JPH10327534A - Power supply - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply, capable of protecting other devices from an overcurrent which occurs to the power supply and of unfailingly detecting its overcurrent abnormality, even if power is supplied from a single constant voltage source to a plurality of devices. SOLUTION: If an overcurrent occurs, it is detected by a current-detecting circuit 11, which compares a load current I flowing into a device M with a reference current value I*, and a current-controlling element 12 is actuated according to the output of the current-detecting circuit 11. Because the load current 1 is limited by the reference current I* and an overcurrent which flows into the device M is controlled, no overcurrent causes a voltage drop to occur, thereby affecting no other devices. At this time, a time-counting circuit 13 measures a period of time, when the load current I continuously exceeds the reference current I*. When this continuing time exceeds a standard continuing time which corresponds to the continuing time of a transient overcurrent, which occurred to the power supply, i.e., when the overcurrent caused by a short circuit, etc., flows continuously, the overcurrent is detected as abnormality of the power supply.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply device, and more particularly, to a power supply device in which a single constant voltage source supplies power to a plurality of devices. The present invention relates to a power supply device capable of avoiding affecting other devices.

[0002]

2. Description of the Related Art Conventionally, for example, in a system or the like comprising a plurality of terminal devices and a main control device for controlling these terminal devices, each device has an individually stabilized power supply circuit, It runs on power from the circuit.

It is conceivable to use a common voltage source for each device, but in this case, there are the following problems. In other words, the devices connected to a single constant voltage source operate independently of each other. Therefore, when the power of the device is turned on or the load fluctuates during operation, the current transiently exceeds the rated value. Flows, there is a possibility that a malfunction of another connection device may be caused by a voltage drop accompanying the flow. Further, when a failure such as a short circuit occurs in any device, the failure spreads to all connected devices.

[0004] For this reason, especially when it is necessary to use a common voltage source, there is a problem as described above. Therefore, a circuit for immediately shutting off the power supply when an excessive current or voltage drop is detected is provided. Or providing a circuit for limiting the current value to a constant value.

[0005]

However, if a circuit for interrupting the power supply as described above is provided, the power supply is interrupted even for a transient overcurrent generated when the power is turned on, for example. However, there is a problem in that a device malfunctions, such as stopping the device although it is not necessary to stop the device. In addition, when a circuit for limiting the current to a constant value is provided, for example, even if a short circuit abnormality occurs in the device, the circuit is limited to a constant value. Because it is not possible to detect whether the current is excessive due to a failure such as an abnormality, it is not possible to detect that a failure has occurred in the device, and the failure is left as it is, resulting in a more serious failure. There is a problem that there is a possibility.

Accordingly, the present invention has been made in view of the above-mentioned conventional unsolved problem, and there is provided a power supply device which supplies power to a plurality of devices by using a single constant voltage source. It is an object of the present invention to provide a power supply device capable of preventing an excessive current generated in a device from affecting another device and accurately detecting an excessive current abnormality of the device.

[0007]

According to a first aspect of the present invention, there is provided a power supply apparatus comprising: a DC power supply for supplying power to a plurality of loads; and a load current flowing through each of the loads. A current detection circuit that detects whether or not the load current value is larger than a reference current value set for each load; and when the current detection circuit detects that the load current value is larger than the reference current value, And a current suppressing circuit for suppressing a flowing load current.

According to the present invention, power is supplied from a single DC power supply to a plurality of loads. At this time, the current detection circuit detects whether a load current value, which is a current value flowing through each load, is larger than a reference current value preset for each load. As the reference current value, for example, a rated current value of a load or the like is set. When the load current value is larger than the reference current value, that is, when an excessive current is flowing, the load current flowing to the corresponding load is suppressed by the current suppression circuit.

Therefore, for example, when power is supplied from a single constant voltage source to a plurality of loads such as a terminal device, when power is applied to one of the loads, or when a load fluctuates in any of the loads, etc. In such a case, there is a possibility that an excessively large current flows transiently, and a voltage drop caused by the excessive current fluctuates the power supplied to another load, thereby causing a malfunction.

However, when an excessive current is supplied, the excessive current is detected by the current detecting circuit, and the current flowing through the load where the excessive current is generated is suppressed by the current suppressing circuit. The current is suppressed, and a voltage drop associated with the current is suppressed, thereby preventing a malfunction of another load.

According to a second aspect of the present invention, there is provided a power supply device comprising: a measuring circuit for measuring a duration during which the load current value exceeds the reference current value; and a measuring time of the measuring circuit for each of the loads. When the set standard duration is exceeded, an abnormality detection circuit that determines that an abnormality has occurred in the corresponding load, and power supply from the DC power supply to the plurality of loads and supply of power based on the determination of the abnormality detection circuit. And a cutoff control circuit capable of controlling cutoff.

According to the present invention, when the current detection circuit detects that the load current value flowing through the load exceeds the predetermined reference current value, the state where the load current value exceeds the reference current value continues. The measured duration is measured by a measurement circuit, and when the measured time exceeds a preset standard duration, the abnormality detection circuit detects that an abnormality has occurred in the corresponding load. And
The cutoff control circuit operates based on the result of the determination by the abnormality detection circuit. For example, when the abnormality detection circuit determines that an abnormality has occurred, the power supply to the load is interrupted.

Accordingly, for example, if the standard duration is set according to the duration of the excessive current generated when the load is turned on or when the load fluctuates, the excessive current is generated when the load is turned on or the load fluctuates. In the event that
Since this excessive current falls within the standard continuation time, the abnormality detection circuit does not detect it as a load abnormality. However, if an excessive current occurs due to a load short circuit, etc., the excessive current does not fall within the standard duration, so the abnormality detection circuit detects the load as abnormal and the cutoff control circuit operates accordingly. Then, the power supply to the corresponding load is cut off. Accordingly, the abnormality detection of the load with respect to the excessive current is accurately performed, and the power supply to the load in which the abnormality has occurred is cut off accurately.

The power supply unit according to a third aspect of the present invention includes control means for controlling the cutoff control circuit based on the information on the plurality of loads or information on the entire system including the plurality of loads. It is characterized by:

According to the present invention, the control means can control the plurality of loads based on information such as whether each load is operating normally or information such as the operating state of the entire system including the plurality of loads. , The cutoff control circuit is controlled,
As a result, power supply from the control power supply to the plurality of loads and supply power cutoff are performed.

Therefore, power supply can be controlled according to the status of each load, and power supply to a plurality of loads is performed accurately. Further, in the power supply device according to claim 4 of the present invention, at least one of the current detection circuit and the measurement circuit is formed so that the reference current value or the standard duration can be changed, At least one of a current value and the standard duration can be controlled.

According to the present invention, at least one of the current detection circuit and the measurement circuit has a circuit configuration capable of changing the reference current value or the standard continuation time. Variable control.

Therefore, when power is supplied from a single DC power supply to a plurality of loads, it is necessary to set a reference current value or a standard duration suitable for each of the plurality of loads. Since at least one of these can be set by the control means, for example, the control means specifies the load fluctuation state of each load and sets the reference current value or the standard continuation time based on this, so that accurate setting can be performed. Done.

[0019]

Embodiments of the present invention will be described below. FIG. 1 shows a schematic configuration of a power supply device according to the present invention. The power supply device 10 includes a constant voltage source 1 that is a power source of a plurality of devices M and generates a DC constant voltage value V. A power protection circuit 2 provided for each device M;
And a control circuit 3 for controlling the power supply protection circuit 2.

FIG. 2 shows the configuration of the power supply protection circuit 2, wherein the power line L of the grounded constant voltage source 1 is
It is connected to _one output terminal T _{1 of the} power supply protection circuit 2. The other output terminal T ₂ of the power supply protection circuit 2 is grounded, and the input terminals of the output terminals T ₁ and T ₂ and the device M is connected.

Whether the load current I flowing through the device M is greater than a predetermined reference current value I ^* on the power line L between the constant voltage source 1 and the output terminal T ₁ , that is, whether the load current is excessive A current detection circuit 11 for detecting whether or not the load current I is flowing and a current control element 12 for suppressing the load current I when the load current I flowing through the device M exceeds the reference current value I ^* are inserted. Also, a time period between the output of the current detection circuit 11 and the control circuit 3 in which the state in which the current detection circuit 11 detects that the load current I exceeds the reference current value I ^* continues. That is, a time counting circuit 13 for measuring the time during which an excessive current continues to occur is inserted, and the output signals of the time counting circuit 13 and the control circuit 3 are supplied to the current detection circuit 11 via the OR circuit 14. It is supposed to be.

The current detecting circuit 11 includes the constant voltage source 1
Resistor 21 having a resistance value R connected in series with a power line L
An amplifier 22 to which the potentials at both ends of the resistor 21 are input;
It comprises a variable voltage source 23 interposed between the high-potential side of the resistor 21 and the amplifier 22 and a switch 24 interposed between the low-potential side of the resistor 21 and the amplifier 22.

The variable voltage source 23 has a reference set voltage ΔV
, And is formed to have a variable voltage value. The reference setting voltage ΔV is set according to a product of a reference current value I ^* that defines a maximum current value to the device M, such as a rated current value of the device M, and a resistance value R of the resistor 21. M is set for each M.
The reference setting voltage ΔV can be updated and set by the control circuit 3. The positive side of the variable voltage source 23 is connected to the power line L, and the negative side is connected to the non-inverting input terminal 22 ⁺ of the amplifier 22.

The switch 24 has a contact 24a or 24
b and a switch that can selectively connect the contact 24c, the contact 24a is connected to the power line L, and the contact 24b
Is grounded, and the contact 24c is connected to the inverting input terminal 2 of the amplifier 22.
2 ^- is connected. And this switch 24
It operates according to a command signals S ₁ from the OR circuit 14,
For example, when the command signal S ₁ is "0", the contact 24a
And rendered conductive and the contact 24c, when the command signal S ₁ is "1", the contact 24b and the contact 24c is adapted to conduct.

Therefore, the difference (V−ΔV) between the voltage V of the constant voltage source 1 and the reference set voltage ΔV of the variable voltage source 23 is input to the non-inverting input terminal 22 ⁺ of the amplifier 22. The command signal S ₁ is “0” at the input terminal 22 ^−.
, The difference (V−R · I) between the voltage V of the constant voltage source 1 and the voltage drop R · I due to the resistor R and the load current I is input, and when the command signal S ₁ is “1”, A potential is input.

[0026] Then, the amplifier 22 has a non-inverting input terminal 22 ⁺ and the inverting input terminal 22 ^- in accordance with the difference of the signal input to, and is capable of outputting an output voltage A _OUT in the range of 0 to + V . Therefore, when the voltage drop RI and the reference setting voltage ΔV satisfy RI ≦ ΔV, the output voltage A _OUT ≒
0, and when R · I> ΔV, the output voltage is 0 <A
_OUT <V.

On the other hand, a current control element 12 such as a P-channel MOS transistor is inserted between the resistor 21 of the power line L and the output terminal T _1, and the output terminal of the amplifier 22 is connected to its gate terminal. A _OUT is applied.

That is, the voltage drop RI and the reference set voltage Δ
When V is R ・ I ≦ ΔV, the output voltage A _OUT ≒ 0, so that the current control element 12 does not conduct to limit the load current I to the device M. Sometimes, the output voltage takes a value of 0 <A _OUT <V, and the load current I is limited by the current control element 12, so that the load current I is limited to a current value determined by the reference set voltage ΔV. It has become.

The time counting circuit 13 includes the amplifier 22
Amplifier 1 for converting the output voltage A _OUT of FIG. 1 into a binary value of, for example, “1” or “0” according to a preset threshold value.
3a and a counter 13b which starts counting when the output signal of the amplifier 13a becomes "1" and resets the count value C when it becomes "0". The output side of the counter 13b is connected to the control circuit 3 and the OR circuit 14.

The threshold value of the amplifier 13a is set to a value for determining whether or not the output voltage A _OUT is at the ground potential. The counter 13b when the count value C becomes the reference integrated value C ^* set in advance, and outputs a count-up signal S _2, for example, as "1". The reference integrated value C ^* is a value set in advance for each device M, and is, for example, a continuous time when a power supply of the device is turned on or a transient excessive current occurs due to a load change of the device. Is set according to.

The OR circuit 14 includes the counter 13
b and count-up signal S ₂ of the power supply control signal S ₃ that instructs the supply or interruption of power to the apparatus M from the control circuit 3 is input, the switch 24 these logical sum as a command signals S ₁ , And the switch 24 is controlled accordingly.

[0032] That is, the power supply control signal S ₃ from the control circuit 2 is count-up signal S ₂ from the instruction to "1" or counter 13b interruption of power in the feed, the count value C is counted up When the value is "1", the switch 24 operates to electrically connect the contact 24b and the contact 24c. When the contacts 24b and 24c are turned on, the output voltage A _OUT ≒ + V
Therefore, the current control element 12 becomes non-conductive,
The power supply to the device M is cut off.

[0033] Then, the control circuit 3 includes, for example, a microcomputer or the like, from the power supply protection circuit 2 corresponding to each device M, reads the count-up signal S ₂ of the counter 13b, abnormality occurs in the apparatus M And adjusts the reference set voltage ΔV of the variable voltage source 23 and the reference integrated value C ^* of the counter 13b. Further, the power supply control signal S ₃ is output, and is output as “1” when the power supply to the device M is cut off and “0” when the power supply is performed. The supply or the interruption of the supply power is controlled.

Here, the device M corresponds to a load, the constant voltage source 1 corresponds to a DC power supply, the current control element 12 corresponds to a current suppressing circuit, the counter 13b corresponds to a counting circuit, and the counter 13b counts. corresponds to the processing abnormality detecting circuit for outputting a count-up signal S ₂ "1" when the value C exceeds the reference integrated value C ^*, corresponding to the switch 24 is shut down control circuit, the control circuit 3 controlling means Yes, it is.

Next, the operation of this embodiment will be described. When all the devices M are operating normally, a predetermined reference current value I ^* flows to each device M. Therefore, the voltage drop R.I caused by the resistor 21 and the load current I flowing through the device M and the reference set voltage .DELTA.V become RI.multidot..DELTA.V, so that the output voltage _A.sub.OUT .noteq.0 of the amplifier 22 becomes Becomes conductive, and the load current I flowing through the device M is not limited by the current control element 12.

In this state, if an excessive current flows through the device M for some reason, the power supply protection circuit 2 corresponding to the device M
In the current detection circuit 11, the current larger than usual flows, so that the voltage drop due to the resistor 21 increases, so that the output voltage of the amplifier 22 takes a value of 0 <A _OUT <V. Therefore, since the gate voltage to the current control element 12 increases, the load current I is limited by the current control element 12. Then, the amplifier 22 operates so that the potentials input to the inverting input terminal 22 ⁻ and the non-inverting input terminal 22 ⁺ coincide, and thus operates so that R · I = ΔV. Since ΔV is set according to the reference current value I ^* and the resistance value R of the resistor 21, that is, the operation is performed so that the load current I and the reference current value I ^* coincide with each other. Is limited to the reference current value I ^* .

At this time, if the cause of the occurrence of the excessive current is caused by turning on the power of the apparatus or a load change, it is a transient excessive current. Since the voltage becomes R の I ≒ ΔV, the output voltage A _OUT of the amplifier 22 becomes A _OUT ≒ 0, the current control element 12 becomes conductive, and the load current I to the device M is not limited.

In the time counting circuit 13, when an excessive current occurs, the output voltage A _OUT of the amplifier 22 becomes 0 <A
_OUT <V, which is higher than the ground potential.
3a becomes "1", and the counter 13
b starts counting. If the excess current is transient, this will eventually subside and the output voltage A _OUT of the amplifier 22 will be A _OUT ≒ 0, and the output of the amplifier 13a will be “0”. Therefore, in response to this, the counter 13b
Resets the count value C.

The reference integrated value C ^* of the counter 13b is
Since the setting is made according to the duration of the transient excessive current, in the case of the transient excessive current, the count value C is reset before the counter 13b counts up. Therefore, the count-up signal S ₂ is “0”
The switch 24 is connected to the contact 24a and the contact 2
Maintaining the state in which the is conductive 4c, power supply to the device M ₂ is subsequently performed.

On the other hand, if the current is excessive due to the occurrence of a short circuit in the device M, the output voltage of the amplifier 22 becomes zero.
<A _OUT <V is maintained, and the output of the amplifier 13a continuously becomes “1”. Therefore, when the count value C of the counter 13b increases and exceeds the reference integrated value C ^* ,
The counter 13b, and the count-up signal S ₂ "1"
, The switch 24 operates and the contact 24
b and the contact 24c are conducted. Thereby, the amplifier 2
2 of the inverting input terminal 22 ^- because in so that the ground potential is input, the output voltage A _OUT ≒ V next to the amplifier 22,
The current control element 12 is turned off, and the current supply to the device M is stopped.

As described above, when a current equal to or more than the reference current value I ^* flows through the device M, this is detected by the current detection circuit 11, and the load current I is limited so as to become the reference current value I ^*. Therefore, it is possible to suppress the flow of an excessive current exceeding the rated value to the device M. Therefore, it is possible to avoid a voltage drop due to an excessive current, and to prevent the constant voltage source 1 from affecting other devices to which power is being supplied.

When an excessive current flows, the power supply is not stopped but the load current I is changed to the reference current value I ^*.
Therefore, the apparatus can be continuously executed without stopping the operation of the apparatus in a transitional state such as when the power is turned on.

The duration of the excessive current is measured, and based on the duration, whether the current is a transient excessive current or a continuous excessive current, that is, an abnormality such as a short circuit is detected. Since it is determined whether or not there is, an abnormality such as a short circuit of the device M can be accurately detected. Further, since the abnormality of the device M can be reliably detected, it is possible to avoid a more serious failure due to the continuous power supply while the failure has occurred.

When the abnormality of the apparatus M is detected, the switch 24 is immediately activated to cut off the power supply to the apparatus M, so that the influence of the abnormality of the apparatus M on other apparatuses can be quickly avoided. can do.

Therefore, even when power is supplied from a single constant voltage source to a plurality of devices, there is no effect of excessive current due to load fluctuations of other devices, and abnormalities of the devices are not caused. Can also be reliably detected.
Also, since it is not necessary to provide a power supply circuit or the like for each device,
Cost can be reduced.

In the control circuit 3, the reference set voltage ΔV of the variable voltage source 23 of the current detection circuit 11 or the reference integrated value C ^* of the counter 13b can be set. Source 23 or counter 1
These settings can be easily performed without operating 3b.

In the control circuit 3, the switch 24
Can be controlled, power supply to the plurality of devices M and cutoff of supplied power can be easily performed.
In particular, for example, when this power supply device is applied to a system including a plurality of terminal devices and a main control device that controls these terminal devices, if the main control device is provided with the control circuit 3, the main control device is provided. In the device, each terminal device can be controlled, and power supply and cutoff can be controlled.

Therefore, for example, the operation status and operation status of each device, such as what processing stage each terminal device is in and the status of each terminal device to operate, are collected from each terminal device. Based on the information, for each terminal device, it is determined whether or not it is necessary to supply power and which does not need to supply power, or which terminal has a higher or lower priority for supplying power. Based on these, the power supply control signal S from the control circuit 3 of the main control device to the power supply protection circuit 2 corresponding to each terminal device.
If output _3, because it is possible to perform power supply and interruption of power supply in accordance with the power supply control signal S _3, it is possible to effectively perform power supply to each terminal device.

In the control circuit 3, since the reference set voltage ΔV of the variable voltage source 23 of the current detection circuit 11 or the reference integrated value C ^* of the counter 13b can be set, the terminal device corresponding to the power supply protection circuit 2 is changed. In such a case, the reference set voltage ΔV or the reference integrated value C can be easily obtained from the main controller.
^* Can be changed. In addition, load characteristics or the frequency of malfunctions are analyzed based on various information of each terminal device,
Based on this, the reference set voltage ΔV or the reference integrated value C ^*
, The characteristics of the power supply protection circuit 2 for each terminal device can be further optimized.

Therefore, it is possible to efficiently supply power to each terminal device in the system using a single constant voltage source 1, thereby improving system operability and rationalizing the power supply circuit. In addition, cost reduction accompanying this,
Power consumption can be reduced.

In the above embodiment, the case where a MOS transistor is used as the current control element has been described. However, the present invention is not limited to this, and a PNP transistor can be used. In this case, the base circuit needs a current limiting resistor.

[0052]

As described above, according to the first aspect of the present invention,
According to the power supply device according to the above, the current detection circuit detects whether the load current value to the load receiving the power supply from the DC power supply is larger than the reference current value, and the current detection circuit detects an excessive current. In such a case, the load current flowing to the corresponding load is suppressed by the current suppression circuit. Therefore, even when power is supplied to a plurality of loads by using a single DC power supply, any one of the loads may be generated. In addition, it is possible to surely avoid inducing a malfunction of another load due to a voltage drop caused by the excessive current.

According to the power supply device of the second aspect of the present invention, the time during which the load current value to the load exceeds the reference current value is measured. Since the power supply to the load is detected and detected, if the duration of the transient excessive current due to the load fluctuation of the load is set as the standard duration, the transient excessive current is set. Otherwise, that is, if an excessive current is continuously generated due to a load short circuit or the like, an abnormality is detected. Therefore, it is possible to reliably detect an abnormality of the load with respect to the excessive current, and to shut off supply power when the abnormality is detected. .

Further, according to the power supply device of the third aspect of the present invention, the power control circuit can be controlled by the control means based on the operation information of each load or the operation information of the entire system including a plurality of loads. Therefore, it is possible to accurately supply power to each load.

Further, according to the power supply device of the fourth aspect of the present invention, the control means can change at least one of the reference current value of the current detection circuit and the standard duration of the measurement circuit. Accordingly, the appropriate reference current value and the standard continuation time can be set by setting according to the actual operation status such as the load characteristics of each load or the frequency of malfunction.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a power supply device to which the present invention is applied.

FIG. 2 is a block diagram illustrating a configuration of a power supply protection circuit.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 constant voltage source 2 power supply protection circuit 3 control circuit 11 current detection circuit 12 current control element 13 time counting circuit 13 b counter 23 variable voltage source 24 switch

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Masatoshi Sugimoto 1 Fuji-Facom Control Co., Ltd., Fuji-cho, Hino-shi, Tokyo

Claims (4)

[Claims] A DC power supply for supplying power to a plurality of loads; a current detection circuit for detecting whether a load current value flowing through each of the loads is greater than a reference current value set for each of the loads; A power supply device comprising: a current suppression circuit that suppresses a load current flowing to a corresponding load when a current detection circuit detects that the load current value is larger than the reference current value. 2. A measuring circuit for measuring a duration during which the load current value exceeds the reference current value, and when a measurement time of the measuring circuit exceeds a standard duration time set for each load. An abnormality detection circuit that determines that an abnormality has occurred in the load, and a cutoff control circuit that can control power supply from the DC power supply to the plurality of loads and cutoff of supply power based on the determination of the abnormality detection circuit. The power supply device according to claim 1, wherein: 3. The control device according to claim 1, further comprising a control unit that controls the cutoff control circuit based on information on the plurality of loads or information on an entire system including the plurality of loads. Power supply. 4. At least one of the current detection circuit and the measurement circuit is formed so as to be able to change the reference current value or the standard duration, and the control means includes at least one of the reference current value and the standard duration. 4. The power supply according to claim 3, wherein one of the power supplies is controllable.