JPS5947527B2 - Power supply abnormality detection method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention makes it possible to detect not only load abnormalities but also abnormalities within individual power supply units in a power supply device having a plurality of power supply units, and prevents damage to components. The present invention relates to an abnormality detection method for a power supply device that makes it possible to detect abnormalities in a power supply device.

FIG. 1 is a diagram showing an outline of a known power supply device having a plurality of power supply units, and FIG. 2 is a diagram showing its output voltage-output current characteristics. In Figure 1, 1-1 to 1-4
is a power supply unit, 2 is a load, 3 is a power on/off control circuit, 4 is a power off instruction circuit, 5 is an AND circuit, 6 is an O
R circuit, T indicates an alarm display circuit, OCA indicates an overcurrent detection signal, and UVA indicates an undervoltage detection signal.

Each of the power supply units 1-1 to 1-4 includes a switching transistor that converts direct current to alternating current, a transformer, a rectifier circuit provided on the secondary side of the transformer, and an overvoltage circuit provided on the output side. It has a current detection circuit and an undervoltage detection circuit, and also has a drooping characteristic as shown in FIG. The overcurrent detection signal OCA becomes logic "1" when all power supply units are in an overcurrent state. On the other hand, the undervoltage detection signal UVA becomes logic "1" when at least one power supply unit is in an undervoltage state. Overcurrent detection signal 0CA
Or, when the undervoltage detection signal UVA becomes logic "1", the power cut-off instruction circuit 4 disconnects the power supply units 1-1, 1-2.
, 1-3, 1-4, and at the same time, the alarm display circuit T displays the alarm state. Upon receiving the above off signal, each power supply unit turns off the switching transistor. Third
The figure is an electrical circuit diagram showing the configuration of a conventional power supply unit.
FIG. 4 is a diagram showing the voltage-current characteristics.

In Figure 3, 8 is a diode, 9 is a capacitor, 1
0 is a switching transistor, 11 is a transformer, 12
13 is a diode, 13 is a chiyoke coil, 14 and 15 are capacitors, 16 is a shunt resistor, 11 is an undervoltage detection circuit, 18 is a drooping circuit, 19 is a voltage detection circuit, and 20 is a control circuit.

The diode 8 and the capacitor 9 are for rectifying and smoothing the AC input, and the switching transistor 10 is for converting the direct current obtained as a result of the rectification and smoothing into alternating current.

The alternating current output from the switching transistor 10 is supplied to the primary side of a voltage generator 11, and the secondary output of the transformer 11 is converted into a direct current I by a diode 12, a choke coil 13, and capacitors 14 and 15. This direct current I. is supplied to the load 2 (see FIG. 1). Current I supplied to load 2 from the power supply unit. A voltage proportional to the magnitude of is developed across shunt resistor 16 and this voltage is sent to droop circuit 18. The drooping circuit 18 carries a current I.
When the magnitude of becomes 0CAI, a logic "l" signal is output. Undervoltage detection circuit I on the output side of the power supply unit
This undervoltage detection circuit IT is provided with an output voltage V. When becomes below a certain value, a logic "L" signal is output. Control circuit 20 is a pulse width modulation control circuit. The drooping circuit 18 carries a current I. When the magnitude of is greater than or equal to the value 0CAI, a logic "l" signal is output. The output of drooping circuit 18 is sent to AND circuit 5 (see FIG. 1) and control circuit 20. Output voltage V. is compared with a voltage setting value in the voltage detection circuit 19, and the resulting voltage deviation is sent to the control circuit 20. The control circuit 20 performs constant voltage control when the output of the drooping circuit 18 is logic "o", and the drooping circuit 1
If the output of 8 is logic "L", the output current I. is the value 0C
Constant current control is performed so that A1iC. It goes without saying that the control circuit 20 controls the conduction period of the switching transistor 10. The output of the undervoltage detection circuit IT is sent to the 0R circuit 6. Although not shown, the load terminal of the undervoltage detection circuit IT is provided with a mechanism, such as a diode, for preventing current from flowing in from other power supply units. Therefore, undervoltage detection circuit I
The voltage monitored by T is not the load voltage itself.
In a power supply unit such as that shown in FIG. 3, a transformer 11. When an overcurrent flows due to a failure in the diode 12, the choke coil 13, the capacitor 14, or the capacitor 15, there is a risk that the diode 8, transistor 10, and other components may be destroyed.

Further, if an overcurrent flows due to a failure in the above component, but no overcurrent flows to the shunt resistor 16, the abnormality in the power supply unit in which the above component becomes abnormal will not be detected, and no alarm will be displayed. At this time, current will no longer flow from the abnormal power supply unit to load 2, so if the load is heavy, the remaining power supply units will enter the droop region, the undervoltage detection circuit IT will be activated, and an alarm will occur. is displayed, and all power supply units are disconnected under the control of the power disconnection instruction circuit 4. However, it is not possible to detect alarms of individual power supply units. Moreover,
If the remaining power supply units have a light load that does not fall within the drooping region, the undervoltage detection circuit IT will not operate, so no abnormality will be detected and no alarm will be displayed. As mentioned above,
Conventional power supplies can detect abnormalities in the load and prevent damage to elements caused by such abnormalities, but cannot detect failures within the power supply unit.

The present invention eliminates the above-mentioned drawbacks, and provides an abnormality detection method for a power supply device that is capable of detecting abnormalities inside individual power supply units in a power supply device having a plurality of power supply units. It is intended to.

Therefore, the abnormality detection method of the power supply device of the present invention is as follows:
comprising a plurality of power supply units and a control circuit that at least controls disconnection of the plurality of power supply units,
and each of the power supply units is a switching regulator type power supply unit comprising a switching transistor, a transformer connected to the switching transistor, and a rectifier circuit provided on the secondary side of the transformer. In the power supply device, each of the power supply units includes a first overcurrent detection means for detecting an overcurrent in the output current, a second overcurrent detection means for detecting an overcurrent in the current flowing through the switching transistor, and an output current. an undervoltage detection means for detecting an undervoltage, an output current exceeding the overcurrent detection value on the secondary side based on the output value of the first overcurrent detection means and the output value of the second overcurrent detection means; switching transistor control means for controlling the switching transistor so that the current flowing through the switching transistor does not exceed the overcurrent detection value on the primary side; and an output value of the first overcurrent detection means. , further comprising notification means for notifying the control circuit of the output value of the second overcurrent detection means and the output value of the undervoltage detection means; and the notification means includes an OR circuit that ORs the output value of the second overcurrent detection means and the output value of the undervoltage detection means, and the output value of the OR circuit. The present invention is characterized by comprising a signal line for sending to the control circuit, and a signal line for sending the output value of the first overcurrent detection means to the control circuit. below,
The present invention will be explained with reference to the drawings.

FIG. 5 is an electric circuit diagram of one embodiment of the power supply unit used in the present invention, and FIG. 6 is a diagram showing its drooping characteristics and overcurrent detection setting values. The power supply unit shown in FIG. 5 is used as the power supply unit shown in FIG. In FIG. 5, 20' is a control circuit, 21 is a current transformer, 22 is a drooping circuit, 23 is an 0R circuit, and 24 is an overcurrent detection circuit.

Note that the same reference numerals as in FIG. 3 indicate the same parts. The magnitude of the current flowing through the switching transistor 10 is detected by a current transformer 21, and the current value is sent to an overcurrent detection circuit 24. The overcurrent detection value of the overcurrent detection circuit 24 is 0C.
It is set to A2. As shown in FIG. 6, the value 0CA2 is set larger than the value 0CA1. Of course, the value is 0CA
2 is a value converted to the secondary side. When the drooping circuit 22 receives a logic "1" signal from the overcurrent detection circuit 24, it converts the level of the signal and sends it to the control circuit 2'. Control circuit 20
' is a pulse width modulation control circuit. The output of the drooping circuit 18 is sent to the AND circuit 5 (see FIG. 1) and the control circuit 20'.
sent to. Output voltage V. is compared with the voltage setting value in the voltage detection circuit 19, and the resulting voltage deviation is sent to the control circuit 2'. The control circuit 20' performs constant voltage control when the outputs of the drooping circuits 18 and 22 are both logic "0", and controls the current from the switching transistor 10 when the output of the drooping circuit 22 is logic "1". Constant current control is performed so that the value becomes 0CA2, and when the output of the drooping circuit 18 is logic "1", the output current is 1. Constant current control is performed so that the value becomes 0CA1t. The control circuit 2' is, of course, for controlling the conduction period of the switching transistor. The output of the overcurrent detection circuit 24 and the output of the undervoltage detection circuit 17 are input to the 0R circuit 23, and the output is sent to the 0R circuit 6.

As mentioned earlier, the power supply unit in FIG.
Power supply units 1-1, 1-2, 1-3, 1-4 in the diagram
It is used as a.

Now, if an abnormality occurs in load 2, the output current of all power supply units will exceed the overcurrent setting value, so the AN
D circuit 5 outputs a logic "1" signal. When the power cut-off instruction circuit 4 receives this signal, it sends an OFF signal to all power supply units. At this time, the alarm display circuit 7 displays a load abnormality. If an abnormality occurs in any power supply unit, the overcurrent detection circuit 24 or undervoltage detection circuit 17 in that power supply unit operates, and the abnormality in this power supply unit causes the 0R circuit 23, the signal line, and the 0R circuit to operate. 6, the power cut-off instruction circuit 4 is notified.
Upon receiving this notification, the power-off instruction circuit 4 issues an off signal to the power supply unit. At this time, the machine number of the power supply unit in which the abnormality has occurred is displayed on the alarm display circuit 7. In the embodiment of FIG. 5, transformer 11. diode 12
, transistor 1 even if an overcurrent flows due to a failure in the tyoke coil 13, capacitor 14, or capacitor Yl5.
Since the current can be limited to 0AC2 at 0, damage to parts can be suppressed to a minimum of 1, and the overcurrent detection circuit 2
Since the power supply disconnection instruction circuit 4 or the power supply unit 1-i (i=1, 2, 3, or 4) can be instructed to disconnect from the signal l from the power supply unit 4, it is possible to prevent the failure from spreading. As is clear from the above description, according to the present invention, in a power supply device having a plurality of power supply units, an overcurrent detector for detecting overcurrent from a switching transistor is provided. It is possible to detect abnormalities in the parts and also to prevent parts from being destroyed.

Furthermore, according to the present invention, the overcurrent detection signal and the undervoltage detection signal of the switching transistor are logically summed, and this logical sum signal is sent to the power on/off control circuit.
The number of alarm signal lines can be reduced.

[Brief explanation of drawings]

Fig. 1 is a diagram showing an outline of a known power supply device having a plurality of power supply units, Fig. 2 is a diagram showing the characteristics of its output voltage and output current, and Fig. 3 is a diagram showing the configuration of a conventional power supply unit. 4 is a diagram showing its voltage-current characteristics, and FIG. 5 is a diagram showing one of the power supply units used in the present invention.
The electrical circuit diagram of the embodiment, FIG. 6, is a diagram showing its drooping characteristics and overcurrent setting value. 1-1 to 1-4...Power supply unit, 2...Load, 3...Power on/off control circuit, 4...Power cut off instruction circuit , 5...
...AND circuit, 6...0R circuit, T...
...Alarm display circuit, 0CA...Overcurrent detection signal, UVA...Undervoltage detection signal, 8...
...Diode, 9...Capacitor, 10.
...Switching transistor, 11...
...Transformer, 12...Diode, 13...
...Chiyoke coil, 14 and 15...Capacitor, 16...Shunt resistor, 1T...
...Undervoltage detection circuit, 18... Drooping circuit, 1
9... Voltage detection circuit, 20 and 20'...
...Control circuit, 21...Current transformer, 22...
... Drooping circuit, 23... 0R circuit, 24...
...Overcurrent detection circuit.

Claims (1)

[Claims] 1 comprising a plurality of power supply units and a control circuit that at least controls disconnection of the plurality of power supply units, and each of the power supply units includes a switching transistor, a transformer connected to the switching transistor, and a control circuit that controls disconnection of the plurality of power supply units; In the power supply device, which is a switching regulator type power supply unit including a rectifier circuit provided on the secondary side of the transformer, each power supply unit has a first overcurrent for detecting an overcurrent of the output current. a current detection means, a second overcurrent detection means for detecting an overcurrent of the current flowing through the switching transistor, an undervoltage detection means for detecting an undervoltage of the output current, an output value of the first overcurrent detection means; Based on the output value of the second overcurrent detection means, the output current does not exceed the overcurrent detection value on the secondary side, and the current flowing through the switching transistor does not exceed the overcurrent detection value on the primary side. The switching transistor control means for controlling the switching transistor, the output value of the first overcurrent detection means, the output value of the second overcurrent detection means, and the output value of the undervoltage detection means as described above. Notifying means for notifying the control circuit is provided, and furthermore, the overcurrent detection value on the primary side is set higher than the overcurrent detection value on the secondary side, and the notifying means is configured to set the overcurrent detection value on the primary side to be higher than the overcurrent detection value on the secondary side. an OR circuit that ORs the value and the output value of the undervoltage detection means;
An abnormality detection method for a power supply device, comprising a signal line for sending an output value of the OR circuit to the control circuit, and a signal line for sending an output value of the first overcurrent detection means to the control circuit.