JP7103627B2 - Overcurrent protection circuit, overcurrent protection system, overcurrent protection method and program by overcurrent protection circuit - Google Patents

Description

The present invention relates to an overcurrent protection circuit, an overcurrent protection system, an overcurrent protection method and a program by the overcurrent protection circuit.

In a device to which power is supplied, for example, if the input terminal that receives the power is short-circuited to the ground terminal, an overcurrent exceeding the rating may flow through the device. Therefore, some devices to which power is supplied include an overcurrent protection circuit that suppresses the overcurrent.
Patent Document 1 discloses a technique relating to an overcurrent protection circuit as a related technique.

Japanese Unexamined Patent Publication No. 2017-046570

By the way, in the overcurrent protection circuit described in Patent Document 1, the circuit that detects the overcurrent operates to turn off the power supply that supplies power to the input terminal, and then the power supply that supplies power to the control unit is also available. When turned off, overcurrent detection is reset. Therefore, if the power supply that supplies power to the input terminal is turned on again without removing the cause of the overcurrent, the current will flow through the device until the overcurrent is detected again.
Therefore, there is a demand for a technique that does not allow an overcurrent to flow through the device even when the device is restarted without removing the cause of the overcurrent after detecting the overcurrent in the device and stopping the supply of electric power.

Each aspect of the present invention aims to provide an overcurrent protection circuit, an overcurrent protection system, an overcurrent protection method and a program by the overcurrent protection circuit, which can solve the above-mentioned problems.

In order to achieve the above object, according to one aspect of the present invention, the overcurrent protection circuit includes a first switch provided in series with the power supply path and a detection unit for detecting the current flowing through the path. The first determination unit determines whether or not the current detected by the detection unit is an overcurrent, and the determination unit determines that the current detected by the detection unit is an overcurrent. Control to supply a control signal for closing the switch to the first switch, and after the determination unit determines that the current detected by the detection unit is an overcurrent, the first switch is opened. A control signal generator that supplies a signal to the first switch, the first terminal having a first terminal and a second terminal, and a control signal for opening or closing the first switch. A comparator having a second switch, a third terminal, a fourth terminal, and a fifth terminal to be supplied to the switch, and a reference voltage is applied to the third terminal to be applied to the fourth terminal. When the current is higher than the reference voltage applied to the third terminal, a signal capable of controlling the first switch in the closed state is output from the fifth terminal to the first terminal, and the above is described. When the voltage at the fourth terminal is lower than the reference voltage applied to the third terminal, a signal capable of controlling the first switch in the open state is transmitted from the fifth terminal to the first terminal. When the comparator for outputting to the fourth terminal, the disconnection means for disconnecting the path for supplying a voltage higher than the reference voltage to the fourth terminal, and the determination unit for determining that the current is not an overcurrent, the first The disconnection means is controlled so that the connection between the terminal 1 and the second terminal is controlled to be closed and the disconnection means does not disconnect the path, and the current detected by the determination unit is an overcurrent. A control unit that controls the space between the first terminal and the second terminal in an open state and controls the disconnection means so that the disconnection means disconnects the path. A control signal generator having the above .

According to another aspect of the present invention, the overcurrent protection system includes the overcurrent protection circuit described above and a device to which power is supplied via the overcurrent protection circuit.

According to another aspect of the present invention, the overcurrent protection method by the overcurrent protection circuit has a first switch provided in series with the power supply path, and a second terminal having a first terminal and a second terminal. This is an overcurrent protection method using an overcurrent protection circuit including a switch, a comparator having a third terminal, a fourth terminal, and a fifth terminal, and a disconnection means, and detects a current flowing through the path. The control signal for closing the first switch is sent to the first switch until it is determined whether or not the detected current is an overcurrent and the detected current is determined to be an overcurrent. The first switch includes supplying a control signal for opening the first switch to the first switch after determining that the detected current is an overcurrent. A control signal for opening or closing the switch is supplied to the first switch, a reference voltage is applied to the third terminal, and a voltage at the fourth terminal is applied to the third terminal. When the reference voltage is higher than the reference voltage, a signal that can control the first switch in the closed state is output from the fifth terminal to the first terminal, and the voltage at the fourth terminal is the first. When the current is lower than the reference voltage applied to the terminal 3, a signal that can control the first switch in the open state is output from the fifth terminal to the first terminal, and the fourth. When it is determined that the path for supplying a voltage higher than the reference voltage to the terminal is not overcurrent and the detected current is not an overcurrent, the connection between the first terminal and the second terminal is closed. When the disconnection means is controlled so that the disconnection means does not disconnect the path, and the detected current is determined to be an overcurrent, the first terminal and the second disconnection means. It includes controlling the connection with the terminal in an open state and controlling the disconnection means so that the disconnection means disconnects the path .

According to another aspect of the present invention, the program comprises a first switch provided in series with a path for supplying power, a second switch having a first terminal and a second terminal, and a third terminal. , A computer of an overcurrent protection circuit including a comparator having a fourth terminal and a fifth terminal and a disconnection means detects the current flowing in the path, and whether or not the detected current is an overcurrent. A control signal for closing the first switch is supplied to the first switch until it is determined that the detected current is an overcurrent, and the detected current is an overcurrent. After determining that there is, the control signal for opening the first switch is supplied to the first switch, and the control signal for opening or closing the first switch is supplied to the first switch. When the reference voltage is applied to the third terminal and the voltage at the fourth terminal is higher than the reference voltage applied to the third terminal, the first switch is supplied. Is output from the fifth terminal to the first terminal, and the voltage at the fourth terminal is lower than the reference voltage applied to the third terminal. A signal that can control the first switch in the open state is output from the fifth terminal to the first terminal, and a path for supplying a voltage higher than the reference voltage to the fourth terminal is disconnected. When it is determined that the detected current is not an overcurrent, the connection between the first terminal and the second terminal is controlled to be closed, and the disconnection means does not disconnect the path. When it is determined that the detected current is an overcurrent, the disconnection means is controlled so as to open the space between the first terminal and the second terminal, and the disconnection means is used. Controls the disconnection means so as to disconnect the path .

According to each aspect of the present invention, even if the device is restarted in a state where the cause of the overcurrent has not been eliminated after the overcurrent is detected in the device and the power supply is stopped, the overcurrent flows through the device. do not have.

It is a figure which shows the structure of the overcurrent protection system by one Embodiment of this invention. It is a figure which shows the processing flow of the overcurrent protection system by one Embodiment of this invention. It is a figure which shows the operation sequence of the overcurrent protection system by one Embodiment of this invention. It is a figure which shows the minimum structure of the overcurrent protection circuit 30 by embodiment of this invention. It is a schematic block diagram which shows the structure of the computer which concerns on at least one Embodiment.

<Embodiment>
Hereinafter, embodiments will be described in detail with reference to the drawings.
As shown in FIG. 1, the overcurrent protection system 1 according to an embodiment of the present invention includes an AC (Alternating Current Curent) -DC (Direct Current) converter 10, a DC-DC converter 20, and an overcurrent protection circuit 30.

The AC-DC converter 10 includes an input terminal IN1 and an output terminal OUT1. The DC-DC converter 20 includes an input terminal IN2 and an output terminal OUT2. The overcurrent protection circuit 30 includes an input terminal IN3 and an output terminal OUT3. The input terminal IN1 is connected to, for example, a first facility 2 (for example, a power system) provided outside the overcurrent protection system 1, as shown in FIG. The output terminal OUT1 is connected to the input terminal IN3. The output terminal OUT3 is connected to the input terminal IN2. The output terminal OUT2 is connected to, for example, a second facility 3 (for example, a factory, a plant, etc.) provided outside the overcurrent protection system 1, as shown in FIG.
In the overcurrent protection system 1, the AC-DC converter 10 supplies power to the DC-DC converter 20 via the overcurrent protection circuit 30. In the overcurrent protection system 1, when a large current flows through the DC-DC converter 20 for some reason, such as when the power supply terminal of the DC-DC converter 20 is short-circuited to the ground, the overcurrent protection circuit 30 causes the AC-DC converter. This is a system that cuts off the power supplied from the 10 to the DC-DC converter 20.

The AC-DC converter 10 converts AC power received from the outside into DC power, and outputs the converted DC power. Specifically, the AC-DC converter 10 receives AC power from the first equipment 2 via the input terminal IN1. The AC-DC converter 10 converts the received AC power into DC power. The AC-DC converter 10 outputs the converted DC power from the output terminal OUT1 to the input terminal IN3.

The DC-DC converter 20 converts the DC power received from the outside into the DC power required for the subsequent stage circuit, and outputs the converted DC power to the subsequent stage circuit. Specifically, when the DC-DC converter 20 receives DC power from the overcurrent protection circuit 30 via the input terminal IN2, the DC-DC converter 20 converts the received DC power into the DC power required for the second facility 3. The DC-DC converter 20 outputs the converted DC power to the second equipment 3.

The overcurrent protection circuit 30 outputs the DC power received at the input terminal IN3 from the output terminal OUT3. Further, when the overcurrent protection circuit 30 detects a current exceeding a predetermined threshold current by the received DC power, the overcurrent protection circuit 30 cuts off the output of the DC power from the output terminal OUT3.

Specifically, as shown in FIG. 1, the overcurrent protection circuit 30 includes a first transistor 301 (an example of a first switch), an LDO (Low Drop-Out) regulator 302, and a second transistor 303 (second transistor). An example of a switch, an example of a control signal generator), a comparator 304 (an example of a control signal generator), a control device 305 (an example of a determination unit, an example of a control unit, an example of a control signal generator), a third transistor 306 (an example of a control signal generator). (Example of disconnection means), load 307, first voltage source 308, second voltage source 309, fuse F1 (example of control signal generator), current detection resistor R1 (example of detection unit), pull-up resistor R2, pull-down resistor It is equipped with R3.

Each of the first transistor 301, the second transistor 303, and the third transistor 306 includes a drain terminal, a gate terminal, and a source terminal. The LDO regulator 302 includes an input terminal and an output terminal. The comparator 304 includes a positive input terminal, a negative input terminal, and an output terminal. The control device 305 includes a first input terminal, a second input terminal, a first output terminal, and a second output terminal. The load 307, the first voltage source 308, the second voltage source 309, the fuse F1, the current detection resistor R1, the pull-up resistor R2, and the pull-down resistor R3 each include a first terminal and a second terminal.

The drain terminal of the first transistor 301 is connected to the input terminal of the LDO regulator 302. The gate terminal of the first transistor 301 is connected to each of the source terminal of the second transistor 303 and the first terminal of the pull-down resistor R3. The source terminal of the first transistor 301 is connected to each of the first input terminal of the control device 305 and the first terminal of the current detection resistor R1. The output terminal of the LDO regulator 302 is connected to the first terminal of the fuse F1. The drain terminal of the second transistor 303 is connected to each of the output terminal of the comparator 304 and the first terminal of the pull-up resistor R2. The gate terminal of the second transistor 303 is connected to the first output terminal of the control device 305. The positive input terminal of the comparator 304 is connected to each of the drain terminal of the third transistor 306 and the second terminal of the fuse F1. The negative input terminal of the comparator 304 is connected to the first terminal of the first voltage source 308. The second input terminal of the control device 305 is connected to the second terminal of the current detection resistor R1. The second output terminal of the control device 305 is connected to the gate terminal of the third transistor 306. The source terminal of the third transistor 306 is connected to the first terminal of the load 307. The second terminal of the load 307, the second terminal of the first voltage source 308, the first terminal of the second voltage source 309, and the second terminal of the pull-down resistor R3 are each connected to the ground. The second terminal of the second voltage source 309 is connected to the second terminal of the pull-up resistor R2.
The drain terminal of the first transistor 301 and the input terminal of the LDO regulator 302 are connected to the input terminal IN3 of the overcurrent protection circuit 30. Further, the second input terminal of the control device 305 and the second terminal of the current detection resistor R1 are connected to the output terminal OUT3 of the overcurrent protection circuit 30.

The first transistor 301 goes into an on state (that is, a conduction state) or an off state (that is, a cutoff state) according to the voltage control of the gate terminal via the second transistor 303 by the control device 305. Specifically, the first transistor 301 is turned on when the voltage at the gate terminal is controlled to the High level. Further, the first transistor 301 is turned off when the voltage of the gate terminal is controlled to the Low level.
When the first transistor 301 is in the ON state, the first transistor 301 outputs the electric power received at the drain terminal (that is, the input terminal IN3) from the source terminal. As a result, the power is output from the output terminal OUT3 via the current detection resistor R1. Further, when the first transistor 301 is in the off state, it does not output power from the source terminal regardless of whether or not it receives power at the input terminal IN3.
The first transistor 301 is, for example, a MOSFET (Metal-Oxide-Semiconductor Field-Effective Transistor).

The LDO regulator 302 generates a DC voltage having a predetermined voltage value from the DC voltage input from the input terminal with low loss. The LDO regulator 302 outputs the generated DC voltage to the positive input terminal of the comparator 304 and the drain terminal of the third transistor 306 via the fuse F1.

The LDO regulator 302 finally serves as a power source for turning on the first transistor 301. However, the LDO regulator 302 only needs to be able to blow (that is, blow) the fuse F1 when an overcurrent is detected after supplying a voltage to the positive input terminal of the comparator 304. Therefore, the outer shape and current capacity of the LDO regulator 302 may be small enough to immediately disconnect the fuse F1 when an overcurrent is detected.

The second transistor 303 goes into an on state (that is, a conduction state) or an off state (that is, a cutoff state) according to the voltage control for the gate terminal by the control device 305, and applies a voltage to the gate terminal of the first transistor 301. Output. Specifically, the second transistor 303 is turned on when the voltage at the gate terminal is controlled to the High level by the control device 305, and the voltage corresponding to the voltage at the output terminal of the comparator 304 (that is, the voltage of the comparator 304 (that is, the comparator 304) If the voltage of the output terminal is High level, High level voltage, if Low level, Low level voltage) is output to the gate terminal of the first transistor 301. Further, the second transistor 303 is turned off when the voltage of the gate terminal is controlled to the Low level by the control device 305, and the voltage of the gate terminal of the first transistor 301 is changed to the Low level voltage by the pull-down resistor R3. Become.
The second transistor 303 is, for example, a MOSFET.

The first voltage source 308 outputs a voltage Vref (an example of a reference voltage) from the first terminal, and determines the voltage of the negative terminal of the comparator 304. The voltage value of the voltage Vref is lower than the voltage value of the output voltage of the LDO regulator 302.

The comparator 304 outputs a voltage from the output terminal according to the magnitude relationship between the voltage of the positive input terminal and the voltage Vref of the negative input terminal. Specifically, for example, when the voltage of the positive input terminal is higher than the voltage Vref of the negative input terminal, the comparator 304 outputs a high level voltage from the output terminal to the drain terminal of the second transistor 303. Further, for example, when the voltage of the positive input terminal is lower than the voltage Vref of the negative input terminal, the comparator 304 outputs a low level voltage from the output terminal to the drain terminal of the second transistor 303. That is, the comparator 304 outputs a Low level voltage when the fuse F1 is blown.

The control device 305 controls the voltage at the gate terminal of the first transistor 301 via the second transistor 303 based on the current flowing through the current detection resistor R1. Specifically, the control device 305 receives the voltage of the first terminal of the current detection resistor R1 at the first input terminal. The control device 305 receives the voltage of the second terminal of the current detection resistor R1 at the second input terminal. Then, the control device 305 specifies the difference voltage between the voltage received at the first input terminal and the voltage received at the second input terminal.
When the specified difference voltage exceeds a predetermined threshold voltage, the control device 305 outputs a Low level voltage to the gate terminal of the second transistor 303. Further, the control device 305 outputs a high level voltage to the gate terminal of the second transistor 303 when the specified difference voltage does not exceed a predetermined threshold voltage. The predetermined threshold voltage here is a voltage used to determine whether or not an overcurrent has flowed through the current detection resistor R1. That is, when an overcurrent flows through the current detection resistor R1, a Low level voltage is output from the source terminal of the second transistor 303, so that the first transistor 301 is turned off.

Further, in the control device 305, when the difference voltage between the voltage received at the specified first input terminal and the voltage received at the second input terminal exceeds a predetermined threshold voltage, that is, the current detection resistance R1 is excessive. When a current flows, an overcurrent detection signal for notifying that an overcurrent has flowed is output to the current detection resistor R1. Specifically, when an overcurrent flows through the current detection resistor R1, the control device 305 outputs an overcurrent detection signal indicating a high level voltage from the second output terminal to the gate terminal of the third transistor 306. Further, when the overcurrent does not flow through the current detection resistor R1, the control device 305 outputs an overcurrent detection signal indicating a Low level voltage from the second output terminal to the gate terminal of the third transistor 306.

The difference voltage between the voltage of the first terminal of the current detection resistor R1 and the voltage of the second terminal of the current detection resistor R1 is proportional to the current flowing through the current detection resistor R1. Therefore, the difference voltage between the voltage received at the first input terminal and the voltage received at the second input terminal specified by the control device 305 has a one-to-one correspondence with the current flowing through the current detection resistor R1. Therefore, specifying the difference voltage between the voltage received by the control device 305 at the first input terminal and the voltage received by the second input terminal is equivalent to specifying the current flowing through the current detection resistor R1.

Further, when the control device 305 specifies the absolute value of the current flowing through the current detection resistor R1, for example, the resistance value of the current detection resistor R1 is stored in advance, and the voltage received at the specified first input terminal. The difference voltage between the voltage received at the second input terminal and the voltage received at the second input terminal may be divided by the resistance value of the current detection resistor R1.
Further, when the control device 305 specifies the absolute value of the current flowing through the current detection resistor R1, for example, the difference voltage between the voltage received at the first input terminal and the voltage received at the second input terminal and the flow. When a data table showing the correspondence with the current flowing through the detection resistor R1 is stored in advance and the difference voltage between the voltage received at the first input terminal and the voltage received at the second input terminal is specified, the specified difference voltage is specified. The current value corresponding to may be specified in the stored data table.

The third transistor 306 is turned on (that is, conducted) or turned off (that is, cut off) according to the voltage control of the gate terminal by the control device 305. Specifically, the third transistor 306 receives an overcurrent detection signal output by the control device 305 at the gate terminal. The third transistor 306 is turned on when the received overcurrent detection signal is a signal indicating a high level voltage. Further, the third transistor 306 is turned off when the received overcurrent detection signal is a signal indicating a Low level voltage.

When the third transistor 306 is turned on, the fuse F1 is disconnected. Specifically, when the third transistor 306 is turned on, a path for current to flow from the LDO regulator 302 to the ground via the fuse F1 is created. Therefore, a current flows from the LDO regulator 302 to the ground of the load 307 via the fuse F1 and the third transistor 306. The current value of the current exceeds the current value that causes the fuse F1 to be disconnected. Therefore, when the third transistor 306 is turned on, the fuse F1 is disconnected.
The third transistor 306 is, for example, a MOSFET.

The load 307 determines the current value of the current flowing through the fuse F1 when the third transistor 306 is turned on. As the load 307, a load is selected so that when the third transistor 306 is turned on, a current for disconnecting the fuse F1 flows through the fuse F1. The load 307 is, for example, a chip resistor.
The second voltage source 309 outputs the voltage VRL from the second terminal. As the voltage value of the voltage VRL, a voltage value at which the output voltage of the comparator 304 is stable and the first transistor 301 is turned on is selected.

The fuse F1 is disconnected when a current equal to or higher than a predetermined current flows. Specifically, the fuse F1 is disconnected because a large current flows when the third transistor 306 is turned on.

The same current as the current flowing into the DC-DC converter 20 flows through the current detection resistor R1. The difference voltage between the first terminal and the second terminal of the current detection resistor R1 is a voltage proportional to the current flowing into the DC-DC converter 20.

The pull-up resistor R2 is a resistor for the first transistor to maintain a stable voltage at the output terminal of the comparator 304 when the comparator 304 is in a state of outputting a high level voltage. An example of the comparator 304 is a general open-drain or open-collector comparator, in which a pull-up resistor is connected to the output and connected to the second terminal of the second voltage source 309. However, as another example of the comparator 304, it may be a differential amplifier such as an operational amplifier. When the comparator 304 is a differential amplifier such as an operational amplifier, it does not have a pull-up resistor R2 and a second voltage source 309, and a second transistor from an output terminal having a low impedance of the differential amplifier such as an operational amplifier. A voltage may be applied to the drain terminal of 303.

Next, the processing of the overcurrent protection system 1 according to the embodiment of the present invention will be described with reference to FIGS. 2 and 3.
The fuse F1 is not broken, the first transistor 301 is in the ON state, the overcurrent protection circuit 30 has not detected an overcurrent, and the overcurrent protection circuit is connected to the AC-DC converter 10. The state in which power is supplied to the DC-DC converter 20 via 30 is called a normal state. Further, the case where the overcurrent protection circuit 30 detects an overcurrent is called an abnormal state. Here, the process of the overcurrent protection system 1 in which the overcurrent protection circuit 30 changes from the normal state to the abnormal state and cuts off the power supply from the AC-DC converter 10 to the DC-DC converter 20 will be described.

In the normal state, when power is supplied from the output terminal OUT1 of the AC-DC converter 10 to the input terminal IN3 of the overcurrent protection circuit 30, the output voltage of the LDO regulator 302 is changed to the positive input terminal of the comparator 304 via the fuse F1. Is output to. Further, the output voltage Def of the first voltage source 308 is output to the negative input terminal of the comparator 304. Since the voltage of the positive input terminal of the comparator 304 is higher than the voltage Vref of the negative input terminal, the comparator 304 outputs a high level voltage to the drain terminal of the second transistor 303.

Further, in the normal state, the control device 305 sets the high level voltage to the first high level voltage because the difference voltage between the voltage received at the first input terminal and the voltage received at the second input terminal does not exceed a predetermined threshold voltage. Output from the output terminal to the gate terminal of the second transistor 303. The second transistor 303 receives a high level voltage at the gate terminal and is turned on. The second transistor 303 outputs the high level voltage output from the comparator 304 from the source terminal to the gate terminal of the first transistor 301. The first transistor 301 is turned on, and the power input to the input terminal IN3 of the overcurrent protection circuit 30 is output from the source terminal. The power output from the source terminal is output from the output terminal OUT3 of the overcurrent protection circuit 30.

Further, in the normal state, the control device 305 outputs an overcurrent detection signal indicating a Low level voltage from the second output terminal to the gate terminal of the third transistor 306. The third transistor 306 receives a Low level voltage at the gate terminal and is turned off. Therefore, there is no path for current to flow from the LDO regulator 302 to the ground via the fuse F1. Therefore, the fuse F1 is not broken.

Here, for example, in the DC-DC converter 20, it is assumed that a problem occurs in which the power supply voltage (that is, the input terminal IN2) and the ground are short-circuited. In this case, a large current flows from the AC-DC converter 10 to the DC-DC converter 20 via the first transistor 301 and the overcurrent detection resistor R1.

At this time, the overcurrent detection resistor R1 outputs the voltage of the first input terminal and the voltage of the second input terminal according to the current flowing into the DC-DC converter 20 (step S1). The control device 305 determines whether or not the difference voltage between the voltage of the first input terminal and the voltage of the second input terminal exceeds a predetermined threshold voltage. In the example here, the difference voltage between the voltage of the first input terminal of the control device 305 and the voltage of the second input terminal of the control device 305 is controlled by the voltage of the first input terminal of the control device 305 in the normal state. It becomes larger than the difference voltage between the voltage and the voltage of the second input terminal of the device 305 (step S2, timing t1 in FIG. 3A). The control device 305 determines that the difference voltage between the voltage of the first input terminal and the voltage of the second input terminal exceeds a predetermined threshold voltage. When the control device 305 determines that the difference voltage between the voltage of the first input terminal and the voltage of the second input terminal exceeds a predetermined threshold voltage, the control device 305 outputs an overcurrent detection signal indicating a high level voltage. Output from the second output terminal to the gate terminal of the third transistor 306 (step S3, timing t2 in FIG. 3B). Then, the control device 305 outputs the Low level voltage to the first output terminal in parallel with outputting the overcurrent detection signal indicating the High level voltage from the second output terminal to the gate terminal of the third transistor 306. Is output to the gate terminal of the second transistor 303 (step S4).

When the second transistor 303 receives a Low level voltage at the gate terminal, it is turned off, and the source terminal voltage, that is, the gate terminal voltage of the first transistor 301 becomes the Low level voltage due to the pull-down resistor R3. ..
The first transistor 301 is turned off when the voltage at the gate terminal reaches the Low level voltage (step S5).

When the third transistor 306 receives an overcurrent detection signal indicating a high level voltage at the gate terminal, the third transistor 306 is turned on (step S6). When the third transistor 306 is turned on, a current flows from the LDO regulator 302 to the load 307 via the fuse F1 and the third transistor 306. At this time, the current value of the current flowing through the fuse F1 is the current value at which the fuse F1 is disconnected. Therefore, when the third transistor 306 is turned on, the fuse F1 is disconnected (step S7). When the fuse F1 is disconnected, the voltage at the second terminal of the fuse F1 becomes a low level voltage (timing t3 in FIG. 3C).

When the voltage at the second terminal of the fuse F1, that is, the voltage at the positive input terminal of the comparator 304 reaches the Low level voltage (timing t4 in FIG. 3D), the voltage at the positive input terminal of the comparator 304 becomes the negative input terminal. Since the voltage is lower than the voltage Vref of the above, a Low level voltage is output from the output terminal to the drain terminal of the second transistor 303.

When the comparator 304 outputs a Low level voltage from the output terminal to the drain terminal of the second transistor 303, the control device 305 outputs a High level voltage from the first output terminal to the gate terminal of the second transistor 303. In both cases and when a Low level voltage is output from the first output terminal to the gate terminal of the second transistor 303 (timing t5 in FIG. 3E), the voltage of the source terminal of the second transistor 303, That is, the voltage at the gate terminal of the first transistor 301 becomes the Low level voltage (timing t6 in FIG. 3 (f)).

The first transistor 301 is turned off when the voltage at the gate terminal is a Low level voltage. Therefore, for example, the overcurrent protection system 1 is reset due to an abnormal state, and the control device 305 outputs a high level voltage from the first output terminal to the gate terminal of the second transistor 303, and the low level is set. Even when the overcurrent detection signal indicating the voltage is output to the gate terminal of the third transistor 306 to release the abnormal state, the fuse F1 is disconnected, so that the abnormal state is not detected again. Therefore, the overcurrent protection system 1 is reset when an abnormal state occurs, and the control device 305 outputs a high level voltage from the first output terminal to the gate terminal of the second transistor 303, resulting in a low level voltage. Even if an abnormal state is generated by outputting an overcurrent detection signal indicating the above to the gate terminal of the third transistor 306, the detection of the abnormal state and the cancellation of the abnormal state are not repeated. As a result, the voltage at the input terminal of the DC-DC converter 20 changes as shown in FIG. 3 (g). When the voltage of the output terminal of the AC-DC converter 10 changes from the low level voltage to the high level voltage as shown in FIG. 3 (h) (timing t7 in FIG. 3 (h)), FIG. As shown in 3 (e), the voltage at the gate terminal of the second transistor 303 changes from the low level voltage to the high level voltage (timing t8 in FIG. 3 (e)).

In the process of step S5, when the first transistor 301 is turned off, the AC-DC converter 10 and the DC-DC converter 20 are electrically disconnected, and the AC-DC converter 10 to the DC-DC converter 20 are cut off. The power supply to is cut off. When the power supply to the DC-DC converter 20 is cut off, the DC-DC converter 20 is turned off. Further, when the power supply to the DC-DC converter 20 is cut off, no current flows through the overcurrent detection resistor R1, so that the control device 305 applies a high level voltage from the first output terminal to the second transistor. It is output to the gate terminal of 303, and an overcurrent detection signal indicating a Low level voltage is output to the gate terminal of the third transistor 306. As a result, the abnormal state is canceled, but the detection of the abnormal state and the cancellation of the abnormal state are not repeated.

The overcurrent protection system 1 according to the embodiment of the present invention has been described above.
In the overcurrent protection system 1 according to the embodiment of the present invention, when the control device 305 detects an overcurrent, the control device 305 controls the third transistor 306 to be in the ON state, thereby causing a current to flow through the fuse F1 to blow the fuse F1. Break the wire. When the fuse F1 is disconnected, the signal output by the comparator 304 becomes a signal for controlling the first transistor 301 to be in the off state.
In this way, the first transistor 301 is turned off regardless of whether the second transistor 303 is turned on or off in the overcurrent protection system 1. Therefore, even if the overcurrent protection system 1 is restarted without removing the cause of the overcurrent in the overcurrent protection system 1, the overcurrent does not flow through the overcurrent protection system 1.

FIG. 4 is a diagram showing the minimum configuration of the overcurrent protection circuit 30 according to the embodiment of the present invention.
As shown in FIG. 4, the overcurrent protection circuit 30 includes a first switch 101, a detection unit 102, a determination unit 103, and a control signal generation device 104.

The first switch 101 is provided in series with the path for supplying electric power. The detection unit 102 detects the current flowing in the path. The determination unit 103 determines whether or not the current detected by the detection unit 102 is an overcurrent. The control signal generation device 104 supplies a control signal for closing the first switch 101 to the first switch 101 until the determination unit 103 determines that the current detected by the detection unit 102 is an overcurrent. Then, after the determination unit 103 determines that the current detected by the detection unit 102 is an overcurrent, a control signal for opening the first switch 101 is supplied to the first switch 101. It should be noted that after the determination unit 103 determines that the current detected by the detection unit 102 is an overcurrent, it is after the determination unit 103 first determines that the current detected by the detection unit 102 is an overcurrent. be. Therefore, even if the determination unit 103 redetermines that the current detected by the detection unit 102 is an overcurrent, the control signal generation device 104 subsequently outputs a control signal for opening the first switch 101. Continues to supply to the first switch 101.

In the processing according to the embodiment of the present invention, the order of the processing may be changed as long as the appropriate processing is performed.

Each of the storage unit and the other storage devices according to the embodiment of the present invention may be provided anywhere within a range in which appropriate information is transmitted and received. Further, each of the storage unit and the other storage devices may exist in a plurality of areas within a range in which appropriate information is transmitted and received, and the data may be distributed and stored.

Although the embodiment of the present invention has been described, the above-mentioned control device 305 and other control devices may have a computer system inside. The process of the above-mentioned processing is stored in a computer-readable recording medium in the form of a program, and the above-mentioned processing is performed by the computer reading and executing this program. A specific example of a computer is shown below.
FIG. 5 is a schematic block diagram showing a configuration of a computer according to at least one embodiment.
As shown in FIG. 5, the computer 5 includes a CPU 6, a main memory 7, a storage 8, and an interface 9.
For example, each of the above-mentioned control device 305 and other control devices is mounted on the computer 5. The operation of each processing unit described above is stored in the storage 8 in the form of a program. The CPU 6 reads the program from the storage 8, expands it into the main memory 7, and executes the above processing according to the program. Further, the CPU 6 secures a storage area corresponding to each of the above-mentioned storage units in the main memory 7 according to the program.

Examples of the storage 8 include HDD (Hard Disk Drive), SSD (Solid State Drive), magnetic disk, optical magnetic disk, CD-ROM (Compact Disk Read Only Memory), DVD-ROM (Digital Versatile Disk Read). , Semiconductor memory and the like. The storage 8 may be internal media directly connected to the bus of computer 5, or external media connected to computer 5 via an interface 9 or a communication line. When this program is distributed to the computer 5 via a communication line, the distributed computer 5 may expand the program in the main memory 7 and execute the above processing. In at least one embodiment, the storage 8 is a non-temporary tangible storage medium.

Further, the above program may realize a part of the above-mentioned functions. Further, the program may be a file that can realize the above-mentioned functions in combination with a program already recorded in the computer system, that is, a so-called difference file (difference program).

Although some embodiments of the present invention have been described, these embodiments are examples and do not limit the scope of the invention. Various additions, omissions, replacements, and changes may be made to these embodiments without departing from the gist of the invention.

1 ... Overcurrent protection system 2 ... 1st equipment 3 ... 2nd equipment 5 ... Computer 6 ... CPU
7 ... Main memory 8 ... Storage 9 ... Interface 10 ... AC-DC converter 20 ... DC-DC converter 30 ... Overcurrent protection circuit 105, 304 ... Comparator 301 ... First transistor 302 ... LDO regulator 303 ... Second transistor 305 ... Control device 306 ... Third transistor 307 ... Load 308 ... First voltage source 309 ... Second voltage Source F1 ・ ・ ・ Fuse R1 ・ ・ ・ Overcurrent detection resistance R2 ・ ・ ・ Pull-up resistance

Claims (6)

A first switch provided in series with the power supply path,
A detector that detects the current flowing in the path,
A determination unit that determines whether or not the current detected by the detection unit is an overcurrent, and a determination unit.
Until the determination unit determines that the current detected by the detection unit is an overcurrent, a control signal for closing the first switch is supplied to the first switch, and the detection unit detects the current. A control signal generator that supplies a control signal for opening the first switch to the first switch after the determination unit determines that the generated current is an overcurrent. A second switch having a second terminal and supplying a control signal for opening or closing the first switch to the first switch, and a third terminal, a fourth terminal, and a fifth terminal. When a reference voltage is applied to the third terminal and the voltage at the fourth terminal is higher than the reference voltage applied to the third terminal, the first When a signal capable of controlling the switch to the closed state is output from the fifth terminal to the first terminal, and the voltage at the fourth terminal is lower than the reference voltage applied to the third terminal. In addition, a comparator that outputs a signal that can control the first switch to the open state from the fifth terminal to the first terminal, and a path that supplies a voltage higher than the reference voltage to the fourth terminal. When it is determined that the current detected by the determination unit is not an overcurrent, the connection between the first terminal and the second terminal is controlled to be closed, and the disconnection is performed. The disconnection means is controlled so that the means does not disconnect the path, and when the determination unit determines that the current detected is an overcurrent, the connection between the first terminal and the second terminal is established. A control signal generation device having a control unit that controls the disconnection means and controls the disconnection means so that the disconnection means disconnects the path .
Overcurrent protection circuit with. A fuse having a sixth terminal and a seventh terminal, the sixth terminal being connected to the fourth terminal, and a voltage higher than the reference voltage applied to the seventh terminal.
With
The disconnection means
It is a disconnection means that can disconnect the fuse when it is in an operating state.
The control unit
When the determination unit determines that the current detected is not an overcurrent, the connection between the first terminal and the second terminal is controlled to be closed, and the disconnection means is controlled to not operate. Then, when the determination unit determines that the current detected is an overcurrent, the connection between the first terminal and the second terminal is controlled to be open, and the disconnection means is operated. Control to state,
The overcurrent protection circuit according to claim 1 . The disconnection means
A third switch that is open or closed,
With the load connected to the third switch,
With
The control unit
By controlling the third switch to be in the open state or the closed state, it is possible to control whether or not the fuse is blown.
The overcurrent protection circuit according to claim 2 . The overcurrent protection circuit according to any one of claims 1 to 3 .
Devices that are powered via an overcurrent protection circuit and
Overcurrent protection system with. A first switch provided in series in the power supply path, a second switch having a first terminal and a second terminal, and a comparator having a third terminal, a fourth terminal, and a fifth terminal. It is an overcurrent protection method by an overcurrent protection circuit provided with a disconnection means .
Detecting the current flowing in the path and
Determining whether the detected current is overcurrent and
Until it is determined that the detected current is an overcurrent, a control signal for closing the first switch is supplied to the first switch, and after determining that the detected current is an overcurrent, thereafter. Supplying a control signal for opening the first switch to the first switch and
Including
Supplying a control signal for opening or closing the first switch to the first switch, and
When a reference voltage is applied to the third terminal and the voltage at the fourth terminal is higher than the reference voltage applied to the third terminal, the first switch can be controlled to the closed state. A signal is output from the fifth terminal to the first terminal, and when the voltage at the fourth terminal is lower than the reference voltage applied to the third terminal, the first switch is opened. To output a signal that can be controlled to the state from the fifth terminal to the first terminal,
To disconnect the path for supplying a voltage higher than the reference voltage to the fourth terminal.
When it is determined that the detected current is not an overcurrent, the disconnection is controlled so that the connection between the first terminal and the second terminal is closed and the disconnection means does not disconnect the path. When the means is controlled and it is determined that the detected current is an overcurrent, the space between the first terminal and the second terminal is controlled to be open, and the disconnection means guides the path. Controlling the disconnection means so as to disconnect,
Overcurrent protection method by overcurrent protection circuit including . A first switch provided in series in the power supply path, a second switch having a first terminal and a second terminal, and a comparator having a third terminal, a fourth terminal, and a fifth terminal. And a computer with an overcurrent protection circuit equipped with disconnection means ,
Detecting the current flowing in the path and
Determining whether the detected current is overcurrent and
Until it is determined that the detected current is an overcurrent, a control signal for closing the first switch is supplied to the first switch, and after determining that the detected current is an overcurrent, thereafter. Supplying a control signal for opening the first switch to the first switch and
Supplying a control signal for opening or closing the first switch to the first switch, and
When a reference voltage is applied to the third terminal and the voltage at the fourth terminal is higher than the reference voltage applied to the third terminal, the first switch can be controlled to the closed state. A signal is output from the fifth terminal to the first terminal, and when the voltage at the fourth terminal is lower than the reference voltage applied to the third terminal, the first switch is opened. To output a signal that can be controlled to the state from the fifth terminal to the first terminal,
To disconnect the path for supplying a voltage higher than the reference voltage to the fourth terminal.
When it is determined that the detected current is not an overcurrent, the disconnection is controlled so that the connection between the first terminal and the second terminal is closed and the disconnection means does not disconnect the path. When the means is controlled and it is determined that the detected current is an overcurrent, the space between the first terminal and the second terminal is controlled to be open, and the disconnection means guides the path. Controlling the disconnection means so as to disconnect,
A program that executes.

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