JP3187477B2 - Switching power supply device and composite element used therefor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an RCC (ringing choke converter) type switching power supply having an overvoltage protection function of detecting abnormal heat generation and cutting off the output. More specifically, the thermal fuse is inserted into the base of the switching transistor and is brought close to the constant voltage diode for the control voltage. The present invention relates to a switching power supply device to be stopped and a composite element used for the switching power supply device.

[0002]

2. Description of the Related Art An RCC type switching power supply is a self-excited single switching power supply utilizing blocking oscillation, and has a small number of circuit components and is widely used for low power at low cost.

FIG. 3 shows an example of a typical conventional switching power supply. This power supply has an overvoltage protection circuit incorporated in an RCC circuit. RCC circuit includes an input capacitor C _1, a transformer T, a switching transistor Q ₁ which is turned on / off by the induced voltage is connected to the primary winding N _P and base winding N _B, the secondary winding N _S And a rectifying / smoothing circuit 10 for converting the output from the DC to DC.
Further comprising a constant voltage control unit 12 incorporated in the base circuit of the switching transistors Q _1, a reset circuit 14 for the exciting current of the primary winding N _P to the initial state.

[0004] The base of the switching transistor Q ₁ starting resistor R _S and the base resistor R _B and speed-up capacitor C ₁ is connected. Constant voltage controller 12
The constant-voltage diode ZD ₁ for overvoltage detection, a capacitor C ₃ for smoothing the resistor R _1, a diode D.

[0005] Operation of the RCC circuit is well known and outlined, the switching transistor Q ₁ is turned on / off by using the induced voltage of the base winding N _B of the transformer T, the voltage due to this Is rectified and smoothed on the secondary side to obtain a desired DC voltage. Then, the constant voltage control unit 12 sets RC
Stabilizes the output of the C circuit. When the output voltage rises,
Also increased induced voltage of the base winding N _B, the DC control voltage by a diode D and a smoothing capacitor C ₃ is also increased. Therefore, by conducting a constant voltage diode ZD ₁ for voltage detection, to reduce the base current of the switching transistors Q _1, increase the time to turn off the switching transistor Q _1. In this way, the output voltage is controlled to be a constant voltage.

However, when an excessive output voltage exceeding the control capability of the constant voltage control unit 12 is generated due to some abnormality, the load may be damaged, and a large loss may be generated instantaneously. In particular, when an integrated circuit is used as a load, the damage is increased because the degree of integration of the integrated circuit and the reduction in power consumption are progressing. Therefore, an overvoltage protection circuit that immediately shuts off the output voltage when such an overvoltage occurs is required.

The overvoltage protection circuit 16 is configured to detect an overvoltage on the secondary side of the transformer T and stop the switching operation on the primary side by the signal. Circuit incorporated on the primary side, the current limiting resistor R ₃ and the photo-thyristor PTh (the light receiving element of the photo coupler) a base bias resistor R ₄ is connected in series between the input terminals, the base and emitter of the switching transistor Q ₁ Transistor switch Q between
₂ and its base is connected to the base bias resistor R _4.
Connected to, it is provided with a parallel connection of a resistor R ₂ and capacitor C ₄ between the gate and cathode of the photo-thyristor PTh. Circuit incorporating the secondary side, a series connection of a constant voltage diode ZD ₂ and the base bias resistor R ₆ for current limiting resistor R ₅ and the over-voltage detector, a collector resistor R ₇
And light emitting diode LED (light emitting element of photo coupler)
And a series connection of transistor switch Q _3, provided in parallel between the output terminal, in which the base of the transistor switch Q ₃ is connected to the base bias resistor R _6.

The operation of the overvoltage protection circuit 16 is such that when an overvoltage occurs, a constant-voltage diode Z for detecting an overvoltage on the secondary side is used.
D ₂ is turned on, a current flows to the base of transistor switch Q _3, transistor switch Q ₃ is turned on,
The collector current flows, and the light emitting diode LED emits light. This light is received by the primary-side photo thyristor PTh to generate a current, and a current flows through the gate of the photo-thyristor PTh to turn on the photo-thyristor PTh.
Current flows to the base of transistor switch Q _2, transistor switch Q ₂ is turned on, the base current of the switching transistor Q ₁ is rapidly pulled out. This switching transistor Q ₁ maintains the off-state to cut off the output of the power supply.

[0009]

To the 0005] RCC smoothing capacitor C ₃ of the constant voltage control unit 12 of the circuit, electrolytic capacitors are used. An electrolytic capacitor has a property that a chemical change occurs internally due to aging, and the electrolytic solution decreases to decrease the capacity. When the aging electrolytic capacitor will decrease., The higher the voltage applied to the smoothing capacitor C constant voltage diode ZD ₁ simultaneously terminal voltage increases of _3, the constant voltage diode ZD ₁ generates heat. The temperature gradually rises due to the heating, be up to about 150 to 200 ° C., a constant voltage diode ZD ₁ is to be destroyed by heat. At this time, if it is destroyed in the open mode, it will be in an uncontrolled state and the output voltage will rise sharply. Further, a constant voltage diode ZD ₁ itself may not be thermally destroyed, or burning out the pattern of the printed circuit board by its abnormal heating, or cause a fire or smoke. If the pattern on the printed circuit board is burned out, the open mode is destroyed. Therefore, as described above, the circuit is in the uncontrolled state and the output voltage rises sharply.

[0010] However, in the conventional overvoltage protection circuit as described above it can not detect the abnormality until the output voltage and the like is constant-voltage diode ZD ₁ is broken is increased. In addition, since the overvoltage signal is transmitted using the photocoupler, the operation delay is large, and the output cannot be cut off immediately when the output rises sharply, and the load may be destroyed. Also, many, high cost this overvoltage protection circuit is complicated and the number of parts.

An object of the present invention is to provide a switching power supply device and a composite element used in the switching power supply device, which can prevent an overvoltage from occurring by detecting abnormal heating of a constant voltage diode for detecting a control voltage and cutting off the output. It is to provide.

[0012]

SUMMARY OF THE INVENTION The present invention is a switching power supply device having an RCC circuit and a constant voltage control unit incorporated in a base of a switching transistor of the RCC circuit. Here, the constant voltage control unit includes an electrolytic capacitor for smoothing the control voltage and a constant voltage diode for detecting the control voltage. The present invention has been made by paying attention to the above-described overvoltage generation mechanism in such a power supply device, that is, a phenomenon of abnormal heat generation of a constant voltage diode based on a decrease in capacitance of a capacitor due to aging,
A temperature fuse inserted into the base of the switching transistor and mounted in close proximity to the constant voltage diode, wherein the temperature fuse is blown when abnormal heat generation of the constant voltage diode stops oscillation of the switching transistor. It is a feature.

In this power supply device, it is desirable to use a composite element in which a constant voltage diode and a thermal fuse are mounted close to each other and housed in a heat-resistant case. The fusing temperature of the thermal fuse is set at a temperature equal to or higher than the temperature at which the constant voltage diode generates abnormal heat and lower than the temperature at which the constant voltage diode is broken.

[0014]

The capacitance of the smoothing electrolytic capacitor of the constant voltage control unit decreases due to aging, and the terminal voltage increases. At the same time, the terminal voltage of the constant voltage diode also increases. Therefore, the constant voltage diode gradually generates heat. Since the thermal fuse is mounted close to the constant voltage diode,
Fusing due to abnormal heating of the constant voltage diode. Since the thermal fuse is inserted into the base of the switching transistor, the base current is cut off and the oscillation stops. This prevents an uncontrolled state and an overvoltage from occurring.

[0015]

FIG. 1 is a circuit diagram showing a preferred embodiment of the present invention. Since the basic circuit configuration of this switching power supply device is almost the same as that shown in FIG. 3, the corresponding parts are denoted by the same reference numerals and description thereof will be omitted.

[0016] Features of the present invention, the thermal fuse F is inserted into the base portion of the switching transistors Q _1, located in the point of mounting in close proximity to the constant voltage diode ZD ₁ for control voltage detection, the conventional complex overvoltage No protection circuit is required.
This thermal fuse F is inserted for between starting resistor R _S and the cathode terminal of the constant voltage diode ZD _1, be inserted between the cathode terminal of the switching transistor Q ₁ and the constant voltage diode ZD ₁ Good.

The operation of the switching power supply will be described. When the power is turned on, the current through the starting resistor R _S flows to the base of the switching transistor Q _1, a switching transistor Q ₁ is turned on. As a result, the voltage is applied to the primary winding N _P, also a voltage is generated in the base winding N _B. Voltage of the base winding N _B becomes a voltage of positive feedback to the base of the switching transistor Q _1, a switching transistor Q ₁ is once turned on, linearly increasing the exciting current. At this time, the induced voltage of the secondary winding N _S rectifying Since smoothing circuit applied to the opposite direction with respect to 10 of the diode current does not flow in the secondary winding N _S, only the exciting current to the primary winding N _P flows. The exciting current increases with time, the switching transistor to Q ₁ current is the base current increases becomes impossible to keep the saturation of the switching transistors Q _1, lowers the voltage of the primary winding N _P. Also it decreases the voltage of the base winding N _B, the change is positively fed back to the base. As a result, switching
Transistor Q ₁ is turned off at once. At this time, the induced voltage of the secondary winding N _S is applied to the forward direction to the diode of the rectifying and smoothing circuit 10, a current flows to the load side. If emission current is completed, a current begins to flow to the base of the switching transistor Q ₁ through a base resistor R _B, a switching transistor Q ₁ again turned on. In this way, the oscillation is continued by repeating the same operation, and the rectifying and smoothing circuit 10
To obtain a desired DC output.

However, since the output voltage of the RCC circuit is unstable only by this, the constant voltage control unit 12 for stabilization is used.
Is provided. When the output voltage rises, the base winding N
The voltage of _B also increases. Capacitor C smoothing this
₃ rises in proportion to this, the constant voltage diode ZD ₁ conducts, reducing the base current of the switching transistor Q ₁ ,
Speed off _one . That is, when the output voltage increases,
By controlling the base current in a direction to prevent this, the output voltage is stabilized.

The smoothing capacitor C of the constant voltage controller 12
_{As for 3} , as described above, since the electrolytic capacitor is used, the capacity decreases due to aging. Thus the terminal voltage of the capacitor C ₃ is also raised to the constant voltage diode ZD ₁ terminal voltage simultaneously rises. Constant voltage diode ZD
_{If 1} heats up and breaks down in open mode, the output voltage could be out of control. Therefore in proximity to the constant voltage diode ZD ₁ implements the thermal fuse F, the detecting the abnormal heat generation of the constant voltage diode ZD ₁ by thermal fuse F. When the thermal fuse F blows due to abnormal heat generation, the base current is cut off and the oscillation stops. Naturally, the fusing temperature of the thermal fuse F depends on the constant voltage diode ZD _1.
Lower than the destruction temperature.

By mounting the thermal fuse and the constant voltage diode close to each other and forming a composite element, the detection sensitivity can be increased and the detection accuracy can be improved (the characteristic variation among the elements can be reduced). This embodiment is shown in FIG. A constant voltage diode 2 is provided inside the rectangular parallelepiped case 20.
2 and the thermal fuse 24 are incorporated as close as possible. The case 20 is made of, for example, a heat-resistant material such as ceramics, and has a hole for lead insertion formed on opposing side surfaces. The constant voltage diode 22 and the thermal fuse 24 are housed in the case 20, and the lead 26 is exposed outside through the hole, and is filled with a material 28 having good thermal conductivity and heat resistance.

[0021]

According to the present invention, the temperature fuse is mounted close to the constant voltage diode for detecting the control voltage and is incorporated in the base of the switching transistor. The thermal fuse is blown before the output voltage becomes overvoltage, so that the base current of the switching transistor can be cut off and the oscillation can be stopped. Therefore, the power supply device itself can be protected, the load can be prevented from being destroyed due to an uncontrollable state of the output voltage, and smoke and ignition can be prevented at the same time. Furthermore, RCC
Since only a thermal fuse is added to the constant voltage control section of the circuit, the circuit is greatly simplified, the number of parts is reduced, and the cost is greatly reduced.

Further, since the composite element is formed by combining the thermal fuse and the constant voltage diode, it is in a state of being extremely close to the heat, the abnormality detection capability is improved, and the variation in the characteristics of each element can be suppressed.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing one embodiment of a switching power supply device according to the present invention.

FIG. 2 is an explanatory view showing one embodiment of the composite device according to the present invention.

FIG. 3 is a circuit diagram showing an example of a conventional switching power supply device.

[Explanation of symbols]

12 constant voltage control unit 20 case 22 constant voltage diode 24 thermal fuse C ₃ capacitor ZD ₁ constant voltage diode Q ₁ switching transistor F thermal fuse

────────────────────────────────────────────────── (5) Continuation of the front page (51) Int.Cl. ⁷ Identification symbol FI H02M 3/338 H02M 3/338 A (56) References JP-A-63-53903 (JP, A) JP-A-2-223737 ( JP, A) JP-A-62-262333 (JP, A) JP-A-57-144126 (JP, U) JP-A-55-15910 (JP, U) JP-A-64-40284 (JP, U) 63-10505 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) H02M 3/28 G05F 1/10 304 H02H 5/04 H02M 1/00 H02M 3/338

Claims (2)

(57) [Claims] The ringing choke converter includes a ringing choke converter circuit, an electrolytic capacitor for smoothing a control voltage, and a constant voltage diode for detecting a control voltage.
A switching power supply device having a constant voltage control unit incorporated in a base part of a switching transistor of a converter circuit, comprising a thermal fuse inserted in the base part of the switching transistor and mounted in close proximity to the constant voltage diode, For the control voltage smoothing
Capacitance reduction due to aging of electrolytic capacitors
Switching power supply the constant voltage diode of the abnormal heat generation temperature fuse when is characterized by stopping the oscillation of the switching transistor blown based. 2. A proximity to the constant voltage diode and a thermal fuse housed in resistance to heat case, both the constant voltage diode
Lead and both leads of the thermal fuse
Pulled out from heat-resistant case and filled with heat-resistant material
It has a structure and the fusing temperature of the thermal fuse is
Temperature above which abnormal heat generation occurs and temperature
2. The constant voltage diode for detecting a control voltage of the switching power supply device according to claim 1 ,
A composite element incorporated as a thermal fuse .