maker starts driving. The ice maker motor M ₁ rotates to drop the iced ice into the ice box. Let's do it. At this time, the switch SW ₄ is turned on by the cam formed at one end of the ice making drive motor M ₁ , and the positions SW ₁ and SW ₂ are moved from the contact point A while the relay Ry is operated. The switch B is switched to the contact point B to rotate the ice making drive motor M ₁ in the reverse direction.

Therefore, when the rotating shaft of the icemaker driving motor M ₁ reaches its original position, the switch SW ₃ is switched back from the contact point B to the contact point A to stop the driving of the ice tray driving motor M ₁ and the water supply controller Power is supplied to (U). That is, the ice tray is in place and waits for the water supplied from the water supply control unit (U).

When the potential of the connection point d becomes lower than the potential of the connection point c at first due to the potential difference between the connection points c and d of FIG. 2 in which the charging time of the capacitor is set, the output of the comparator 20 becomes high (H). ), The transistors Q ₃ and Q ₄ are driven to start water supply, and after a certain time, the potential of the connection point d becomes higher than the potential of the connection point c by charging the capacitor C ₁ . As a result, the output of the comparator 20 is set to the low L state, and the water supply is stopped by turning off the transistors Q ₃ and Q ₄ . That is, the ice tray is filled with water.

After the water supply, the temperature of the temperature sensing element R _TH attached to the ice tray rises, so that the potential of the connection point b becomes higher than the connection point a, so that the output of the comparator 10 is in a low (L) state and the transistor Q ₁ ), (Q ₂ ) is turned off, the power supply of the water supply control unit (U) of the ice making motor driving unit (T) is cut off, the relay (Ry) is turned off, the switch (SW ₄ ) is turned off, In addition, the switches SW ₁ and SW ₂ are switched from the low limit B to the contact A. FIG.

However, the above description is that one cycle is performed without power failure, and the configuration and operation principle of the automatic return signal generation circuit unit Y of the ice making vessel, which is the core of the present invention, are as follows.

The diode (D ₂ ) is connected to the connection point (b) of the ice temperature sensor (S), the negative terminal of the condenser (C ₄ ) is connected to the ice making motor driving unit (T), and the diode (D ₂₎ ) and connects the conventional flip-flop circuit (FF ₁₎ and the inverter (E) between the capacitor (C _4).

In addition, the RC delay circuit is connected to the terminal CK of the flip-flop circuit FF ₁ so as to reset after a predetermined time.

Now, when the power outage is restored and then divided into two descriptions are as follows.

First, when the power is turned on after a power failure while the ice tray does not rotate, the contact of the switch SW ₁ of the ice tray motor driver T is still attached to the contact A, and thus the automatic return signal of the ice tray The equivalent circuit of the generating circuit unit Y is as shown in FIG. 3 (a), and is input to the terminal CP of the flip-flop circuit FF ₁ in a low L state to flip the flip-flop circuit FF ₁ . The output of the terminal Q of is maintained at the initial state of high (H) state and the reverse direction to the diode (D ₂ ), the ice maker operation is kept normal. That is, the output of the comparator 10 goes low (L) state and continues to make ice.

)에 로우(L)상태가 발생되므로 다이오드(D₂)의 순방향으로 접속점(b)의 전위가 로우(L) 상태가 되어 접속점(a) 보다 낮아지므로 비교기(10)의 출력은 정전 이전의 하이(H)상태와 동일하게 되어 회전은 계속 진행된다. 일정시간 후 콘덴서(C₃)의 충전으로 비교기(40)의 입력 접속점(k)보다 접속점(j)의 전위가 높아지면 비교기(40)의 출력은 하이(H)상태가 되어 플립플롭회로 (FF₁)의 단자(CK)에 하이(H)상태가 이럭되어 플립플롭을 리셋트시키고 단자(

)의 출력은 초기 상태인 하이(H)상태가 되어 비교기(10)는 정상동작을 한다. 즉, 일정시간 후 플립플롭회로(FF₁)의 단자(CK)에 하이(H)상태가 입력되므로 모든 것을 리셋트시켜 정전 이전과 동일하게 된다.Second, when the ice making bowl is turned on after the power failure during rotation, the equivalent circuit of the automatic return signal generating circuit unit Y is located at the contact point B of the switch SW ₁ of the ice making motor driving unit T. As shown in (b), the high (H) state is instantaneously input to the terminal CP of the flip-flop circuit FF ₁ , and the flip-flop is set to the terminal (

), A low L state is generated, and thus the potential of the connection point b becomes a low L state in the forward direction of the diode D ₂ , so that the output of the comparator 10 is high before the power failure. It becomes the same as (H) state, and rotation continues. After a certain time, if the potential of the connection point j becomes higher than the input connection point k of the comparator 40 by charging the capacitor C ₃ , the output of the comparator 40 becomes high (H) and the flip-flop circuit FF _The high (H) state is applied to the terminal (CK) of ₁ ) to reset the flip-flop and

) Output becomes the high (H) state of the initial state and the comparator 10 operates normally. That is, since the high (H) state is input to the terminal CK of the flip-flop circuit FF ₁ after a predetermined time, all of them are reset to be the same as before the power failure.

In summary, if the ice of the ice tray is short enough that the ice does not melt, the signal from the comparator 10 is the same as the signal of the high (H) state before correction. If all the ice in the ice tray melts and becomes water, and if the ice tray is tilted and only a little water is left, the temperature of the temperature sensing element (R _TH ) will increase and ice will be made with only a little water. However, in the present invention in which the automatic return signal generating circuit unit (Y) is added, the signal of the high (H) state is always output, so even if there is only a little water, the water can be automatically supplied again from the water supply unit and the ice making becomes conventional. There is an advantage that can freeze much ice.

In particular, if all the water has been removed, it takes a long time for the high (H) signal to come out of the comparator 10, and in order to return to the original state, the recovery test and the operation start signal switch must be driven from the outside to high (H). The signal could be sent out in the) state and the operation could be made.

In the present invention, the water tank presence detection unit (V) and the ice making amount control switch (SW ₆ ) of the ice making amount control unit (X) was configured separately from the conventional water supply control unit (J), the circuit test and operation start signal unit The separate (W) is configured separately from the conventional ice temperature control unit (H) when described as follows.

The water tank presence detection unit (V) detects whether the water tank itself is in the right position to supply water, and if the water tank is not in the proper position, the switch (SW ₇ ) is turned on, so the ice temperature detection unit ( Since the potential of the connection point a of S) is always lower than the connection point b, the output signal from the comparator 10 is always in the low (L) state, so that the entire operation is stopped. In other words, in the prior art, the water supply control unit J is configured as a part, but in the present invention, the whole can be controlled by configuring it separately.

Describing the ice making amount control unit (X) is to detect whether the amount of ice in the ice box is large or small. Conventionally, a part of the water supply control unit (J) is configured, and if the ice box has a lot of ice, the ice switch is a water supply motor (M). ₂ ) was interrupted by stopping the supply of water to the ice tray. However, in the present invention, since the water supply motor is not blocked by installing it separately, water is supplied to the ice making vessel and the ice is blocked in the ice making vessel, thus retaining more ice by the amount of ice held in the ice making vessel than the conventional one. can do.

When water is sufficiently frozen in the ice making bowl, the output of the comparator 10 becomes high (H), thereby rotating the ice making drive motor M ₁ . At this time, the switch (SW ₆ ) is turned off by the cam attached to the rotating side of the ice making bowl, and when the amount of ice is small, the motor (M ₁ ) is turned on and at the same time on. However, when the amount of ice making is large, the switch SW ₆ is not turned on and remains off. In addition, after the water supply is finished, after a predetermined time, the potential of the connection point f becomes higher than the potential of the connection point e of the ice making control unit X by charging the capacitor C ₂ , so that the output of the comparator 30 is in a low (L) state. Since the potential of the connection point (a) of the ice temperature sensing unit (S) is lower than the connection point (b) by the diode (D ₂ ), the output of the comparator 10 continues to be low (L) state motor (M ₁ ) To control the rotation. After that, the amount of ice is reduced and the switch SW ₁ is in the OFF state, and the potential of the connection point f becomes lower than the connection point e so that the output of the comparator 30 becomes the high (H) state and at the same time the potential of the connection point a. Will remain intact and perform the intestinal motion.

The circuit test and operation start signal unit W installed between the ice temperature sensor unit S and the automatic return signal generation circuit unit Y may be used for a long time by the user who has stopped operation for a long time or in a water supply line. It is used to remove foreign substances, it is conventionally composed of a part of the ice temperature sensor (S) to force the signal sent to the high (H) state from the ice temperature sensor (S) when testing such a function For this reason, the test switch was kept pressed, but in the present invention, since the signal is set in the flip-flop circuit FF ₁ of the automatic return signal generation circuit unit Y, it is not necessary to press it for a long time as in the prior art, and only as long as necessary for sending the first signal. Press and release once to see all the features.

As described above, the automatic return signal generating circuit unit Y and the ice making unit control unit X are added to the automatic ice maker circuit, and the circuit test and operation start signal unit W, the water tank presence / absence detection unit V, and the ice making amount adjustment There is a feature that can increase the reliability of the function by installing the switch (SW ₆ ) separately.

Claims (1)

In the control circuit of the ice maker including the temperature sensing unit (S), ice tray motor driving unit (T), and water supply control unit (U), the charging capacitor (C ₂ ) and the amount of ice making up at the input terminal of the comparator (30) According to the potential difference between the connection points f and e connected to the inverting (-) and non-inverting (+) terminals of the comparator 30 by the control switch SW ₆ , the output is connected to the connection point of the temperature sensing unit S ( Water is applied to the intermediate connection point n of the ice making amount control unit X to be applied to A), the connection point a of the temperature sensing unit S, and the diode D ₃ on the output side of the ice making amount control unit X. The water tank presence / absence detection unit (V) provided with the tank clutch (SW ₇ ), the connection point (b) of the temperature detection unit (S), and the terminal (C _P ) of the flip-flop circuit (FF ₁ ) are inverters (E). ) Is connected to the connection point (i) of the ice making motor motor (T) via the resistor (R ₁₆ ) and the charging capacitor (C ₄ ), and the comparator 40 is connected to the terminal (CK) of the flip-flop circuit (FF ₁ ). Configure the peripheral circuit Before the capacitor (C ₃₎ a connection point (k, j) to be in accordance with the potential difference between the input is the output of the comparator 40, the flip-flop circuit automatic return signal of the ice-making bowl so as to set or reset the (FF _1), the by The test switch SW ₅ at the intermediate connection point O of the generation circuit unit Y, the connection point b of the temperature sensing unit S, and the diode D ₂ on the output side of the automatic return signal generation circuit unit Y. Control circuit of the automatic ice maker, characterized in that consisting of a circuit test and operation start signal unit (W) provided.

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