JP3365438B2 - Automatic reset type protection circuit for active filter device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an active filter device, and more particularly to improvement of an active filter device used in a power supply circuit of an air conditioner or the like. In recent years, with the spread of electronic devices using switching power supplies, the harmonic current to the power supply line has increased, causing damage to other electronic devices and causing harmonic interference in power transmission and distribution systems. Is being considered.

Therefore, further improvement of the power factor is required in the power supply circuit in order to comply with the harmonic regulation.
As an example, improvement of a power supply circuit using an active filter device is desired.

[0003]

2. Description of the Related Art An active filter device according to a conventional example will be described below with reference to FIGS. An active filter device according to a conventional example is a hybrid I in which a circuit as shown in FIG. 3 is formed on an aluminum substrate.
C is used for a power supply circuit of an air conditioner, for example.

In this circuit, an AC voltage input from terminals (A, B) of FIG. 3 is full-wave rectified by a rectifying circuit composed of diodes (D1 to D4), and then a monolithic IC (IC1) for control is used. Switching transistor (T
R1) is PWM-modulated by a PWM chopper, and an active filter circuit (1) for supplying a voltage to a coil (L1) serving as a primary coil of a transformer through terminals (C, D) and a temperature of the device. Temperature rises due to heat, an overheat protection circuit (2) that stops the driving of the active filter circuit (1) to protect the circuit, and an active filter circuit (1) when an overcurrent flows in the active filter circuit (1) ) Is stopped and the circuit is protected by an overcurrent protection circuit (3).

Regarding the operation of the circuit, normally, neither the overheat protection circuit (2) nor the overcurrent protection circuit (3) operates, and P
The voltage stabilized by the WM chopper is supplied to the coil (L1). When an overcurrent flows in the circuit,
The overcurrent protection circuit (3) operates and the operation of the active filter circuit (1) stops.

The operation of the active filter circuit (1) is performed by the potential at the point A'in FIG. 3, that is, the monolithic IC.
Determined by the potential of the soft start terminal (CS) of (IC1), the active filter circuit (1) is turned on if the potential at the point A'is the power source potential (+ Vcc), and is turned off if it is the ground potential (GND). . This change in potential is made by the soft start transistor (TR5), and when the soft start transistor (TR5) is turned on, the potential at the point A'is drawn to the ground potential (GND), and OF
When F is applied, the power supply potential (+ Vcc) is reached.

If an overcurrent flows, the overcurrent protection circuit (3) operates and the soft start transistor (TR
5) is turned on and the operation of the active filter circuit (1) is stopped. The external electrolytic capacitor (CD) is rapidly charged at the time of rising of the AC power supply, and the path as shown in FIG. 4, ie, AC input (A) → diode (D1).
→ External diode (D01) → Electrolytic capacitor (CD)
→ ground potential (GND) → terminal (E) → resistance (R5) → diode (D4) → AC input (B) path and diode (D1) → coil (L1) → switching transistor (TR1) → terminal (E) Overcurrent may flow in the path.

At this time, the switching transistor (T
R1) repeats ON / OFF operation, so O
Overcurrent is generated during N operation by switching transistor (TR
1), the switching transistor (TR1) may be destroyed, so an overcurrent protection circuit (3) is provided to protect it. That is, when an overcurrent flows at the time of rising of the AC voltage, the overcurrent also flows from the ground potential (GND) to the resistor (R5) and flows into the resistor (R18). Therefore, the resistor (R18) and the capacitor (C8) are connected to each other. The potential at the connection point of is decreased.

As a result, the potential of the non-inverting input of the comparator (OP2) lowers and falls below the reference voltage of the comparator (OP2) set by the resistors (R20, R21) and the diode (D6), and during normal operation. The output of the comparator (OP2), which was at the high level (hereinafter referred to as "H"), becomes the low level (hereinafter referred to as "L"). Therefore, the transistor (TR2) which is an open collector is turned on, the soft start transistor (TR5) connected to the collector of the transistor (TR2) through the diode (D9) is turned on, and the potential at the point A ′, that is, the soft start. The potential of the terminal (CS) is the ground potential (GN
D) and the operation of the active filter circuit (1) is stopped.

If the temperature rises due to heat,
The overheat protection circuit (2) operates and the operation of the active filter circuit (1) stops. That is, when the substrate temperature rises, the temperature of the diode (D10) also rises, the potential of the non-inverting input of the comparator (OP1), which is the connection point between the diode (D10) and the resistor (R15) decreases, and the resistance (R16) increases. , R17) drops below the reference voltage of the comparator (OP1), the output of the comparator (OP1), which was "H" during normal operation, is "L".
become.

As a result, the transistor (TR2) which is an open collector is turned on, and the transistor (TR2) is turned on.
The soft start transistor (TR5) connected to the collector of 2) through the diode (D9) is turned on, the potential at the point A'is drawn to the ground potential (GND), and the operation of the active filter circuit (1) is performed. Stop. Also
Japanese Patent Application No. 58-93086 (Japanese Utility Model No. 60-2390)
Although it is described in the microfilm of
The temperature around the path and the power transistor is higher than the set temperature of the sensor.
Temperature detection, the output is reduced when the
Inverter device protection device including output circuit and stop circuit
Is listed. Furthermore, Japanese Utility Model Application No. 55-86973
Described in the microfilm of (Actual Development Sho 57-14637)
A resettable thermal response overcurrent protector is listed as listed.
Has been. Japanese Unexamined Patent Publication No. 48-58357 discloses a control circuit and an electric circuit.
A constant-current circuit consisting of a flow-blocking protection circuit and an error detection amplifier
Voltage power supply protection circuit and that the protection circuit operation has been activated.
The detection circuit to detect and a certain value after the detection circuit detects
When the protection circuit is automatically reset after a lapse of time
Limited reset circuit is described.

[0012]

However, according to the active filter device of FIG. 3 according to the conventional example, the overheat protection circuit (2) is activated and the active filter circuit (1) is stopped to lower the substrate temperature. Since a circuit for restarting the active filter circuit (1) is not provided later, it is necessary to release the protection by the overheat protection circuit (2) with an external microcomputer (not shown) and perform control to prompt the restart. There is a problem that handling of the device becomes complicated. Also, the inverter of Japanese Utility Model Application No. 58-93086.
Device protection device To cancel the protection operation as described above,
It was necessary to operate the set circuit. JP-A-48-58
No. 357 is about resetting the protection circuit automatically.
However, there is a single protection for overheat and overcurrent.
It cannot be done in the guard circuit.

[0013]

The present invention has been made in view of the above conventional drawbacks, and as shown in FIG. 1, an active filter circuit (11) for generating a power supply voltage based on an AC voltage, and An overheat protection circuit (12) for stopping the driving of the active filter circuit (11) when the temperature of the device rises, and an overcurrent protection for stopping the operation of the active filter circuit (11) when an overcurrent flows. A circuit (13) and the active filter circuit (1) provided by the overheat protection circuit (12) after a lapse of a certain time.
By providing the release circuit (14) for releasing the protection of 1), the present invention provides an active filter device that can automatically restart after temperature protection works only in the device.

[0014]

[Operation] According to the active filter device of the present invention, as shown in FIG. 1, an overheat protection circuit (12) or
Since the overcurrent protection circuit (13) has the release circuit (14) for releasing the protection by the overheat protection circuit (12) after a certain time has elapsed since the operation, the temperature protection or the overcurrent protection is performed only by the device. It becomes possible to automatically restart the device after the current protection works, and the handling of the device becomes easy.

In the active filter device according to the present invention, the release circuit (14) includes a time constant setting resistor (R
t) and the time constant setting capacitor (Ct) are connected in series, and are connected to the transistor (TR) with a resistor,
The protection by the overheat protection circuit (12) is released by turning on / off the transistor (TR) according to the time constant determined by these.

Therefore, it becomes possible to cancel the protection by the overheat protection circuit (12) with a simple circuit by utilizing the time constants of the time constant setting resistor (Rt) and the time constant setting capacitor (Ct).

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An active filter device according to an embodiment of the present invention will be described below with reference to FIG. The active filter device according to the embodiment of the present invention is a hybrid IC in which a circuit as shown in FIG. 2 is formed on an aluminum substrate and is used for a power supply circuit of an air conditioner or the like.

As shown in FIG. 2, the active filter device according to the present embodiment has an active filter circuit (1
1), overheat protection circuit (12), overcurrent protection circuit (1
3), a release circuit (14), a soft start transistor (TR15), and a protection circuit transistor (TR12). The active filter circuit (11) is a circuit that supplies a power supply voltage to the external coil (L11) based on the AC voltage input from the terminals (AC1, AC2) of FIG. 2, and is a PWM together with the switching transistor (TR11). Control monolithic IC (IC11) that constitutes a chopper, and diodes (D11 to D1)
4) and a rectifier circuit.

The overheat protection circuit (12) is a circuit for protecting the circuit by stopping the driving of the active filter circuit (11) when the temperature of the device rises due to heat, and includes a comparator (OP11) and heat detection. It is composed of a diode (D20) for use. The overcurrent protection circuit (13)
A circuit that protects the active filter circuit (11) by stopping the operation of the active filter circuit (11) when an overcurrent flows through the active filter circuit (11).
2), resistors (R38 to R41), capacitors (C18,
C19) etc.

The release circuit (14) is an overheat protection circuit (1
2) Or, a circuit that restarts the active filter circuit (11) after a certain time has elapsed since the active filter circuit (11) stopped operating due to the protection by the overcurrent protection circuit (13). , A time constant setting resistor (Rt), a time constant setting capacitor (Ct), a transistor (TR16), and the like.

The protection circuit transistor (TR12) is
It is turned off during normal operation, and the overheat protection circuit (12) and the overcurrent protection circuit (13) operate to operate the comparator (OP1).
When the output of (1, OP12) becomes "L", it is turned on and the soft start transistor (TR15) is turned on. Soft start transistor (TR15) is O
As a result of being N, the potential of the soft start terminal (CS) of the monolithic IC (IC11) is pulled to the ground potential and the operation of the monolithic IC (IC11) is stopped.

In the following, the operation of the above circuit will be described in three cases, that is, when the overcurrent protection works and when the temperature protection works during the normal operation. 1) During normal operation, an AC voltage is input to the device from terminals (AC1, AC2) and full-wave rectified by a rectifier circuit including diodes (D11 to D14) to form a monolithic IC (IC11).
Is input to the input terminal (VDET) of. Based on this full-wave rectified waveform, the switching transistor (TR11) is turned on / off, and the PWM-modulated power supply voltage is the coil (L11) that is the primary coil of the external transformer via the terminals (C, D). Is output to.

2) When overcurrent protection operates When an overcurrent flows, this overcurrent flows into the resistor (R38) via the resistor (R35) as described in the conventional example. Then, the potential of the connection point between the resistor (R38) and the capacitor (C18), that is, the potential of the non-inverting input of the comparator (OP12) decreases, and the comparator (the resistor (R40, R41) and the diode (D16) set by OP
The output voltage of the comparator (OP12), which was "H" during the normal operation, becomes "L".
Therefore, the comparator (OP12) and the comparator (O
Since the output side of P11) is connected, the cathode (K) side of the diode (D17) becomes "L", the comparator (OP11) is latched, and the output of the comparator (OP11) becomes "L". Therefore, the protection circuit transistor (TR12), which is an open collector and has been turned off in the normal operation, is turned on and is connected to the collector of the transistor (TR12) through the diode (D19). The soft start transistor (TR15) is turned on, the potential at the point A ', that is, the potential of the soft start terminal (CS) of the monolithic IC (IC11) is drawn to the ground potential (GND), and the operation of the active filter circuit (11) is started. Stop.

3) When the temperature protection works, when the temperature of the device, especially the aluminum substrate (not shown) that supports the circuit rises due to heat generation, the temperature of the diode (D20) provided for temperature detection. Rises, and the power supply voltage (+ Vcc) is changed to a resistor (R45) and a diode (D2
0) comparator divided by bleeder ratio (OP1
The non-inverting input potential of 1) decreases.

Therefore, when the non-inverting input potential becomes lower than the potential of the inverting input portion of the comparator (OP11) set by resistance division of the power supply voltage (+ Vcc), the output of the comparator (OP11) becomes "L". Further, since the cathode side of the diode (D17) becomes "L", the non-inverting input potential further lowers and enters the latch state, and the "L" state of the output of the comparator (OP11) is held.

As a result, the open collector protection circuit transistor (TR1) which was turned off in the normal operation is used.
2) is turned on and the soft start transistor (TR1
5) is turned on, so monolithic IC (IC11)
The electric potential of the soft start terminal (CS) is pulled to the ground potential, and the operation of the monolithic IC (IC11) is stopped.

After a certain period of time elapses after the temperature protection works as described above, the base potential of the transistor (TR16) is changed by the time constant set by the time constant setting resistor (Rt) and the time constant setting capacitor (Ct). Goes up and is turned on. That is, the connection point of the time constant setting resistor (Rt) and the time constant setting capacitor (Ct) connected in series is connected to the base of the transistor (TR16) via the resistor. The potential at point B is
Time constant setting resistor (Rt) and time constant setting capacitor (C
t) and rises according to the time constant set by.

As a result, the base potential of the transistor (TR16) rises, so that the transistor (TR16) which has been turned off is turned on after a certain period of time.
To be done. Therefore, when the transistor (TR16) is turned on, the potential of the non-inverting input part of the comparator (OP11) is lowered, so that the comparator (L) latched and "L" when the temperature protection or the current protection is working ( OP
Since the output of 11) becomes "H", the overheat protection circuit (1
The temperature protection by 2) is released.

As a result, the protection circuit transistor (T
R12) is turned off, the soft start transistor (TR15) is turned off, and the monolithic IC (IC1
Since the potential of the soft start terminal (CS) of 1) returns to the power source potential (+ Vcc), it restarts. As described above, according to the active filter device of the present invention, as shown in FIG. 2, the release circuit (14) that releases the protection by the overheat protection circuit (12) after a certain time has elapsed.
Therefore, the time constant setting resistor (R
t) and the time constant of the time constant setting capacitor (Ct) are used to control the ON / OFF operation of the transistor (TR16), so that the overheat protection circuit (1
It becomes possible to cancel the protection by 2) and restart the active filter circuit (11).

For this reason, it becomes possible to restart only the device without requiring an external start signal, and the handling thereof becomes easy.

[0031]

As described above, according to the active filter device of the present invention, the overheat protection circuit (12) or the overcurrent protection circuit (13) operates and then the overheat protection circuit is operated after a certain time has elapsed. Since the release circuit (14) for releasing the latch circuit according to (12) is provided, it becomes possible to automatically restart after the temperature protection or the overcurrent protection works in only the device.

[Brief description of drawings]

FIG. 1 is a principle diagram of an active filter device according to the present invention.

FIG. 2 is a circuit diagram of an active filter device according to an embodiment of the present invention.

FIG. 3 is a circuit diagram of an active filter device according to a conventional example.

FIG. 4 is a circuit diagram illustrating an operation of an overcurrent protection circuit of the active filter device.

[Explanation of symbols]

(11) Active filter circuit (12) Overheat protection circuit (13) Overcurrent protection circuit (14) Release circuit (Rt) Time constant setting resistance (Ct) Time constant setting capacitor (TR) Transistor

Continuation of the front page (56) References JP-A-48-58357 (JP, A) JP-A-52-50550 (JP, A) JP-A-6-331203 (JP, A) Actual development Sho-57-14637 (JP , U) Actual development Sho-60-2390 (JP, U) Actual development 2-57229 (JP, U) Actual development 3-63035 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB) Name) H02H 7/10-7/20 H02J 3/00-5/00 H02M 1/00-1/30

Claims (2)

(57) [Claims] 1. A power supply voltage is generated based on an AC voltage.
An active filter circuit (11),Detects that the temperature of the device has risen and
Overheat protection circuit (12) that locks when it becomes in a state, The overheat protection circuit (1
Overcurrent protection circuit (13) that puts 2) into the locked state
When, It is turned off during normal operation and the overheat protection circuit (12) or
When the current protection circuit (13) detects overheat or overcurrent
Is operated to disable the active filter circuit (11).
A protection circuit transistor (TR12) to be operated, Release to release the locked state of the overheat protection circuit (12)
Having a circuit (14),When the device is overheated or overcurrent flows
In either case, keep the overheat protection circuit (12) in the locked state.
When the protection circuit transistor (TR12) is activated,
The drive of the active filter circuit (11) is stopped and protected.
Let Stop the driving of the active filter circuit (11)
After a certain period of time has passed, the release circuit will overheat
For releasing the protection circuit (12) from the locked state,
The transistor is disabled and the active filter circuit
Acti characterized by releasing protection of road (11)
Automatic protection type protection circuit for filter device. 2. A power supply voltage is generated based on an AC voltage.
An active filter circuit (11),Detects that the temperature of the device has risen and
Overheat protection circuit (12) that locks when it becomes in a state, The overheat protection circuit (1
Overcurrent protection circuit (13) that puts 2) into the locked state
When,It is turned off during normal operation and the overheat protection circuit (12) or
When the current protection circuit (13) detects overheat or overcurrent
Is operated to disable the active filter circuit (11).
A protection circuit transistor (TR12) to be operated, Time constant setting resistor (R1) and time constant setting capacitor (C
t) and unlock the overheat protection circuit (12)
It consists of a transistor (TR) and the overheat protection circuit (1
2) has a release circuit (14) for releasing the locked state,When the device is overheated or overcurrent flows
In either case, keep the overheat protection circuit (12) in the locked state.
When the protection circuit transistor (TR12) is activated,
The active filter circuit (11) is stopped and protected.
Let Stop the driving of the active filter circuit (11)
After letting me protect Constant setting resistor (R1) and time constant setting capacitor
Sensor (Ct) and the time specified by
The overheat protection circuit (12) is locked with the transistor (TR).
To deactivate the protection circuit transistor,
Cancel protection of the active filter circuit (11)
Active filter device characterized byAutomatic recovery type
Protection circuit.