KR890000654Y1 - Device for power supply - Google Patents

Abstract

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Description

Power supply device of bubble generator for ornamental fish

1 is a block diagram of the present invention.

2 is a circuit diagram of the present invention.

* Explanation of symbols on the main parts of the drawings

1: power unit 2: battery charging unit

3: inverter unit 4: control unit

5: Amplification Circuit PT ₁ : Trans

PT ₂ : Pulse transformer K: Alarm

ScR ₂ : Die List R _a , R _b : Relay Contact

D ₂ , D ₄ , D ₇ : Diode R ₉ , R ₁₂ , R ₂₀ : Resistance

_{N 1, N 2, N 3} , N 4: NAND gate _{T 1, T 2, T 3} ,, T 4,: the transistors

The present invention relates to a power supply body of the bubble generator for high sharks.

Conventionally, the bubble generator for ornamental fish is operated by using AC power of 100V or 220V (60㎐), so it is not operated during power outage and there is a closed end that damages the ornamental fish. In case of power failure, user has to connect battery directly to inverter and bubble generator in case of power outage, and if battery is consumed and bubble is reduced, remove battery and recharge battery. If you leave it connected to the inverter and leave it alone, there is a combination that the battery is completely consumed and the battery is not used.

The present invention devises an automatic switching and control circuit to eliminate such defects. When using AC power, the bubble generator uses the AC power as it is, and the inverter transformer configures the battery charging circuit to charge the battery. After switching the battery to operate the inverter to operate the bubble generator with the battery power, and the battery is consumed after a certain period of time, it becomes a limit of consumption due to the exhaustion limit and detects this when the amount of bubbles is small, and at the same time alarm the alarm It is designed to enable the use of recharging by completely preventing the battery consumption by generating the power supply and to prevent the damage of the safe power supply and ornamental fish in advance. The construction and the effect of the present invention will be described in detail based on the accompanying drawings.

When AC power is supplied to the power supply unit 1, the voltage changeover switch SW ₁ and the overcurrent protection fuse F ₁ are connected according to the voltage, and the relay coil R is connected through the resistor R ₁ . When the power is applied, the relay contact R _a supplies power to the transformer PT ₁ and the bubble generator Z, and the relay contact R _b is attached to the control unit 4 or the battery charging unit 2, respectively. In addition, a low voltage is generated on the secondary side of the transformer (PT ₁ ), and the DC voltage classified as the up-down current diode (D ₁ ) is applied to the battery charging unit (2), and the DC voltage rectified to the up-down diode (D ₂ ). The power is applied to the control unit 4 via the pure wine F ₂ and the relay contact R _b .

In case of power failure, no voltage is applied to the relay coil R, so the relay contact _Ra is in a blocking state, and the voltage generated from the inverter unit 3 is in a blocking state with the AC power supply AC side. It is configured to operate only (Z) and the relay contact (R _b ) is switched to the battery (BT) power supply of the battery charging unit 2 to supply power to the transformer (PT ₂ ) and the amplification circuit (5) to generate a bubble generator ( It is configured to supply driving power to Z).

The control unit 4 supplies power to the battery BT (+) terminal through the anti-restriction diode D ₅ and connects the resistor R ₂₅ and the zener diode ZD ₃ to always supply constant power to the inverter unit 3. Supply to the oscillation circuit.

In case of power failure, connect the volume (VR ₄ ) of the resistor (R ₁₅ ) at both ends of the power supply to detect the battery consumption voltage of the battery charger (2), and connect the Zener diode (ZD ₂ ) and the transistor (T ₇ ), and the resistor (R ₁₇ ) and the light-emitting diode (LED ₂ ) thyristors (ScR ₃ ) are connected to the NAND gate (N ₂ ) of the IC by removing the current flowing in the gate to the thyristors (ScR ₃ ) in the circuit where the anode and cathode are connected. It is.

In addition, during energization, the current passing through the relay contact (R _b ) and the diode (D ₄ ) resistor (R ₉ ) and the diode (D ₇ ) passes through the connection resistor (R ₁₇ ) to the base of the transistor (T ₈ ). Is connected to the collector and emitter of the transistor T ₈ so that the input of the NAND gate N ₂ of the IC is always at a low level, so that the input of the NAND gate N ₁ is always at power supply. It is configured to be at the low level in the case of high level power failure.

NAND gate (N ₃ ) input is low level when energized, low level during normal operation, low level during normal operation, and high level when the driving force of bubble generator (Z) is depleted due to exhaust of battery charge part (2). The gate (N ₁ ) output is at high level when energized and is connected to the input of the NAND gate (N ₃ ), and the NAND gate (N ₂ ) output is at high level so that the input and the NAND gate (N ₄ ) of the NAND gate (N ₄ ) are maintained. ₃ ) is connected to the input of the inverter oscillation control transistor (T ₄ ) (T ₄ ) via a resistor (R ₄ ) (R ₄ ) to stop the operation of the inverter and the NAND gate (N ₄ ) The input goes high level and the output changes to low level. The resistor R ₁₂ is applied to the base of the transistor T ₆ connected to the cathode and the anode of the thyristor Sc ₂ of the battery charging unit 2 circuit. In case of power failure, the output of NAND gate (N ₄ ) goes to high level. In this case, the battery power supply circuit is shut off during the power supply circuit of the battery power supply, and the output of the NAND gate N ₄ becomes low level when the AC power supply is applied.

Detectors (K) In the circuit the input of the NAND gate (N ₃₎ is a NAND gate (N ₁₎ outputs the high level, the NAND gate (N ₂₎ of NAND gate to be output a high level (N ₃₎ connected to the output resistance (R ₂₃ When the signal is cut off (+) at the transistor (T ₉ ) base and the current passing through the connected resistor (R ₂₁ ) conducts the transistor (T ₁₀ ), the alarm (K) is configured to generate an alarm sound.

In the battery charging unit 2, when the power rectified by the diode D ₁ flows through the anode of the die thruster ScR ₁ and the resistor R ₁₁ diode D ₃ , a current flows into the gate of the ScR ₁ . Enod and cathode of ScR ₁ were turned on to start charging the battery of the battery charging unit 2 through the charge current limiting resistor R ₁₀ . At this time, connect the resistor (R ₁₄ ) and the charge completion voltage setting volume (VR ₃ ) and the zener diode (ZD ₁ ) to control the overcharge of the battery.When the battery charge completion voltage is set by the volume (VR ₃ ), the battery is completely when the charging Zener diode (ZD ₁₎ is conducting thyristors (ScR ₂₎ of the lower current bucket to the gate thyristors (ScR ₂₎ of the anode and cathode is conducting a current through the resistance (R ₁₁₎ The current flows to the cathode and anode of the thyristor (ScR) through the light emitting diode (LED ₁ ) and blocks the gate signal current of the die thruster (ScR ₁ ) so that the anode and cathode of ScR ₁ are blocked. Charging stops.

And power failure has connects enoic wood and cathode of the transistor (T _6), regardless of the fundamental voltage of the volume (VR ₃₎ to the anode and cathode of the ScR ₂ flows through a signal to the base of the transistor (T ₆₎ T _Since the emitter and collector of ₆ are conducting, the current passing through the resistor (R ₁₁ ) passes through the collector and emitter of the light emitting diode (LED ₁ ) and transistor (T ₆ ), so that the gate of the diester (ScR ₁ ) is blocked. Wood and cathode are cut off to protect the battery charging (2) circuit in case of power failure.

In the inverter section 3, the positive power supply side of the known unstable multivibrator circuit and the resistor R ₂₅ and the zener diode ZD ₃ are connected to the negative side to supply a constant power supply to supply voltage fluctuations. so that the fluctuation of the frequency corresponding to connect the adjusting volume (VR ₂₎ and a pulse width adjusting volume (VR ₁₎ of the pulse period (frequency), and to tune to the normal power 60㎐ frequency, to the base of the transistor (T _S) The emitter and collector of the transistor (T _S ) are interrupted or conducting sequentially in response to the 60 Ω signal, and the current through the resistor (R ₅ ) connected to the (+) stage is connected through the resistor (R ₃ ). transistor amplifier circuit _{(T 2) (+) (} T 3) the through-conductive, relay contact points (R _b) and the resistor (R _b) current is connected to the common terminal of the pulse transformer (PT ₂₎ of the PT ₂ When the transistors T ₂ (T ₃ ) connected to both ends of the coil are sequentially turned on and off, the current passes. Magnetic fields of the N pole and the S pole are generated, and an AC power source of 60 kW is formed on the secondary side of the transformer PT ₁ . In addition, when the power source formed in the secondary coil of the pulse transformer PT ₂ is connected to the base of the transistor T ₁ through the resistor R ₂ , the same operation as that of the transistor T ₂ T ₃ is repeated. Applying a phosphorous current, the transformer (PT ₁ ) secondary coil winding number and voltage and the crank (PT ₁ ) primary voltage to the primary side of the transformer (PT ₁ ) in proportion to the number of coil windings to 100V or 220V 60㎐ It becomes usable.

In addition, the amplification unit 5 of the inverter unit 3 connects the emitter and the collector of the transistor T ₄ to the base and the emitter of the transistor T _{3 in} order to operate only in case of power failure. When the output high level of the IC NAND gate N ₂ of (4) is reached, a signal is applied to the base of the transistor T ₄ through the resistor R ₄ so that the emitter and the collector are conducted so that the resistor R ₅ and the resistor ( Since the pulse passing through R ₃ is blocked by the transistor T ₄ , the transistor T ₂ (T ₃ ) is blocked to stop the amplification circuit operation of the inverter unit 3.

In addition, if the battery is depleted in the bubble generator (Z) during the power failure, the NAND gate (N ₂ ) output becomes high level, and the amplification circuit operation prevents the battery from being exhausted. There is no case that can not be prevented by the discharge.

In the present invention, when the power supply is supplied to the battery terminal via the anti-noise diode (D ₅ ), the battery power supply resistor (R ₁₅ ) and the voltage setting device are set in case of power failure. When the battery is depleted for a certain time by the volume VR ₄ and falls to a voltage at which the bubble generator Z has no bubble generating effect, no current flows in the zener diode ZD ₂ , so that the resistance R ₁₆ and the resistance R ₁₆ are increased. The passing current is applied to the thyristor (ScR ₃ ) gate so that the anode and cathode of ScR ₃ are conducted so that the current through the resistor (R ₁₇ ) is passed through the light emitting diode (LED ₁ ) and the IC NAND gate (N ₂ ) When the input signal voltage becomes low level, the output of the NAND gate N ₁ becomes high level, thereby controlling the oscillation amplifier circuit 5 of the inverter unit 3 to stop the operation of the inverter unit 3 and On the gate (N ₁ ) input side, the relay contact (R _b ) has a battery charge. It is connected to all (2) side, so the low level and the output become high level. The input side of the NAND gate (N ₃₎ the output of the NAND gate (N ₁₎ outputs the high level and the NAND gate (N ₂₎ output of NAND gate receives a signal of a high level (N ₃₎ is at a low level.

When the output of the NAND gate N ₃ is at the low level, since the current passing through the resistor R ₂₄ does not pass, the emitter and the collector of the amplifying transistor T ₉ do not conduct, and thus the resistor N ₂₄ passes through the resistor R ₂₄ . the current is generated by the warning sound is the emitter side of the conductive collector is so applied the signal to the base transistor (T ₁₀₎ alarm (K) of the (T ₁₀₎ operation.

In addition, when the bubble generator Z operates normally during power failure, since the battery of the battery charging unit 2 has sufficient power, when a current passes through the zener diode ZD ₂ and power is applied to the base of the transistor T ₇ , the transistor ( Since the emitter and collector of T ₇ are conducting and the current passing through the resistor R ₁₆ passes through the emitter and collector of the transistor T ₇ , the current does not flow through the gate of the die thruster ScR ₃ . When the anode and cathode of (ScR ₃ ) are blocked so that the current through resistor (R ₁₇ ) and resistor (R ₁₉ ) makes the input of NAND gate (N ₂ ) high level, the output of NAND gate (N ₂ ) is is at a low level to start the oscillation of the inverter portion 3, so the bubble generator (Z) is driven, and also the input of the NAND gate (N ₃₎ is a NAND gate (N ₁₎ outputs the high level and the NAND gate (N ₂₎ of the receiving the output signal of the low level output of the NAND gate (N ₃₎ is to Is the current through a resistor (R ₂₃₎ is applied to the base of the transistor (T ₉₎ transistor (T ₉₎ the emitter and collector are conductive, so flow in the base, the current of the transistor (T ₁₀₎ of the level detector (K) Will stop. Wherein the NAND gate (N ₄₎ is when the when according to a NAND gate logic circuit, the output of the NAND gate (N ₄₎ at a high level to block the battery charge of the battery charger (2) and a NAND gate (N _4), the output is at a low level The battery will begin charging.

In addition, when the AC power source AC passes through the control unit 4, the voltage rectified by the diode D ₂ passes through the relay contact R _b and the diode D ₄ , so the input of the NAND gate N ₁ is performed. The silver is blocked by the resistor R ₂₀ and the transistor T ₈ so that the NAND gate N ₂ output becomes a high level to block the oscillation amplifier circuit 5 of the inverter unit 3 and the NAND gate ( N ₄ ) output becomes low level, battery (BT) starts charging and NAND gate (N ₃ ) input is NAND gate (N ₁ ) output low level signal and NAND gate (N ₂ ) output high level signal. The output of the NAND gate N ₃ becomes a high level to stop the operation of the alarm K.

As described above, the present invention interrupts the operation of the inverter unit 3 when the AC power source AC enters the bubble generator Z for the ornamental fish, and operates the battery charging unit 2 to charge the battery BT so that power failure occurs. The battery power can be switched and used at a time, so that the user is convenient and the controller 4 operates when the bubble generating effect of the bubble generator Z is lowered as the power consumption is less than the power consumed by the battery BT. By blocking the oscillation amplification circuit of the inverter unit 3 and alarming the alarm K, the battery BT can be recharged and used. When operating the battery charging unit 2 is cut off based on the censor (T ₆ ), so the battery charging is limited at this time, so that the battery (BT) power can be used efficiently, and the relay contact (R) is connected to the AC power supply ( Ac) Configuration when the transformer (PT ₁₎ and the bubble generator (Z) to the number of power and at the time of power failure block the AC power source (AC) and to the battery power source the power supply only to the bubble generator (Z) of the drive part (3) It is designed to be used safely without external load in case of power failure, and it is designed to be used effectively for the growth of ornamental fish by always supplying safe power to bubble generator.

Claims (1)

Connect the both ends of the secondary side in which the relay contact (R _a ) is provided on the primary coil of the AC power side transformer (PT ₁ ) to the input side of the battery charging unit (2), and the pulse transformer (PT) of the inverter unit (3). ₂₎ secondary-side upper and lower transistor (T ₁₎ relay contacts (R _b), diode (D ₄₎ the control (4 through a resistance (R ₉₎ installed in the emitter and collector of the die OY Figure (D ₂₎ each of The diode (D ₄ ) resistor (R ₉ ) is connected to the transistor (T ₈ ) base and the emitter collector of transistor (T ₆ ) is the cathode enwood of the thyristors (ScR ₂ ) of the battery charger (2). And a base connected to the output of the NAND gate N ₄ of the controller 4 through a resistor R ₁₂ , and a transistor T ₄ (T) installed in the amplification circuit 5 of the inverter unit 3. the control section 4 of the base ₄ in common), a NAND gate (N ₂₎ output, and a NAND gate (N ₃₎ set the alarm (K) known to the collector of the transistor coupled to the input (T ₁₀₎ The power supply of the bubble generator for an ornamental fish hayeoseo.