KR880002462Y1 - Coin-freed apparatus for controlling dispensing of ice - Google Patents

Abstract

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Description

Ice generation control circuit of cold beverage vending machine

A circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

1: water level and ice detector 2: Schmitt trigger circuit

3: amplification part 4: rectification part

5: constant voltage circuit 6: differential amplifier

7: Amplifier and Relay Control Circuit OP AMP: Differential Amplifier

LY ₁ : Lead Relay LY ₂ : DC Relay

S ₁ , S ₂ , S ₃ : Water level and ice detection rod

The present invention relates to a circuit for controlling ice generation in a water tank which is essential for the supply of cold drink in a cold beverage vending machine, and in particular, to ensure that a certain amount of ice is always produced in the water tank. The present invention relates to an ice making control circuit that automatically detects when a certain amount of ice is consumed in order to enable a continuous supply and automatically controls a cooling system of a cold beverage vending machine so that the ice is regenerated.

In general, in forming an ice making control circuit for supplying a cold beverage in a cold beverage vending machine, not only the ice sensing rod detects water or ice in the tank, but also the water or ice detected by the sensing rod itself. Depending on the difference in resistance value, a method may be used in which the control circuit itself is turned on to generate ice or to short-circuit to stop ice formation.

In the conventional cold beverage vending machine, in forming the ice production control circuit as described above, two ice level sensing rods for detecting the amount of ice and two separate level sensing rods for detecting the water level are used. And the ice level sensing unit, the configuration was not only very complicated, but also the circuit configuration using only two ice level sensing rods, so that ice began to be generated without any ice in the tank. After the maximum amount of ice was produced, it could not produce ice at an intermediate stage from reaching the state where the ice was almost consumed. Therefore, the required amount of ice could not always be produced in the tank, and therefore, there was a drawback that it was extremely difficult to supply a large amount of the cold beverage produced by the ice in the tank at a time or continuously.

The purpose of the present invention is to solve this drawback, by using only three sensing rods without using a separate water level sensing rods to allow them to detect the water level and the amount of ice at the same time, the maximum amount of ice in the tank After it is produced, a certain stage before all the amount of ice is consumed, that is, to detect it in a state where a certain amount remains, and generate ice again, so that a certain amount of ice is always generated in the tank so that a large amount of cold beverage is temporarily In addition to being able to supply as well as continuous supply, the circuit configuration is simple to contribute to cost reduction and to provide a cold beverage vending machine that greatly improved the reliability of the product. When the ice production control circuit of the cold beverage vending machine according to the present invention as described above is first schematically described as follows.

First, referring to the schematic configuration of the ice making control circuit according to the present invention, three water levels and ice detection rods (S ₁ ), (S ₂ ), (S ₃ ) are installed in the tank such as water or ice At the same time, the water level and ice detection rods (S ₁ ) and (S ₂ ) or (S ₃ ) and the lead relay (LY ₁ ) of the amplification unit and the relay control circuit unit (7) are detected at (S ₂ ). It is configured to determine the current applied from the power source T ₁ (T ₂ ) to the Schmitt trigger circuit unit 2 according to the resistance value of air, water or ice itself, which is present between the connectable (S ₃ ). Constant amplitude only when the input voltage exceeds a certain amount according to the level of the input voltage determined by the level and the ice detector 1 and the level of the voltage applied to the base of the transistor Q ₇ . Schmidt tree which generates this output voltage and supplies it to the amplifier 3 An amplifying section 3, in which the output circuits of the nearly circuit section 2 and the Schmitt trigger circuit section 2 supply signals to the "+" input terminal of the differential amplifier OP AMP according to a signal coming from the collector of the transistor Q ₈ , and The rectifier 4 rectifies the AC voltage input from the power source T ₁ (T ₂ ) into a DC voltage and a constant voltage which forms a reference voltage so that a constant voltage is always input to the input terminal of the differential amplifier OP AMP. The voltages applied from the circuit section 5 and the constant voltage circuit section 5 are supplied to the reference voltages almost uniformly by the resistors R ₄ and R ₅ , respectively, and supplied from the power supply T ₁ and T ₂ . A differential amplifier (6) for supplying a signal of a high or low state to the amplification unit and the relay control circuit unit (7) by receiving the changed signal as a comparison voltage while passing through the water level and the ice detection unit (1), and this differential an amplification section (6) lead relay (LY ₁₎ in accordance with the signal applied from the DC Lee To drive the two (LY ₂₎ by operating the water and ice detection rod (S ₂₎ and (S ₃₎ switch (SW) the ON, OFF, as the cooling of the vending machine and cold drinks device that (not shown) between the It is comprised as the amplification part and the relay control circuit part 7 which control ice formation.

This invention is described in more detail according to the drawings as follows.

First, look at the configuration of the water level and the ice detector (1) three water level and the ice detection rod (S ₁ ) (S ₂ ) (S ₃ ) toward the direction of ice formation (S ₂ ), (S ₃ ), ( S ₁ ) are arranged in sequence, the water level and the ice detection rod (S ₁ ) is connected to the AC power source (T ₁ ) via the resistor (S ₁₃ ), (S ₂ ) is a condenser (C ₇ ) It is connected to the AC power (T ₂ ) that is grounded via the (S ₃ ) is a switch (SW) driven by the operation of the lead relay (LY ₁ ) of the amplifier and the relay control circuit (7) Can be connected to (S ₂ ) through. On the other hand, the power source T ₁ is connected to the resistor R ₁₄ of the Schmitt trigger circuit unit 2 through the resistor R ₁₃ and the diode D ₈ . On the other hand, in the Schmitt trigger circuit part 2, the resistor R ₁₄ connected to the diode D ₈ of the water level and the ice detector 1 has transistors Q ₇ , (Q ₈ ) and resistor R ₁₇ (R _{18) (R 19) (R} 20) (R 23) an emitter resistor (R ₂₃₎ of the Schmidt and connected to the base terminal of the input transistor (Q ₇₎ of the trigger circuit, the transistor (Q ₈₎ is configured as such It is connected to the variable resistor R ₂₅ which is connected to the ground, and the capacitor C ₈ connected between the diode D ₈ and the resistor R ₁₄ is grounded, and the resistor R ₁₄ and the transistor ( One side of the resistor (R ₁₆ ) connected between the bases of Q ₇ ) is grounded by being connected to a diode (D ₉ ) which serves to reduce noise, and the other side thereof is connected to the resistor (R ₁₅ ). .

Next to the collector of the amplifier unit 3 is provided with an output terminal of the transistor (Q ₈₎ of the Schmitt trigger circuit is connected to the base of the transistor (Q _9), between the base of the transistor (Q ₈₎ the collector and the transistor (Q ₉₎ of Two resistors R ₂₁ and R ₂₂ are connected in parallel with each other, and a diode D ₁₀ is connected between the collector of transistor Q ₈ and the resistor R ₂₂ to reduce noise. have. On the other hand, a capacitor (C ₃ ) (C ₄ ) is connected between the resistor (R ₂₁ ) (R ₂₂ ) and the base of the transistor (Q ₉ ), respectively, and a diode (D ₁₁ ) is connected to the capacitor (C ₄ ) in parallel. One side is grounded. In addition, the collectors of the capacitors C ₃ (C ₄ ), resistors R ₁₅ (R ₁₇ ) (R ₂₀ ) and transistors Q ₉ are connected to the Schmitt trigger circuit section 2 from the rectifier section 4. Each is connected to (J). The emitter of the transistor Q ₉ is connected to the "+" input terminal of the differential amplifier OP AMP via the diode D ₁₂ and the resistor R ₂₄ .

In the rectifying section 4, an AC power source T ₃ (T ₄ ) is connected to an input terminal A of the rectifying circuit composed of four diodes D ₀ to D ₃ (B), and one output terminal of the rectifying circuit. (A ') is grounded and the other output terminal (B') is connected to the input terminal of the constant voltage circuit section (5) via a resistor (R ₁ ). And the diode that is, the respective ground between the rectifier output (B ') and the resistor (R _1), the capacitor (C ₁₎ is grounded be connected and, a resistance (R ₁₎ and the input terminal of the constant voltage circuit (5) ( D ₁ ) and condenser (C ₂ ) are connected.

The base of the constant-voltage circuit portion 5 is provided, and the base and collector of the transistor (Q ₁₎ emitter and the transistor (Q ₂₎ to the collector of connected, respectively, the transistor (Q ₁₎ is connected to ground via a diode (D ₃₎ The resistor R ₂ connected between the collector of the transistors Q ₁ and Q ₂ and the output terminal of the rectifier 4 is grounded via the diode D ₂ , and the resistor R ₂ and the diode D are connected to each other. _The resistor R ₃ connected between ₂ ) is connected between the base of the transistor Q ₁ and the diode D ₃ .

The output terminal of the constant voltage circuit section 5 is connected to the differential amplifier for adding a constant voltage to the differential amplifier and is connected to the collector of the transistor Q ₃ in the amplifier section and the relay control circuit section 7. . A differential amplifying part 6 of the differential amplifier (OP AMP) "-" voltage is input coming from the constant voltage circuit (5) receiving the voltage division by two resistors (R ₄₎ (R _5), its " The force stage is configured to receive a signal from the amplifier 3 and supply the signal to the amplifier and the relay control circuit 7.

The voltage entering the "-" input terminal becomes the reference voltage, and the voltage entering the "+" input terminal becomes the comparison voltage.

In the amplifier section and the relay control circuit section 7, the resistor R ₆ connected to the output terminal of the differential amplifier is connected to the base of the transistor Q ₃ , and the resistor R ₆ and the base of the transistor Q _{3 are} connected. A resistor (R ₈ ) is connected between them and is grounded. The emitter of transistor Q ₃ is grounded and the collector is connected to the base of resistor R ₇ and transistor Q ₄ , respectively, and between the collector of transistor Q ₄ and the base of transistor Q ₅ . (R ₉ ) is connected and grounded. The emitter of transistor Q is grounded and the collector is connected to the base of diode D ₄ and lead relay LY ₁ and transistor Q ₅ , respectively, and the collector and transistor Q of transistor Q ₄ . _The diode D ₄ and the resistor R ₁₀ are connected between the bases of ₄ ). The emitter of transistor Q ₅ is grounded and the collector is connected to the base of resistor R ₁₁ and transistor Q ₆ , respectively, and between the collector of transistor Q ₅ and the base of transistor Q ₆ is a diode. (D ₄ ) and resistor (R ₁₂ ) are connected. The emitter of the transistor Q ₆ is grounded, a diode D ₇ is connected to the collector, and a DC relay LY ₂ is provided in parallel with the diode D ₇ .

The diode D ₄ , the lead relay LY ₁ , and the resistor R ₁₁ are connected to one point to which the capacitor C ₂ of the rectifier 4 is connected, and the diode D ₇ and the DC relay ( LY ₂ ) is connected to one point to which the condenser C ₁ of the rectifier 4 is connected.

In the circuit according to the present invention, D ₁ , D ₂ , D ₃ , and D ₆ are constant voltage diodes, C ₁ to C ₄ are electrolytic capacitors, and C ₅ and C ₆ are ceramic capacitors.

Referring to the effect of the present invention configured as described above are as follows.

First, the basic operation relationship of the ice generation control circuit according to the present invention will be described as follows.

AC power applied from the power source T ₃ (T ₄ ) is rectified through the rectifying unit 4 and constant at a predetermined voltage value in the constant voltage circuit unit ₅ , and then distributed by R ₄ and R ₅ to be differential amplifiers. The reference voltage input to the "-" input terminal of the (OP AMP) and the AC power applied from the power supply T ₁ (T ₂ ) to the Schmitt trigger circuit section 2 depend on the state of the contents in the tank. (S ₁ ) (S ₂ ) (S ₃ ) is changed due to the change in the resistance value sensed, and then through the Schmitt trigger circuit (2) and the amplifier (3), the "+" input terminal of the differential amplifier (OP AMP) The switch SW and the cooling device are respectively controlled by a read relay LY ₁ and a DC relay LY ₂ operated by an output signal from the output of the differential amplifier according to the state of the comparison voltage input to the power stage. To drive ice control. As described above, the operation relationship of the circuit according to the present invention, which is controlled according to the constant reference voltage applied to the differential amplifier (OP AMP) and the comparison voltage in which the contents in the tank changes according to the state, is explained in more detail as follows. .

First, the AC voltage from the AC power source T ₃ (T ₄ ) is converted into direct current through the rectifying circuit and the capacitor C ₁ , and then applied to the input terminal of the constant voltage circuit part 5, and the constant voltage circuit part 5 ) Is applied from the output terminal of the constant voltage circuit section 5 by the resistor R ₄ and the resistor R ₅ almost uniformly, and then applied as a reference voltage to the "-" input terminal of the differential amplifier (OP AMP). This is true in either case.

First, if there is no water or ice in the tank, the AC voltage from the AC power source (T ₁ ) (T ₂ ) passes through the resistor (R ₁₃ ) and is rectified through the diode (D ₈ ) and through the condenser (C ₆ ). The filter is converted into a DC voltage and then input through the resistor R ₁₄ to the base of the transistor Q ₇ , which is an input terminal of the Schmitt trigger circuit.

At this time, since the resistance value between the water level and the ice detection rod (S ₁ ) (S ₂ ) is almost infinite, the voltage applied to the base of the transistor (Q ₃ ) of the DC voltage to operate the transistor (Q ₇ ) Enough to be sufficient, transistor Q ₇ is turned on when the voltage is applied to transistor Q ₇ .

When the transistor Q ₇ is ON, the voltage supplied at the predetermined point J through the rectifier 4 flows through the transistor Q ₇ through the resistor R ₁₇ and flows to the resistor R ₂₅ . The transistor Q ₈ is turned off because no voltage is applied to the base thereof. Therefore, transistor Q ₉ is turned on by the voltage across the collector of transistor Q ₈ and thereby the current flowing to the emitter of transistor Q ₉ is differential through diode D ₁₂ and resistor R ₂₄ . The voltage is applied to the "+" input terminal of the amplifier OP AMP.

At this time, since the voltage coming from the output terminal of the differential amplifier OP AMP is HIGH, the transistor Q ₃ is turned on, the transistor Q ₄ is turned off, and the read relay LY ₁ is turned off. Reed relay (LY ₁₎ is in the OFF state when the water level and ice detection rod (S ₂₎ and water, and ice detection rod (S ₃₎ is a diode (D ₅₎ to be cut off and passed to the base of the transistor (Q ₅₎ to each other and The transistor Q ₅ is turned on by the voltage caused by the current flowing through the resistor R ₁₀ .

Transistor (Q ₅₎ is due to a voltage when the diode (D ₆₎ and a resistor (R ₁₂₎ in the ON state is not applied to DC relay (LY ₂₎ is OFF, because DC relay cooling device connected to the (LY ₂₎ is It will not run and will not generate ice. If there is no water or ice in the tank like this, the temperature in the tank will be above a certain temperature, which will be detected by a separate temperature sensor (not shown). The lamp is designed to be driven separately.

Secondly, if there is no water in the tank and there is no ice, the AC voltage from the AC power source (T ₁ ) (T ₂ ) is the resistance value of the resistance (R ₁₃ ) and the water level and the ice detection rod (S ₁ ) and the water level and It is distributed by the resistance value between the ice detection rods S ₂ and is input to the base through the diode D ₈ and the resistor R ₁₄ to the transistor Q ₇ , which is an input terminal of the Schmitt trigger circuit.

In this case, the resistance value of the resistor (R ₁₃₎ water level, and ice detection rod (S ₁₎ (S ₂₎ Since the water between larger than the resistance value of the voltage applied to the base of the transistor (Q ₇₎ transistors (Q ₇ ) Cannot be turned on. I.e. water and ice detection rod (S ₁₎ (S ₂₎ owing to the difference between the resistance value of the resistance value and the resistance (R ₁₃₎ between the smaller the voltage applied to the base of the transistor (Q ₇₎ transistors (Q ₇ ) Turns off. Therefore, the voltage coming out of the collector of transistor Q _{8 which} is the output terminal of the Schmitt trigger circuit becomes LOW. On the other hand, since the output from the collector of the transistor Q _{8 in the} LOW state is applied to the base of the transistor Q ₉ by fixing the resistor R ₂₁ , the transistor Q ₉ is also turned OFF.

Therefore, the output of the "+" input terminal of the differential amplifier, so high voltage is applied to the differential amplifier (OP AMP) is due, and a LOW state voltage of the LOW state is applied to the base of the transistor (Q _3), a transistor (Q ₃ ) Is turned OFF, and the transistor Q ₄ is turned on to operate the reed relay LY ₁ , and the level and ice detection rods S ₂ and the level and ice detection rods connected to the reed relay LY ₁ are operated. The switch between (S ₃ ) is turned on and these two levels and the ice detection rods (S ₂ ) and (S ₃ ) are turned on. In this case, in the ice generation control circuit according to the present invention, instead of the resistance value between the water level and the ice detection rods (S ₁ ) and (S ₂ ), the resistance value between the water level and the ice detection rods (S ₁ ) and (S ₃ ) is applied. Will be.

On the other hand, when the low voltage is applied to the base of the transistor Q ₅ via the diode D ₅ and the resistor R ₁₀ , the transistor Q ₅ is turned off, so that the voltage of the collector is the diode D _6. ) and when the resistance (R ₁₂₎ applied to the base of the transistor (Q ₆₎ through the transistor (Q ₆₎ is so set to oN state DC relay (LY ₂₎ is oN, the cooling unit is activated to start the ice generating will be.

In this way, the cooling device is operated to continue ice production toward the direction of ice formation, passing through the water level and the ice detection rods (S ₂ ) and the water level and the ice detection rods (S ₃ ) to near the water level and the ice detection rods (S ₁ ). Ice production continues. However, since the resistance value of ice is greater than the resistance value of water, if the ice generation continues in this way, the resistance value between the water level and the ice detection rods S ₁ and S ₃ is gradually increased.

Third, the state where the maximum amount of ice is produced is as follows.

In this way, if the resistance value between the water level and the ice detection rod (S ₁ ) (S ₃ ) increases above a certain value, the voltage from the AC voltage (T ₁ ) (T ₂ ) is the resistance value of the resistor (R ₁₃ ). A voltage sufficient to turn on the transistor Q ₇ is applied to the base of the transistor Q ₇ by being distributed by the water level and the resistance value between the ice detection rods S ₁ and S ₃ .

Therefore, the output of the Schmitt trigger circuit section 2 becomes HIGH, the transistor Q ₉ is turned on, and a constant voltage larger than the reference voltage is applied to the "+" input terminal of the differential amplifier OP AMP. Therefore, the output of the differential amplifier (OP AMP) goes HIGH, the transistor Q ₃ is turned on and the transistor Q ₄ is turned off.

Because of such a shape, the water level and the ice detection rod (S ₂ ) and the water level and the ice detection rod (S ₃ ) are separated from each other, this time the resistance value between the water level and the ice detection rod (S ₁ ) (S ₂ ) It is to be applied to the ice generation control circuit.

On the other hand, if the transistor Q ₄ is turned OFF continuously, the voltage applied to the collector of the transistor Q ₄ turns on the transistor Q _{5 and} turns off the transistor Q ₆ , so that the cooling device does not operate. Ice production is stopped because it will not.

The fourth case is described as follows.

In this way, if cold drink continues to be sold while ice production is stopped, the water level and the resistance between the ice detection rods (S ₁ ) and (S ₂ ) fall back below a certain value, and then the transistor which is the input terminal of the Schmitt trigger circuit is again. The voltage applied to the base of (Q ₇ ) becomes LOW and the output of the Schmitt trigger circuit becomes LOW.

The reference for the constant value of the resistance value between the water level and the ice detection rod (S ₁ ) and (S ₂ ) is the variable resistor (R) connected to the emitter of the transistor (Q ₈ ) of the Schmitt trigger circuit (2). ₂₅ ).

Transistor Q ₉ is OFF, output of differential amplifier OP AMP is LOW, transistor Q ₃ is OFF, transistor Q ₄ is ON, and reed relay LY ₁ is operated so that the water level and Ice detection rod (S ₂ ) and the water level and the ice detection rod (S ₃ ) is a short circuit. Therefore, this time, the resistance value between the water level and the ice detection rod (S ₁ ) (S ₂ ) is applied to the circuit according to the present invention.

As described above, since the transistor Q ₅ is turned off and the transistor Q ₆ is turned on, the cooling device is operated to generate ice again.

As described above, the ice production control circuit according to the present invention has a problem that the conventional ice production control circuit has, namely, since the ice is regenerated in the state where the ice is almost consumed after the maximum amount of ice is generated, It is a useful design that solves the shortcomings that could not be supplied continuously so that the required amount of ice is always produced in the tank so that it is possible to supply a large amount of cold drink at a time or to supply continuously.

As described in detail above, the ice generation control circuit according to the present invention has a problem that the ice generation control circuit of the conventional cold beverage vending machine has, i.e., after the ice is almost consumed after the maximum amount of ice is generated, Not only could it not supply a large amount of cold drink at the same time because it was regenerated, but it also solved the drawback that it took a long time to reduce and regenerate the produced ice to reach between the water level and the ice sensor rods (S ₃ ). There is an advantage in that it is possible to continuously supply a cold drink by maintaining a certain amount of ice at all times.

Claims (3)

The water level and the ice detection rod (S ₁ ) (S ₂ ) connected to the power source (T ₁ ) (T ₂ ), respectively, are sequentially arranged along the direction of ice generation, and the water level and the ice detection rod (S ₂ ) and Water level and ice detection unit (1) in which the water level and ice detection rods (S ₃ ) are accessible, and the water level and ice detection rods (S ₁ ) (S ₂ ) (S ₃ ) in the water level and ice detection unit (1) ) transistor (Q ₇ of the voltage to be applied according to the resistance value that changes between a Schmitt trigger circuit (2) and the amplifier unit (3)) (Q ₈₎ (comparison voltage and the power input is determined and through the Q ₈₎ ( T ₃ ) (T ₄ ) receives a reference voltage of a constant voltage value inputted through the rectifier 4 and the constant voltage circuit unit 5, and compares the predetermined signal with the amplified unit and the relay control circuit unit 7. from the differential amplifier (OPAMP) and a differential amplifier (OP aMP) to be supplied to Tran register (Q ₃₎ (Q ₄₎ it is activated in accordance with signals applied via the Above, and ice detection rod (S ₂₎ and the lead relay (LY ₁₎ and the differential amplifier Tran register (Q ₃₎ (Q ₄₎ from (OP AMP) for connecting the _{(S 3) (Q 5)} (Q lead according to the signals applied via ₆₎ relay (LY ₁₎ and the simultaneous operation of the ice generating control of the vending machine and cold drinks, characterized in that consisting of a DC relay (LY ₂₎ that drives the condenser to generate the ice Circuit. According to claim 1, wherein the three water level and the ice sensor rods (S ₁ ) (S ₂ ) (S ₃ ) are arranged in the same order as (S ₂ ) (S ₃ ) (S ₁ ) toward the ice making direction Ice generation of the cold beverage vending machine, characterized in that the water level and the ice detection rods (S ₂ ) and (S ₃ ) are configured to be connected by a switch (SW) operated by the lead relay (LY ₁ ). Control circuit. The variable resistance of claim 1, wherein the variable resistance determines the amount of ice that can be kept constant in the tank at all times in response to the resistance detected by the water level and the ice sensing rods S ₁ , S ₂ , and S ₃ . R ₂₅ ) ice production control circuit of the cold beverage vending machine, characterized in that connected to the emitter of the transistor (Q ₈ ) of the ismit trigger circuit portion (2).