JPH07177738A - Overvoltage detecting circuit - Google Patents

Abstract

PURPOSE:To make it possible to eliminate a matching diode by installing a first comparator which compares the rectified voltage which is obtained by rectifying the secondary-side induced voltage of a main transformer with a first reference voltage and a second comparator which compares the output voltage which is to be supplied to a load with a second reference voltage. CONSTITUTION:In a normal power supply section 1, a secondary side of a main transformer(MT) 2 is normal and so the secondary-side voltage rectified by a diode 9 never exceeds a first reference voltage Vr1. Therefore, the output of a first comparator 6 goes to an L level. However, since the output of a rectifying and smoothing circuit 4 is connected in parallel, the output exceeds a second reference voltage Vr2 in a state of overvoltage. Therefore, the output of a second comparator 7 goes to an H level. In this case, a logic circuit 8 does not output an overvoltage detecting signal. In an abnormal power supply section 1, the secondary-side voltage of the MT2 rises abnormally and exceeds the first reference voltage Vr1. Therefore, the levels of the outputs of both the first and the second comparators 6, 7 are H and the logic circuit 8 outputs an overvoltage detecting signal of H level to a controlling circuit 5.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overvoltage detection circuit in a power supply device for redundant operation. A power supply device is known in which a plurality of power supply units are connected in parallel to supply a stabilized DC voltage to a load. In this case, the output capacity of each power supply unit is increased so that even if one power supply unit fails, another power supply unit can supply the stabilized DC voltage to the load in a redundant operation. Is also known. There is a demand for reliable and economical overvoltage detection in such redundantly operating power supplies.

[0002]

2. Description of the Related Art FIG.
Is a power supply unit, 32 is a main transformer, 33 is a switching transistor, 34 is an overvoltage detection circuit, 35 and 36 are rectifying diodes, 37 is an inductance, 38 is a capacitor, 39 is a matching diode, 40 is a load, and 41 is a DC power supply. .

The power supply section 31 controls the ON period of the switching transistor 33 connected to the primary side of the main transformer 32 to stabilize the DC output voltage.
The structure is not shown. Main transformer 32 again
A rectifying / smoothing circuit composed of rectifying diodes 35, 36, an inductance 37, and a capacitor 38 is connected to the secondary side of the, and the induced voltage on the secondary side of the main transformer 32 is rectified and smoothed. Load 40
It shows a configuration for supplying a stabilized DC voltage to the.

Further, the overvoltage detection circuit 34 compares the rectified output voltage with a set reference value, and when a fault causes the rectified output voltage to rise above the set reference value, detects it and turns off the switching transistor 33. To control. In general, by controlling the ON period of the switching transistor 33 and adding the overvoltage detection signal of the overvoltage detection circuit 34 to the pulse width control circuit for obtaining the stabilized DC voltage, the switching transistor 33 is controlled to the OFF state. The configuration is used.

Further, a plurality of power supply units 31 are connected in parallel to supply a stabilized DC voltage to the load 40, and even if one of them is stopped, the other power supply unit 31 stabilizes the load 40. In the redundant operation power supply device in which the load on each power supply unit 31 is small so as to supply the DC voltage, when the matching diode 39 is omitted, the output voltage Va and the voltage Vb supplied to the load are Are equal.

When the output voltage Va of one power supply unit 31 of the plurality of power supply units 31 abnormally rises and becomes an overvoltage state, each overvoltage detection circuit 34 of the power supply units 31 connected in parallel.
The voltage is input to. Therefore, the overvoltage detection circuit having the lowest overvoltage detection characteristic in the allowable range of the overvoltage detection operation first detects and turns off the switching transistor 33 of the power supply section 31. That is, the operation of the power supply unit 31 is stopped.

If the power supply unit 31 that has stopped operating is not the power supply unit in which the abnormality has occurred, the overvoltage state continues, so the overvoltage detection circuit 34 having the second overvoltage detection characteristic from the lowest detects the overvoltage, and the power supply unit 31 Stop the operation. Similarly, when the operation of the power supply unit 31 is sequentially stopped according to the deviation of the overvoltage detection characteristic, and the operation of the abnormality occurrence power supply unit is stopped, the voltage supplied to the load 40 becomes the normal state. That is,
In the case of an overvoltage state, since the abnormal power supply unit cannot be identified, there is a problem in that the supply of the stabilized DC voltage to the load 40 is stopped.

Therefore, a structure is adopted in which a plurality of power supply units 31 are connected in parallel via a butt diode 39 to supply a stabilized DC voltage to a load 40. That is, the overvoltage detection circuit 34 detects when the output voltage Va of the own power supply unit 31 is in the overvoltage state, and the other power supply unit 31.
When the output voltage Va is in the overvoltage state, the butt diode 39 is in the reverse bias state, and the overvoltage detection circuit 34 does not detect the overvoltage. That is, since it is possible to identify the abnormal power supply unit and stop its operation, the load 4 can be operated by another normal power supply unit by redundant operation.
The stabilized DC voltage can be continuously supplied to zero.

[0009]

As described above, when an overvoltage state occurs, the abutment diode 39 can separate the abnormality generating power supply unit from the normal power supply unit to detect the overvoltage. However, power loss occurs due to the forward voltage drop Vd of the matching diode 39.
Generally, in the power supply device in the redundant operation, the current supplied to the load 40 is very large, so that the power loss in the matching diode 39 becomes large. Therefore, measures have been taken such as providing a cooling structure with a radiation fin or the like, or connecting an expensive diode having a small forward voltage drop Vd in parallel. As a result, it has been difficult to reduce the size and cost.

The output voltage Va of the rectifying and smoothing circuit is the load 4
Since the forward voltage drop Vd of the matching diode 39 is lower than the voltage Vb applied to 0, and this forward voltage drop Vd changes depending on the state of the load 40, the overvoltage detection characteristic in the overvoltage detection circuit 34 is obtained. It is desirable to control in accordance with the fluctuation of the load 40, but it is practically difficult and there is a problem that the overvoltage detection characteristic is not sufficiently accurate. An object of the present invention is to make it possible to omit the butt diode, improve the overvoltage detection accuracy, and reduce the size and cost.

[0011]

The overvoltage detection circuit of the present invention will be described with reference to FIG. 1. The overvoltage detection circuit is connected to the switching transistor 3 connected to the primary side of the main transformer 2 and the secondary side of the main transformer 2. A power supply unit 1 having a rectifying / smoothing circuit 4 and a control circuit 5 that detects an output voltage of the rectifying / smoothing circuit 4 and controls an ON period of the switching transistor 3 is connected in parallel to stabilize a DC voltage applied to a load 10. In the overvoltage detection circuit in the redundant power supply device for supplying the voltage, the rectified voltage obtained by rectifying the induced voltage on the secondary side of the main transformer 2 by the diode 9 and the first reference voltage Vr.
_{The first} comparator 6 for comparing with 1 and the second comparator 7 for comparing with the output voltage of the rectifying and smoothing circuit 4 and the second reference voltage Vr _2.
And the first when the rectified voltage exceeds the first reference voltage Vr ₁ .
Of the output signal of the comparator 6 and the output signal of the second comparator 7 when the output voltage of the rectifying and smoothing circuit 4 exceeds the _second reference voltage Vr ₂ as a control circuit as an overvoltage detection signal. 5
And a logic circuit 8 added to the above.

[0012]

When the DC voltage applied to the load 10 rises abnormally, the induced voltage on the secondary side of the main transformer 2 is normal in the normal power supply section 1, so that the secondary side induced by the diode 9 is applied. The rectified voltage does not exceed the first reference voltage Vr ₁ . Therefore, the output signal of the first comparator 6 remains "0". However, since the output terminals of the rectifying and smoothing circuit 4 are connected in parallel, in the overvoltage state, the second terminal
Will exceed the reference voltage Vr ₂ . Therefore, the output signal of the second comparator 7 becomes "1". Since the logic circuit 8 uses the output signal of the logical product of the output signals of the first and second comparators 6 and 7 as the overvoltage detection signal, in this case,
No overvoltage detection signal is output. On the other hand, in the abnormal power source unit 1 where the overvoltage is generated, the induced voltage on the secondary side of the main transformer 2 is abnormally increased, which exceeds the first reference voltage Vr ₁ . Therefore, the first and second
The output signals of the comparators 6 and 7 both become "1", the logic circuit 8 applies an overvoltage detection signal of "1" to the control circuit 5, and the control circuit 5 controls the switching transistor 3 to the off state. The operation of the power supply unit for abnormality occurrence is stopped. By stopping the operation of the power supply unit in which the abnormality has occurred, the stabilized DC voltage can be continuously supplied from the normal power supply unit to the load 10.

[0013]

EXAMPLE FIG. 2 is an explanatory view of an example of the present invention.
Is a DC power supply, 12 is a main transformer, 13 is a switching transistor, 14 is an overvoltage detection circuit, 15 is a control circuit, 16 and 17 are first and second comparators, 18 is an AND circuit, 19 is a diode, and 20 is a capacitor. , 21 is a resistor, 22 and 23 are rectifying diodes, 24 is an inductance, 25 is a capacitor, and 26 is a load, which are shown only for a single power supply section.

Each power supply unit is directly connected to the load 26 in parallel without a butt diode,
The output voltage Va supplied to the load 26 is detected by the control circuit 15, and the ON period of the switching transistor 13 connected to the primary side of the main transformer 12 is controlled so as to reach the set value.

The overvoltage detection circuit 14 includes a first and second comparators 16 and 17, and an AND circuit 18 which constitutes a logic circuit.
And a case in which the diode 19, the capacitor 20 and the resistor 21 for detecting the induced voltage on the secondary side of the main transformer 12 are used. A rectified voltage Vc by the diode 19, the first reference voltage Vr ₁ and the first comparator 1
Were compared by 6, also the output voltage Va of the rectifying smoothing circuit for supplying a load 26 and a second reference voltage Vr ₂ compared by the second comparator 17.

When all the power supply units connected in parallel are normal, the induced voltage on the secondary side of the main transformer 12 is also normal. Therefore, the relationship of Vc <Vr ₁ and Va <Vr ₂ is established, and the first and the first The output signals of the two comparators 16 and 17 are "0". Therefore, the output signal of the AND circuit 18 becomes “0”, and the control circuit 15 outputs the output voltage Va applied to the load 26.
Is detected and the ON period of the switching transistor 13 is controlled.

When a power supply section in which the output voltage Va rises abnormally occurs, Vc <Vr ₁ , Va> V in a normal power supply section.
r ₂ , the output signal of the first comparator 16 is “0”, and the output signal of the second comparator 17 is “1”. However, the output signal of the AND circuit 18 becomes "0", and the control circuit 15
Keeps controlling the ON period of the switching transistor 13.

Further, in the abnormal power source section, since the voltage generated on the secondary side of the main transformer 12 is rising, Vc
> Vr ₁ and Va> Vr ₂ , and the first and second comparators 1
The output signals of 6 and 17 are both "1". Therefore, the output signal of the AND circuit 18 becomes "1", the overvoltage detection signal of "1" is applied to the control circuit 15, and the control circuit 15 controls the switching transistor 13 to the off state. Then, this off state is continued until the reset means (not shown) of the control circuit 15 is operated.

Therefore, the operation of only the power supply unit in which the abnormality has occurred can be stopped and the normal operation of the power supply unit can be continued, so that the stabilized DC voltage can be continuously supplied to the load 26. Also, since the butt diode can be omitted,
The size can be reduced and the power efficiency can be improved.

FIG. 3 is an explanatory diagram of the overvoltage detection operation.
4A shows the characteristic of the conventional example of FIG. 4, in which an abnormality occurs at time t ₁ , the output voltage Va rises, and the set reference voltage Vr is exceeded at time t ₂ , the overvoltage detection circuit 34 switches. The case where the transistor 33 is turned off and the output voltage Va is lowered by that is shown.

Further, (b) shows the operation of the abnormality generating power supply section of the embodiment of the present invention, in which an abnormality occurs at time t ₁ and the rectified voltage V obtained by rectifying the induced voltage on the secondary side of the main transformer 12 is shown.
c and the output voltage Va increase, and at time t ₂ , Va
Since> Vr ₂ and Vc> Vr ₁ are established, the output signal of the AND circuit 18 becomes “1”, and the control circuit 15 controls the switching transistor 13 to the off state. As a result, the induced voltage on the secondary side of the main transformer 12 is lowered, and the output voltage Va supplied to the load 26 becomes a value set by a normal power supply section.

[0022] The (c) shows the operation of the normal power supply unit of the embodiment of the present invention, the time t _1, the abnormal power supply unit,
When the output voltage Va supplied to the load 26 rises, the control circuit 15 that detects the output voltage Va controls to shorten the ON period of the switching transistor 13, so that the induced voltage on the secondary side of the main transformer 12 is descend. Therefore, the rectified voltage Vc by the diode 19 decreases.

At time t _2, when the operation of the power source section for abnormality occurrence is stopped as shown in (b), the output voltage Va supplied to the load 26 is also reduced, and accordingly, the control circuit 15 causes the switching transistor 13 to operate. Since the ON period gradually increases, the induced voltage on the secondary side of the main transformer 12 also gradually increases, the rectified voltage Vc and the output voltage Va return to the normal state, and the stabilized DC voltage is continuously applied to the load 26. Can be supplied.

The above-mentioned embodiment shows the case where the AND circuit 18 is used as the logic circuit 8, but the first and second comparators 1
It is also possible to use a NAND circuit or the like in accordance with the output logic levels of 6 and 17. Overvoltage detection circuit 1
4, it is also possible to directly control the switching transistor 13 on the primary side of the main transformer 12 to the off state. The switching transistor 13 is not limited to the bipolar type, but may be a switching element having various structures such as a field effect type. Further, the control circuit 5 can be configured to include an overcurrent protection unit, a current balance control unit between a plurality of power supply units, and the like.

[0025]

As described above, according to the present invention, the rectified voltage Vc obtained by rectifying the induced voltage on the secondary side of the main transformer 2 is used.
When the first and the reference voltage Vr ₁ compared by the first comparator 6, the configuration for comparing the output voltage Va and the second reference voltage Vr ₂ and the second comparator 7 supplied to a load 10,
Without using a butt diode, it is discriminated whether or not the own power supply unit is abnormal, and the switching transistor 3 is controlled in the off state in the abnormality generation power supply unit. Accordingly, there is an advantage that the stabilized DC voltage can be continuously supplied to the load 10 by the normal power supply unit. Therefore, in the redundant power supply device, there is an advantage that the power loss due to the butting diodes is eliminated, the power supply efficiency is improved, and the heat radiation means and the like can be simplified, so that the size can be reduced.

[Brief description of drawings]

FIG. 1 is a diagram illustrating the principle of the present invention.

FIG. 2 is an explanatory diagram of an example of the present invention.

FIG. 3 is an explanatory diagram of an overvoltage detection operation.

FIG. 4 is an explanatory view of a main part of a conventional example.

[Explanation of symbols]

 1 Power Supply Section 2 Main Transformer 3 Switching Transistor 4 Rectifying / Smoothing Circuit 5 Control Circuit 6 First Comparator 7 Second Comparator 8 Logic Circuit 9 Diode 10 Load

Continuation of the front page (51) Int.Cl. ⁶ Identification number Office reference number FI technical display location H02M 1/00 E

Claims (1)

[Claims] 1. A switching transistor (3) connected to a primary side of a main transformer (2), and a rectifying / smoothing circuit (4) connected to a secondary side of the main transformer (2).
A power supply unit (1) having a control circuit (5) for detecting the output voltage of the rectifying and smoothing circuit (4) and controlling the ON period of the switching transistor (3) is connected in parallel to stabilize the load. In an overvoltage detection circuit in a redundant operation power supply device for supplying a DC voltage, a first rectified voltage obtained by rectifying the induced voltage on the secondary side of the main transformer (2) is compared with a first reference voltage. A second comparator (7) for comparing the output voltage of the rectifying and smoothing circuit (4) with a second reference voltage, and the rectified voltage exceeds the first reference voltage. The output signal of the first comparator (6) when the output voltage of the second comparator (7) and the output signal of the second comparator (7) when the output voltage of the rectifying and smoothing circuit (4) exceeds the second reference voltage. A logic circuit for adding a logical product with a signal to the control circuit (5) as an overvoltage detection signal Overvoltage detection circuit, characterized in that with 8) and.