KR860001123Y1 - Damper control circuit of a refrigerator - Google Patents

Abstract

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Description

Damper control circuit of the refrigerator

1 is a circuit diagram of the present invention.

2 is a waveform diagram of each point of the present invention.

3 is a hysteresis characteristic curve appearing in the operating state of the present invention.

* Explanation of symbols on the main parts of the drawings

1: temperature setting part 2: temperature detection part

3: Potentiometer 4, 5: Schmitt trigger circuit

The present invention relates to a damper control circuit for controlling the damper operation displacement for each section according to the temperature change within the set temperature range in the damper control device of the refrigerator.

The damper of the refrigerator serves to control the cold air supplied to the refrigerating chamber in order to maintain the temperature of the refrigerating chamber at a predetermined temperature. In general, in controlling such a damper, the operating range of the damper is adjusted according to the set temperature range. Is determined, and the maximum and minimum points of this adjustment angle are operated at the lower and upper limit temperatures of the actual temperature.

That is, when the refrigerating chamber temperature reaches the upper limit of the set temperature, the damper is placed at the maximum point of the determined control angle (large supply of cold air) .Then, when the refrigerating chamber temperature decreases gradually to reach the lower limit of the set temperature, By keeping the refrigerating chamber temperature again by setting the position to the minimum point of the determined control angle (cold air supply blocking), the refrigerating chamber temperature is maintained in the set temperature range. At ~ 9 ℃, when the internal temperature is -3 ℃, the damper control angle is minimized within the determined range to reduce the cold air supply as much as possible, and when the temperature rises to 9 ℃, the cold air supply is maximized again to lower the internal temperature. It is.

Therefore, the momentary operation of the damper reciprocates the upper and lower positions only by the upper limit temperature (9 ° C) and the lower limit temperature (-3 ° C), so that the damper does not operate when the temperature changes within the set range. It causes a big error, and the instantaneous operating displacement is large, which causes a problem in the life of the damper that operates mechanically.

The present invention was devised in view of the above-mentioned shortcomings, and it divided the upper and lower limit operating range of the damper to reduce the instantaneous damper displacement according to the temperature change, and to detect the rise and fall of the internal temperature instantaneously and the damper In order to control the adjustment angle of, it will be described in detail below.

That is, a differential op amp having two inputs includes a temperature setting unit 1 having a constant voltage op amp op ₁ and a variable resistor VR, and a temperature sensing unit 2 including a temperature sensing sensor TS. op ₂ ) and a differential op amp (op ₃ ) with two inputs, its output (V ₁ ) and the output (V ₂ ) of the potentiometer (3), and at its output (V ₃ ) The deadband adjusting resistor R ₁ and the op amp op ₄ are connected to the base of the motor reverse rotation control switching transistor T ₁ via a Schmitt trigger circuit 4 having hysteresis characteristics. The switching motor (T ₂ ) for controlling the motor forward rotation is connected via a Schmitt trigger circuit ( ₅ ) consisting of a resistor (R ₂ ) and an op amp (op ₅ ) and an inverter op amp (op ₆ ). ₁₎ sharing the collector of the emitter and the transistor (T ₂₎ connected to the Motor (M) of, and the Motor (M) and a potentiometer PO The emitter (3) is configured to interlock connection.

In the operating state of the present invention configured as described above, the resistance value according to the temperature of the temperature sensor TS is minimized at the first room temperature state, that is, the moment the refrigerator is operated, so that the output V ₁ of the op amp op ₂ is Since + Vcc and the output (V ₂ ) of the potentiometer (3) is in the state of + Vcc, the two inputs of the differential amplifier (op ₃ ) are balanced and the output (V ₃ ) becomes "0". The output of op amps (op ₄₎ (V ₄₎ and a drive output (V ₄₎ of the (op ₆₎ all become "0", the transistor (T ₁₎ (T ₂₎ are all so placed in the OFF state fluffs The rotor M is not driven, and thus the potentiometer 3 also does not change in the + Vcc state, so the damper is initially kept completely open.

After the cold air flows into the refrigerating chamber, the refrigerating chamber temperature drops. If the output (V ₁ ) of the op amp (op ₂ ) is set to + Vcc at 9 ° C and -Vcc at -3 ° C, the temperature drops. When the refrigerating chamber temperature reaches 9 ° C, the two inputs of the op amp (op ₃ ) are paralleled, and when it falls below 9 ° C, the output (V ₁ ) of the op amp (op ₂ ) is gradually lowered at + Vcc. and thus the output of the op amp (op ₃₎ (V ₃₎ is also gradually from "0" will drop to the state "."

Then, it is input to the non-inverting terminal (+) of the Schmitt trigger circuit (4) (5) having a dead band, and the outputs of the op amps (op ₄ ) and (op ₅ ) until the dead band width (± V) is reached. V ₄ ) remains “0”, and as soon as the output potential (V ₂ ) of the op amp (op ₃ ) reaches the deadband potential (-Vd) due to the continuous temperature drop, the output (V ₄₎ ) Changes from “0” to -Vcc so that output (V ₄ ) through inverter (op ₆ ) becomes + Vcc state, so transistor T ₁ is turned off and transistor T ₂ is turned on and motor (M) The current through flows from b to a.

At this time, when the motor M rotates forward, the potentiometer 3, which operates in conjunction with the motor M, is displaced in the -Vcc direction, and thus the potential applied to the inverting terminal (-) of the op amp op ₃ . (V ₂ ) drops, which drops sharply compared to the non-inverting (+) potential (V ₁ ) falling to the temperature drop, and at some point, the differential input potentials (V ₁ ) and (V ₂ ) become coincidence In this case, the output of the op amp op ₃ is changed from "-" to "0".

Then, the potential (V ₂ ) applied to the inverting terminal (-) of the op amp (op ₃ ) is stopped because the direction of the potentiometer (3), which is displaced in the -Vcc direction, is also stopped at the same time as the motor (M) which is in the forward rotation is stopped. Becomes the fixed state, and the potential (V ₁ ) applied to the non-inverting terminal (+) drops due to the continuous temperature drop, and the input potential difference of the op amp (op ₃ ) increases again, so the output which was in the "0" state The potential (V ₃ ) is also changed to "-" to turn on the transistor (T ₂ ) in the same manner as before, and the motor (M) is rotated forward again, and the potentiometer (3) is displaced in the -Vcc direction. . That is, when the temperature decreases, the cold air passage is narrowed step by step by repeatedly controlling the damper.

When it continues to reach the lower limit of the temperature set point (-3 ° C), the potential V ₂ of the potentiometer 3 is placed at -Vcc, and the output V ₁ of the op amp op ₂ is also -3. It is set to -Vcc at ° C.

On the other hand, when the refrigerating chamber temperature reaches the lower limit of the set temperature and the damper is completely closed and the refrigerating chamber temperature increases, the potential V ₂ of the potentiometer 3 rises to the temperature rise in the state of -Vcc. The output (V ₃ ) gradually rises from the “0” to the “+” potential as it is input to the differential amplifier (op ₃ ) compared to the output of op ₂ ). At this time changed by the Schmitt trigger circuit (4) (5) dead significantly output (V ₄₎ a + Vcc of op amps (op _{4) (op. 5)} that at the moment "0" beyond the (± Vd) of state inverter ( Since the output (V ₄ ) through op ₆ ) is -Vcc, the transistor (T ₂ ) is in the OFF state.When the transistor (T ₁ ) is turned on so that the current flows from a to b, the motor (M) is reversed. In this case, the potential (V ₂ ) of the potentiometer (3) at the position of -Vcc is displaced in the + Vcc direction, thereby increasing the inverting terminal (-) potential of the op amp (op ₃ ). ₃ ) is gradually decreased in voltage (Vd), but it keeps + Vcc voltage continuously until it becomes “0” due to hysteresis characteristics to maintain the operating state of motor (M) and at the point when input is balanced It becomes "0" and thereby stops the motor M which was rotating in reverse and at the same time the potentiometer 3 which was displaced in the + Vcc direction stops. The. Then, as the temperature rises again, the output (V ₃ ) potential of the op amp (op ₃ ) is switched to “+”, and when the + Vd voltage is reached, the transistor (T ₁ ) is turned on to reverse the motor (M) again. It is to be made.

In the present invention operating in this manner, the temperature rises and falls even when the temperature starts to fall within the set temperature range and the temperature rises before reaching the lower limit, or when the temperature rises and falls before reaching the upper limit. As it controls the damper at the moment, it maintains the temperature of the set reference value with almost no deviation, and also gives the reliability of the life of the damper that is mechanically operated because the momentary operation displacement of the damper is short. Will have.

Claims (1)

The non-inverting terminal (+) of the differential op amp (op ₃ ) and the output of the differential op amp (op ₂ ) and the output of the potentiometer (3) have the temperature setting section (1) and the temperature sensing section (2) as two inputs. Each of the inverting terminals (-) is connected to the output terminal thereof, and the output terminal thereof is connected to the base of the switching transistor T ₁ for reverse driving of the motor via a Schmitt trigger circuit (op ₄ ) having hysteresis characteristics, while the Schmitt trigger circuit (op) ₅ ) and an inverter op ₆ are connected to the base of the motor forward rotation driving transistor T ₂ , but the emitter of the transistor T ₁ and the collector of the transistor T ₂ share a motor ( M), and the damper control circuit of the refrigerator, characterized in that by connecting the motor (M) and the potentiometer (3).