JPH09331626A - Load overvoltage protective device of remote-sensing power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a load overvoltage protective device which eliminates a malfunction caused by a sharp decrease of load current and which operates rapidly and has a high reliability and a high operability. SOLUTION: A load overvoltage protective device 10 has an overvoltage detecting section 62 which outputs a power supply stop signal 'a' when it detects overvoltage of the load voltage Vt, a power supply stopping section 64 which stops the supply of power to a load 54 from a power supply 52 by the power supply stop signal 'a', a load current detecting section 12 which outputs a power supply continuing signal 'b' when it detects a sharp decrease of load current It in the load 54, and a power supply continuing section 14 which continues the supply of power to the load 54 from the power supply 52 by the power supply continuing signal 'b' output from the load current detecting section 12.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used in a remote sensing power supply system for supplying power of a power supply to a load provided far away from the power supply so that the load voltage becomes constant. The present invention relates to a load overvoltage protection device for protecting a load from overvoltage.

[0002]

2. Description of the Related Art FIG. 2 is a block diagram showing a conventional load overvoltage protection device.

A remote sensing power supply system 50
Is a load 54 provided far from the power source 52.
Against, supplies power of the power supply 52 via a power supply line 561 and 562, detects a load voltage V _L applied to the load 54 through the remote sensing line 581 and 582, the load voltage V _L is The output voltage Vo of the power supply 52 is controlled to be constant. The load overvoltage protection device 60 used in the remote sensing power supply system 50 includes an overvoltage detection unit 62 that outputs a power supply stop signal a when detecting an overvoltage of the load voltage _VL.
And a power supply stop unit 64 that stops the power supply from the power supply 52 to the load 54 in response to the power supply stop signal a output from the overvoltage detection unit 62.

The power supply 52 includes a primary power supply 521 and a secondary power supply 5.
22. For example, the primary power supply 521 is an AC 100 V commercial power supply, and the secondary power supply 522 is a general DC stabilized power supply that converts an AC voltage input from the primary power supply 521 into a DC voltage. The overvoltage detector 62 includes a load voltage detector 621 and an overvoltage detector 622. The load voltage detector 621 receives the load voltage _VL from the remote sensing lines 581 and 582. The overvoltage detector 622 compares the load voltage _VL input by the load voltage detector 621 with the reference voltage Vr, determines that an overvoltage has occurred when _VL > Vr, and outputs a power supply stop signal a. The power supply stop unit 64 is, for example, an electromagnetic relay or a switching circuit that is opened by a power supply stop signal a,
It is interposed between the primary power supply 521 and the secondary power supply 522.

[0005] The secondary power supply 522 has a voltage stabilizing feedback loop, and is connected to the remote sensing line 5.
The load voltage _VL is remotely sensed via 81 and 582, and the output voltage Vo is controlled so that the load voltage _VL becomes the target value Vm. At this time, the output voltage Vo, the conduction resistance r of the power supply lines 561 and 562 the load current I _L
And the target value Vm by the voltage drop I _L · r
It is controlled to a higher voltage Vm + I _L · r. As a result, the load voltage _VL is maintained at the target value Vm.

[0006]

However, the conventional load overvoltage protection device 60 has the following problems.

[0007] When the load current I _L becomes decreased example '0', the voltage drop on the power supply line 561, 562 becomes '0'. At this time, the load current I _L is abruptly reduced at a faster rate than the response speed of the voltage regulation loop of the secondary power supply 522, across the load 54, the load current I _L
Vm + I _L · r which is the output voltage Vo before the voltage decreases
Is momentarily applied (until the voltage stabilization loop of the secondary power supply 522 responds). Thereafter, when the voltage stabilization loop of the secondary power supply 522 finishes responding, the load voltage _VL is pulled back to Vm. However, since a voltage higher than the target value Vm is applied to the load 54, the overvoltage protection function is activated, and the power supply from the power supply 52 to the load 54 may be stopped. This is because the overvoltage is not applied to the load 54 due to the abnormality of the secondary power source 522, but the load current I
_This is a malfunction caused by a sharp decrease in _L and a response delay of the stabilization loop of the secondary power supply 522. This problem is peculiar to the remote sensing power supply system 50 having long power supply lines 561 and 562, that is, a large conduction resistance r.

To eliminate this malfunction, it is conceivable to delay the response of the overvoltage protection operation. However, this would impair the ability to protect the load 54 at high speed when an overvoltage occurs due to a device abnormality. Further, as a technique for eliminating a malfunction of the power supply system due to a sudden decrease in the load current, there are techniques described in JP-A-23-110434, JP-A-56-1782, and the like.
These techniques attempt to eliminate malfunctions of the protection circuit by detecting a drastic decrease in load current and controlling the output voltage of the power supply to reduce or suppress the output voltage accordingly. There is a constraint that the response speed of the protection circuit must be slower than the response speed of the reduction / suppression of the output voltage.

[0009]

SUMMARY OF THE INVENTION An object of the present invention is to provide a load overvoltage protection device used in a remote sensing type power supply system, which eliminates malfunctions caused by a sudden decrease in load current, operates at high speed, and has high reliability and reliability. An object of the present invention is to provide a load overvoltage protection device with high operability.

[0010]

SUMMARY OF THE INVENTION A load overvoltage protection device according to the present invention supplies power of a power supply via a power supply line to a load provided far away from the power supply, It is used in a remote sensing power supply system that detects a load voltage applied to the load via a sensing line and controls an output voltage of the power supply so that the load voltage becomes constant. In addition, the load overvoltage protection device according to the present invention includes an overvoltage detection unit that outputs a power supply stop signal when the overvoltage of the load voltage is detected, and the power supply stop signal output from the overvoltage detection unit outputs the load from the power supply. A power supply stop unit that stops power supply to the load, a load current detection unit that outputs a power supply continuation signal when a sudden decrease in load current flowing to the load is detected, and a power supply output from the load current detection unit. A power supply continuation unit for continuing power supply from the power supply to the load by a continuation signal.

The load current detector includes a current sensor for detecting the load current, a differential circuit for outputting a voltage corresponding to a differential value of the load current detected by the current sensor, and a differential circuit for outputting a voltage. A negative voltage detector that outputs a negative voltage detection signal when the voltage is less than or equal to a negative constant; and the power supply continuation signal having a pulse width for a predetermined time triggered by the negative voltage detection signal output from the negative voltage detector. And a pulse generating circuit for outputting the same. Further, the pulse width may be set to be longer than a response speed of a load voltage stabilization loop of the remote sensing power supply system.

The load voltage is detected by, for example, an overvoltage detection unit via a remote sensing line. If the load voltage is an overvoltage higher than the reference value, a power supply stop signal is output from the overvoltage detection unit to the power supply stop unit to protect the load. As a result, the power supply from the power source to the load is stopped. On the other hand, the load current detected by the current sensor is output to a differentiating circuit. At this time, if the load current decreases sharply, a negative voltage having a large absolute value is output from the differentiating circuit, so that a negative voltage detection signal is output from the negative voltage detector to the pulse generation circuit. Then, a power supply continuation signal having a pulse width for a predetermined time after the input of the negative voltage detection signal is output from the pulse generation circuit to the power supply continuation unit. As a result, while the power supply continuation signal is being output, the power supply stop signal output from the overvoltage detection unit to the power supply stop unit is cut off. As described above, when the load current suddenly decreases, the overvoltage protection function is temporarily disabled.

[0013]

FIG. 1 is a block diagram showing an embodiment of a load overvoltage protection device according to the present invention. Less than,
A description will be given based on this drawing. However, the same parts as those in FIG.

The load overvoltage protection device 10 has a load voltage V _L
An overvoltage detection unit 62 that outputs a power supply stop signal a when an overvoltage is detected, and a power supply stop unit 64 that stops power supply from the power supply 52 to the load 54 by the power supply stop signal a output from the overvoltage detection unit 62. If, upon detecting a sudden decrease of the load current I _L flowing through the load 54 and the load current detector 12 for outputting a power supply continuation signal b, from the load current detecting unit 12 power 52 by the power supply continuation signal b output from the And a power supply continuation unit 14 for continuing power supply to the load 54.

The load current detector 12, the load current and a current sensor 121 that detects the I _L, a differentiating circuit for outputting a voltage c corresponding to the differential value dI _L / dt of the load current I _L is detected by the current sensor 121 122, a negative voltage detector 123 that outputs a negative voltage detection signal d when the voltage c output from the differentiating circuit 122 is equal to or less than a negative constant, and a negative voltage detector 12
And a pulse generation circuit 124 that outputs a power supply continuation signal b having a pulse width for a certain period of time, triggered by the negative voltage detection signal d output from the signal generator 3. The power supply continuation unit 14 is, for example, an electromagnetic relay or a switching circuit that is opened by the power supply continuation signal b, and is interposed between the overvoltage detection unit 62 and the power supply stop unit 64.

Next, the operation of the load overvoltage protection device 10 will be described.

The secondary power supply 522 is connected to the power supply line 56
Supplies power to the load 54 through the 1,562, through a remote sensing line 581, 582 to detect the load voltage V _L, the output so that the load voltage V _L by the voltage regulation loop becomes a target value Vm The voltage Vo is controlled. That is, the output voltage Vo is
To compensate for voltage drop I _L · r where the conduction resistance r of 61,562 produced by the load current I _L, Vm + I _L
-It is controlled to be r. Also, the load voltage V
_L is detected by the load voltage detector 621 via the remote sensing lines 581 and 582, and compared with the reference voltage value Vr by the overvoltage detector 622. V _L >
In the case of Vr, in order to protect the load 54, the power supply stop signal a is output from the overvoltage detector 622 to the power supply stop unit 64.
Output to Thus, the power supply from the power supply 52 to the load 54 is stopped.

The load current I detected by the current sensor 121
_L is output to the differentiating circuit 122. Load current I _L
Sharply decreases, the differential circuit 122 outputs a negative voltage c having a large absolute value, and the negative voltage detector 123 outputs a negative voltage detection signal d to the pulse generation circuit 124.
The pulse generation circuit 124 outputs a power supply continuation signal b having a pulse width for a certain period of time after the input of the negative voltage detection signal d to the power supply continuation unit 14. While the power supply continuation signal b is being input, the power supply continuation unit 14
2 interrupts the power supply stop signal a output to the power supply stop unit 64. Therefore, by the state of the overvoltage protection function may not work temporarily, it can be avoided to stop the power supply by a sharp decrease in the load current I _L, eliminating troubles may be caused in the operation.

The pulse width of the power supply continuation signal b is preferably set to be longer than the response speed of the load voltage stabilization loop by remote sensing of the secondary power supply 522.
In this case, between the load current I _L the load voltage V _L rises secondary power 522 generated by a reduction of up to return to the target value Vm, surely current supply stop signal a is interrupted. Of course, the pulse width of the power supply continuation signal b is
Even if it is set equal to or shorter than the response speed of the load voltage stabilization loop by the remote sensing of No. 22, a corresponding effect can be obtained.

Meanwhile, when an overvoltage occurs due to abnormality in the secondary power source 522, by the load current I _L is increased, a positive voltage c is outputted from the differentiating circuit 122. Therefore, since the negative voltage detection signal d is not output from the negative voltage detector 123, the power supply continuation signal b is not output from the pulse generation circuit 124. Therefore, since the power supply continuation unit 14 does not operate, if the power supply stop signal a based on the overvoltage of the load 54 is output, the power supply of the secondary power supply 522 is stopped, and the load 54 is protected.

[0021]

According to the load overvoltage protection device of the present invention, a load current detection unit that outputs a power supply continuation signal when a sudden decrease in load current is detected, and a power supply from the power supply to the load based on the power supply continuation signal. With the power supply continuation unit that keeps supplying power, the overvoltage protection function can be operated only when overvoltage occurs due to power supply abnormality, so the overvoltage protection function malfunctions due to sudden decrease in load current and power supply response delay Can be eliminated.

Further, there is no restriction that the response speed of the overvoltage protection function must be reduced in order to avoid a malfunction when the load current is sharply reduced. For this reason, the response speed of the overvoltage protection function can be extremely increased, so that the power supply to the power supply can be stopped at a high speed when an overvoltage occurs due to an abnormality in the power supply.

[Brief description of drawings]

FIG. 1 is a block diagram showing one embodiment of a load overvoltage protection device according to the present invention.

FIG. 2 is a block diagram showing a conventional load overvoltage protection device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 Load overvoltage protection apparatus 12 Load current detection part 14 Power supply continuation part 50 Remote sensing power supply system 52 Power supply 54 Load 62 Overvoltage detection part 64 Power supply stop part 121 Current sensor 122 Differentiation circuit 123 Negative voltage detector 124 Pulse generation circuit 561 , 562 Power supply line 581, 582 Remote sensing line a Power supply stop signal b Power supply continuation signal _IL load current _VL load voltage Vo output voltage

Claims (3)

[Claims] 1. A power supply line is used to supply electric power of the power supply to a load provided at a location far from the power supply, and a load voltage applied to the load is supplied via a remote sensing line. Detecting, controlling the output voltage of the power supply so that the load voltage is constant, used in a remote sensing power supply system, and an overvoltage detection unit that outputs a power supply stop signal when detecting an overvoltage of the load voltage, In a load overvoltage protection device including a power supply stop unit that stops the power supply from the power supply to the load by the power supply stop signal output from the overvoltage detection unit, a rapid decrease of the load current flowing in the load When the load current detection unit that outputs a power supply continuation signal when it detects it and the power supply continuation signal output from this load current detection unit Load overvoltage protection device is characterized in that a power supply continues section to continue the supply of power from the electric supply to the load. 2. The load current detection unit includes: a current sensor that detects the load current; a differentiation circuit that outputs a voltage corresponding to a differential value of the load current detected by the current sensor;
A negative voltage detector that outputs a negative voltage detection signal when the voltage output from the differentiating circuit is equal to or less than a certain negative value, and a pulse width for a predetermined time triggered by the negative voltage detection signal output from the negative voltage detector The load overvoltage protection device according to claim 1, further comprising: a pulse generation circuit configured to output the power supply continuation signal. 3. The load overvoltage protection device according to claim 1, wherein the pulse width is set longer than a response speed of a load voltage stabilization loop of the remote sensing power supply system.