JPH07203674A - Protective unit for switching regulator - Google Patents

Abstract

PURPOSE:To protect the secondary circuit against burning or breakdown by delivering an alarm signal when the secondary output voltage exceeds a reference voltage. CONSTITUTION:The inventive protective unit is different from a conventional unit in that a series circuit of voltage division resistors R1, R2 is connected across a secondary output circuit and the minus terminal of a comparator 20 is connected with the joint of the voltage division resistors R1, R2. The joint between the voltage division resistor R2 and an electrolytic capacitor 7 for rectification is connected with a reference voltage supply Vref which is connected, on the other end thereof, with the plus terminal of the comparator 20. Consequently, when the capacity decreases due to the service life of an electrolytic capacitor 9 for rectification and the ESR increases, the secondary output voltage Eout increases and when it reaches a reference voltage Vref, an alarm signal is delivered from the comparator 20 thus protecting the secondary circuit against burning or breakdown.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching regulator protection device.

[0002]

2. Description of the Related Art FIG. 2 shows an example of a basic circuit of a switching regulator circuit. In the figure, reference numeral 3 indicates, for example, a commercial AC power supply of 100 V or 200 V. The AC voltage from the commercial AC power supply 3 is full-wave rectified by the rectification circuit 16, and the pulsating component is the first rectification electrolytic It is absorbed and smoothed by the capacitor 17 and converted into direct current.

Reference numeral 1 denotes a transformer, which has a main winding 1a and a feedback winding 1b on the primary side and an output winding 1c on the secondary side. The main winding 1a is connected to both ends of the first rectifying electrolytic capacitor 17 via the collector and the emitter of the switching transistor 2.

The feedback winding 1b is connected between the base and emitter of the transistor 2 via a capacitor 4 and a resistor 5 and is provided so as to apply positive feedback to the transistor 2 by an induced voltage. Further, a series circuit of a parallel circuit of the second rectifying electrolytic capacitor 9 and the resistor 12 and a diode 10 of the polarity shown in the figure is connected to both ends of the feedback winding 1b, and further, the anode of the diode 10 and the transistor 2 are connected. A constant voltage diode 11 having the illustrated polarity is connected between the base and the base.

As a result, when the transistor 2 is turned off, the electromotive force e ₂ 'in the direction of the arrow induced in the feedback winding 1b is applied to the second rectifying electrolytic capacitor 9 via the diode 10. Like

Further, a rectifying diode 6 and a rectifying electrolytic capacitor 7 having polarities shown in the figure are connected to both ends of the output winding 1c, and a control circuit (not shown) is provided at both ends of the rectifying electrolytic capacitor 7. ) Is connected. Reference numeral 8 represents a resistor connected between the base of the transistor 2 and the positive terminal of the first rectifying electrolytic capacitor 17.

When the transistor 2 is turned off,
An electromotive force e ₃ 'in the direction of the arrow is induced in the output winding 1c, a forward voltage is applied to the diode 6, and a current is supplied to the control device.

When the supply of the current thus supplied is stopped, the base current starts to flow in the transistor 2 due to the counter electromotive force appearing in the feedback winding 1b. Is turned on. By repeating the on / off of the transistor 2 as described above, the operation of releasing the energy stored in the primary side of the transformer 1 to the secondary side is repeated, and the input is accordingly responded. An output voltage E _out having a level different from the voltage E _in can be obtained.

At this time, the electromotive force e ₂ ′ is uniquely determined by the electromotive force e ₃ ′ (that is, the output voltage E _out ) of the output winding and the turn ratio of the feedback winding 1b and the output winding 1c. Therefore, the terminal voltage Vc ′ of the second electrolytic capacitor for rectification 9 is proportional to the output voltage E _out .

Then, the output voltage E _out rises,
When the terminal voltage Vc ′ of the second rectifying electrolytic capacitor 9 exceeds the zener voltage of the zener diode 11 and breaks over, the base supplied to the transistor 2 when the transistor 2 is turned on after that. The current is bypassed by the Zener diode 11 and the resistor and decreases. As a result, before the collector current of the transistor 2 is sufficiently increased, the transistor 2 is turned off, the energy stored in the transformer 1 is correspondingly reduced, and the output voltage E _out is reduced. The output voltage E _out is held at a constant voltage by such an operation.

The operation of the switching regulator configured as above will be described below. Now, assuming that the base current starts to flow in the transistor 2 in the off state, the collector current of the transistor 2 flowing thereby induces an electromotive force e _{1 in} the direction of the arrow in the main winding 1a, and accordingly a feedback current is supplied. The electromotive force e ₂ indicated by the arrow is also induced in the winding 1b. This electromotive voltage e ₂ acts to increase the base current of the transistor 2 and positive feedback is applied, so that the collector current further increases and the transistor 2 becomes saturated.

At this time, when a collector current flows in the main winding 1, an electromotive force e _{3 in} the direction of the arrow is induced in the output winding 1c, but the diode 6 is reversely bypassed, so that the rectifying electrolysis is performed. No current flows through the capacitor 7. Therefore, since the load of the transistor 2 is only the inductance of the transformer 1, the collector current increases linearly. Such an increase is stopped in a short time due to a shortage of its base current after the transistor 2 is saturated, and the electromotive forces e ₁ and e ₂ are correspondingly reduced to zero. in this case,
The second rectifying electrolytic capacitor 9 is charged by the electromotive force e ₂ while the base current flows through the transistor 2,
Since the terminal voltage Vc is at the negative level, the transistor 2 is rapidly turned off in response to the electromotive forces e ₁ and e ₂ becoming zero as described above.

[0013]

However, in the switching regulator configured as described above,
There are the following problems. That is, the capacity of the second rectifying electrolytic capacitor 9 decreases with the product life and the ESR increases.
And a pulsating voltage is generated in the voltage across the second rectifying electrolytic capacitor 9, and the secondary side output voltage E _{out of} the switching regulator rises above a set value. Puncture due to insufficient withstand voltage of capacitor 7,
There are problems that destruction of the IC due to excessive breakdown voltage, and burning and destruction such as burning due to excessive allowable loss of resistance occur.

Here, in order not to cause the above-mentioned problems, the rectifying electrolytic capacitor is regularly inspected,
The rectifying electrolytic capacitor is visually checked and maintenance such as capacitance measurement is performed to determine whether or not the capacitor has reached the end of its life, but this is not preferable because the work becomes complicated.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a switching regulator protection device capable of automatically detecting the life of an electrolytic capacitor and preventing the secondary side circuit from being burned or destroyed.

[0016]

In order to achieve the above object, the switching regulator protection device of the first means is
A transformer having a main winding and a feedback winding on the primary side and an output winding on the secondary side, and a collector current is supplied through the main winding and a base current through the feedback winding in an ON state. Of the switching regulator circuit configured to discharge the energy stored in the main winding when the transistor is turned on, through the output winding when the transistor is turned off. Equipped with an output voltage abnormality detection circuit that is connected to the secondary side output circuit and compares the output voltage on the secondary side with the reference voltage and outputs an alarm signal when the output voltage on the secondary side exceeds the reference voltage. It is characterized by having done.

Further, in order to achieve the above-mentioned object, the protection device for the switching regulator of the second means comprises, in addition to the above-mentioned first means, an output voltage abnormality detection circuit comprising a reference voltage source and a comparator. It has a feature.

[0018]

According to the switching regulator protection device in the first means, the reference voltage source is, for example, the standard value + α of the secondary side output voltage, and this α is not burned or destroyed in the secondary side circuit. If set to the level, the alarm signal can prevent the secondary side circuit from being burnt or destroyed. In addition, the life of the second electrolytic capacitor can be automatically determined by the alarm signal without maintenance.
Furthermore, if the life of the first or second electrolytic capacitor of the primary side circuit is set to be slightly shorter than that of other electrolytic capacitors, the alarm signal causes the lifetime of all electrolytic capacitors used in the switching regulator to be changed. Can also be judged.

According to the switching regulator protection device in the second means, the output voltage abnormality detection circuit is composed of a reference voltage source and a comparator, and its configuration is simple.

[0020]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit diagram of a switching regulator to which a switching regulator protection device according to an embodiment of the present invention is applied. The same components as those described in the prior art are designated by the same reference numerals, The description is omitted here to avoid duplication.

The difference of the switching regulator circuit of this embodiment from that of the prior art is that a series circuit of voltage dividing resistors R1 and R2 is connected between both output terminals of the secondary side output circuit of the switching regulator circuit. Piezoresistors R1 and R
Connect the negative terminal of the comparator 20 to the second connection point, to connect the reference voltage source V _ref to a connection point between the voltage dividing resistors R2 and rectification electrolytic capacitor 7, the reference voltage source V _ref of the comparator 20 plus terminal Is the point connected to. That is, the output voltage abnormality detection circuit 30 as a protection device including the reference voltage source V _ref and the comparator 20 is connected between both output terminals of the secondary side output circuit.

Here, the voltage of the reference voltage source V _ref is set to the standard value (design value) + α of the secondary side output voltage,
α is set to a value such that the secondary side circuit will not burn or break.

Therefore, when the capacity of the second rectifying electrolytic capacitor 9 decreases and the ESR increases with the life of the product, the secondary output voltage E _{out of the} switching regulator is increased.
Rises, but the secondary side output voltage standard value (design value) +
When α, that is, the reference voltage V _ref is reached, the comparator 2
An alarm signal is sent out from 0, and the secondary circuit can be prevented from being burnt or destroyed in accordance with this alarm signal.

Further, the alarm signal makes it possible to automatically determine the life of the second electrolytic capacitor 9 for rectification without performing maintenance such as periodical inspection, thus simplifying the work. Has been.

Furthermore, the output voltage abnormality detection circuit 30
_Is composed of the reference voltage source V _ref and the comparator 20, the output voltage abnormality detection circuit 30 can be configured easily.

The life of the second rectifying electrolytic capacitor 9 of the primary side circuit is intentionally made slightly shorter than that of the other electrolytic capacitors, and an alarm signal due to the life of the rectifying electrolytic capacitor 9 causes a switching regulator. It is also possible to determine the life of all other electrolytic capacitors used in.

Although the invention made by the present inventor has been specifically described based on the embodiments, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the invention. Needless to say, for example, in the above embodiment, the output voltage abnormality detection circuit 30
Is composed of the reference voltage source V _ref and the comparator 20, but it is also possible to use, for example, a diode or a resistor without using the comparator 20 so as to exhibit the same function.

Further, it is of course applicable to a switching regulator circuit in which a so-called snubber circuit for surge absorption is connected between both terminals of the main winding 1a of the primary side circuit.

Furthermore, in the above embodiment, the life of the second rectifying electrolytic capacitor 9 in the primary side circuit is intentionally made slightly shorter than that of the other electrolytic capacitors, and the rectifying electrolytic capacitor 9 is Although it is possible to judge the lifespan of all other electrolytic capacitors used in the switching regulator by the lifespan alarm signal, the lifespan of the first rectifying electrolytic capacitor 17 in the primary side circuit can be changed to other values. The same effect can be obtained even if it is intentionally made slightly shorter than that of the electrolytic capacitor.

[0030]

As described above, according to the protection device for a switching regulator of the first invention, the secondary side output circuit of the switching regulator circuit compares the secondary side output voltage with the reference voltage, and Since an output voltage abnormality detection circuit that outputs an alarm signal when the secondary output voltage exceeds the reference voltage is provided, the reference voltage source is, for example, the secondary output voltage standard value + α, and this α is the secondary value. If the side circuit is set to a level at which the secondary circuit is not burned or destroyed, the alarm signal can prevent the secondary circuit from being burned or destroyed. Further, the alarm signal makes it possible to automatically determine the life of the second electrolytic capacitor without maintenance. Furthermore, if the life of the first or second electrolytic capacitor of the primary side circuit is set to be slightly shorter than that of other electrolytic capacitors, the alarm signal causes the lifetime of all electrolytic capacitors used in the switching regulator to be changed. Can also be determined.

According to the switching regulator protection device of the second invention, in addition to the first invention, the output voltage abnormality detection circuit is composed of the reference voltage source and the comparator. Can be easily configured.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a switching regulator to which a switching regulator protection device according to an embodiment of the present invention is applied.

FIG. 2 is a circuit diagram of a switching regulator showing a conventional technique.

[Explanation of symbols]

1 transformer 1a main winding 1b feedback winding 1c output winding 2 switching transistor 20 comparator 30 output voltage abnormality detection circuit V _ref reference voltage source

Claims (2)

[Claims] 1. A transformer having a main winding and a feedback winding on a primary side and an output winding on a secondary side, and a collector current is supplied through the main winding in an ON state and the feedback A switching transistor in which a base current is positively fed back through a winding, and the energy stored in the main winding is released when the transistor is on, and the energy is released through the output winding when the transistor is off. Output voltage that is connected to the secondary output circuit of the switching regulator circuit, compares the secondary output voltage with the reference voltage, and outputs an alarm signal when the secondary output voltage exceeds the reference voltage. A switching regulator protection device including an abnormality detection circuit. 2. The switching regulator protection device according to claim 1, wherein the output voltage abnormality detection circuit includes a reference voltage source and a comparator.