JP7221150B2 - current sensor - Google Patents

Description

The present invention relates to a current sensor that detects a detection current flowing through a detection conductor by a zero flux method.

As a current sensor of this type, the following Patent Document 1 discloses that the detection current (measurement current) flowing through the detection conductor (wire to be measured) is detected by a zero flux method (core, magnetoelectric conversion part (Hall element, flux gate element, etc.), feedback winding, etc.). Equipped with a line (negative feedback coil), a voltage-to-current conversion circuit, a detection resistor circuit that converts the negative feedback current into a voltage and outputs it, and an amplifier circuit that amplifies the voltage output from the detection resistor circuit and outputs it as an output voltage. method), and by switching the combination of the detection resistor that makes up the detection resistor circuit and the input resistance of the operational amplifier that makes up the amplification circuit, the detection rate (when converting the measured current into A current sensor is disclosed that can switch the conversion rate of .

JP 2014-215065 A (pages 5-8, FIG. 1)

However, the conventional current sensor described above has the following problems to be improved. In other words, in the conventional current sensor, the detection voltage detected by the detection resistor is all amplified by the operational amplifier constituting the amplifier circuit at any detection rate and output as an output voltage. However, there is a problem that the output voltages output at all detection rates are affected by noise generated in the operational amplifier itself that constitutes the amplifier circuit.

SUMMARY OF THE INVENTION The present invention has been made to solve this problem, and a main object of the present invention is to provide a current sensor capable of reducing the influence of noise generated in an amplifier while allowing the detection rate to be switched.

In order to achieve the above object, a current sensor according to claim 1 comprises: a magnetic core through which a detection conductor is inserted; a magnetoelectric conversion section disposed in the magnetic core; a feedback winding wound around the magnetic core; a voltage-to-current conversion circuit that generates a negative feedback current based on the voltage output from the magnetoelectric conversion unit that cancels the magnetic flux generated in the magnetic core by flowing through the detection conductor, and supplies the negative feedback current to one end of the feedback winding; and an output terminal, wherein the negative feedback current output from the other end of the feedback winding is converted into a voltage using a first detection resistor to convert the detected current to a first detection resistor. 1 or 2 or more first voltage converters for converting the voltage into a first detection voltage at a rate and outputting the voltage; and one or more second voltage converters for converting the detected current into a second detected voltage at a second detection rate higher than the first detection rate and outputting the detected voltage; A switching unit is provided for switching to a connection state in which any one element of the voltage conversion unit and the one or more second voltage conversion units is connected between the other end and the output terminal.

Further, the current sensor according to claim 2 is the current sensor according to claim 1, wherein the resistance value of the detection resistor included in the arbitrary one element of the first detection resistor and the second detection resistor is It defines the characteristic impedance of the line from the other end of the feedback winding to the arbitrary one element.

Further, the current sensor of claim 3 is the current sensor of claim 1 or 2, further comprising: a sensor unit containing the magnetic core, the magnetoelectric conversion section, and the feedback winding; the voltage-to-current conversion circuit; a relay unit housing a path; a termination unit housing the switching unit, the first voltage conversion unit, the second voltage conversion unit, and the output terminal; a first connection cable; and a second connection cable. wherein the sensor unit and the relay unit are connected via the first connection cable, and the voltage-to-current conversion circuit is connected to the magnetoelectric conversion section and the feedback winding via wiring that constitutes the first connection cable. one end of the transmission line, and one end of the transmission line is connected to the other end of the feedback winding via another wiring that constitutes the first connection cable, and the relay unit and the termination unit is connected via the second connection cable, and the switching unit is between the other end of the transmission path and the output terminal connected via the wiring constituting the second connection cable Switch to the connected state in which the arbitrary one element is connected.

A current sensor according to claim 4 comprises a magnetic core through which a detection conductor is inserted, a magneto-electric conversion section disposed in the magnetic core, a feedback winding wound around the magnetic core, and a detection current passing through the detection conductor. a voltage-to-current conversion circuit that generates a negative feedback current based on the voltage output from the magnetoelectric conversion unit and supplies the negative feedback current that cancels the magnetic flux generated in the magnetic core by flowing through the magnetic core to one end of the feedback winding; and an output terminal. A current sensor comprising a first detection resistor that converts the supplied current into a voltage, a second detection resistor that converts the supplied current into a voltage, and amplifies the voltage converted by the second detection voltage an amplifier, a transmission path, and a switching section, wherein the switching section converts the negative feedback current output from the other end of the feedback winding into a current composed of the second detection resistor and the amplifier. Switching and supplying to any one element of the voltage conversion circuit and the transmission path, supplying the signal output from the one element to the first detection resistor, and the switching unit as the one element In the switching state in which the transmission path is switched, the first detection resistor converts the negative feedback current into a voltage, thereby converting the detection current into a first detection voltage at a first detection rate and outputting the voltage to the output terminal. In a switching state in which the switching unit switches to the current-voltage conversion circuit as the one element, the current-voltage conversion circuit and the first detection resistor convert the negative feedback current into a voltage and amplify it. converts the detected current into a second detected voltage at a second detection rate higher than the first detection rate and outputs the second detected voltage to the output terminal.

Further, the current sensor according to claim 5 is the current sensor according to claim 4, wherein the resistance value of the first detection resistor is the feedback current in the switching state in which the switching unit switches to the transmission line as the one element. It is defined as the characteristic impedance of the line from the other end of the winding to the first sensing resistor.

The current sensor according to claim 6 is the current sensor according to claim 4, wherein the resistance value of the second detection resistor is It is defined by the characteristic impedance of the line from the other end of the feedback winding to the current-voltage conversion circuit.

The current sensor according to claim 7 is the current sensor according to claim 6, wherein the resistance value of the first detection resistor is defined by the characteristic impedance of the line from the current-voltage conversion circuit to the first detection resistor. ing.

The current sensor according to claim 8 is the current sensor according to any one of claims 4 to 7, wherein the sensor unit accommodates the magnetic core, the magnetoelectric conversion section, and the feedback winding; A relay unit housing the conversion circuit, the transmission line, the current-voltage conversion circuit, and the switching section, a termination unit housing the first detection resistor and the output terminal, a first connection cable, and a second connection. a cable, wherein the sensor unit and the relay unit are connected via the first connection cable, and the voltage-to-current conversion circuit is connected to the magnetoelectric conversion section via a wiring that constitutes the first connection cable. The switching unit is connected between the one end of the feedback winding and the switching unit is connected to the other end of the feedback winding via another wiring that constitutes the first connection cable, and the relay unit and the The terminal unit is connected via the second connection cable, and the switching unit is connected to the other end of the feedback winding via the other wiring that constitutes the first connection cable. The one element is switched to a connection state in which the one element is connected to the first detection resistor connected via the wiring that constitutes the second connection cable.

Further, the current sensor according to claim 9 comprises a magnetic core through which a detection conductor is inserted, a magneto-electric conversion section arranged in the magnetic core, a feedback winding wound around the magnetic core, and a detection current passing through the detection conductor. a voltage-to-current conversion circuit that generates a negative feedback current based on the voltage output from the magnetoelectric conversion unit and supplies the negative feedback current that cancels the magnetic flux generated in the magnetic core by flowing through the magnetic core to one end of the feedback winding; and an output terminal. A current sensor comprising a first detection resistor that converts the supplied current into a voltage, a second detection resistor that converts the supplied current into a voltage, and amplifies the voltage converted by the second detection voltage a third detection resistor that converts the supplied current into a voltage, a transmission line, a first switching section and a second switching section, the first switching section being connected from the other end of the feedback winding The output negative feedback current is switched and supplied to a first element of any one of the current-voltage conversion circuit and the transmission line formed by the second detection resistor and the amplifier, and the one of the first elements A signal output from the first element is supplied to the second switching section, and the second switching section switches the signal supplied from the first switching section to the first detection resistor and the third detection resistor. While switching and supplying to any one of the second elements, the signal output from the one second element is output to the output terminal, and the first switching unit performs the transmission as the one first element in a switching state where the second switching unit switches to the first detection resistor as the one second element, the first detection resistor converts the negative feedback current into a voltage. a switching state in which the detected current is converted into a first detected voltage at a first detection rate and output to the output terminal, and the first switching unit switches to the current-voltage conversion circuit as the one first element; In a switching state in which the second switching unit switches to the first detection resistor as the one second element, the current-voltage conversion circuit and the first detection resistor convert the negative feedback current into a voltage and amplify it. By doing so, the detected current is converted into a second detected voltage at a second detection rate higher than the first detection rate and output to the output terminal, and the first switching section serves as the one of the first elements. In a switching state in which the transmission line is switched and in a switching state in which the second switching unit switches to the third detection resistor as the one second element, the third detection resistor converts the negative feedback current into a voltage. By doing so, the detection current is set at a third rate lower than the first detection rate. The third detection voltage is converted at the detection rate and output to the output terminal.

Further, the current sensor according to claim 10 is the current sensor according to claim 9, wherein the resistance value of the first detection resistor is the switching unit switched to the transmission line as the one first element by the first switching unit. state and the characteristic impedance of the line from the other end of the feedback winding to the first detection resistor in the switching state in which the second switching unit is switched to the first detection resistor as the one second element ing.

The current sensor according to claim 11 is the current sensor according to claim 9, wherein the resistance value of the second detection resistor is switched by the first switching unit as the one first element to the current-voltage conversion circuit. the characteristic impedance of the line from the other end of the feedback winding to the current-voltage conversion circuit in the switching state and the switching state in which the second switching unit switches to the first detection resistor as the one second element stipulated.

The current sensor according to claim 12 is the current sensor according to claim 11, wherein the resistance value of the first detection resistor is defined by the characteristic impedance of the line from the current-voltage conversion circuit to the first detection resistor. ing.

Further, the current sensor according to claim 13 is the current sensor according to claim 9, wherein the resistance value of the third detection resistor is set to the value of the switching that the first switching unit switches to the transmission line as the one first element. state and the characteristic impedance of the line from the other end of the feedback winding to the third detection resistor in the switching state in which the second switching unit is switched to the third detection resistor as the one second element ing.

A current sensor according to claim 14 is the current sensor according to any one of claims 9 to 13, wherein a sensor unit housing the magnetic core, the magnetoelectric conversion section and the feedback winding; A relay unit housing the conversion circuit, the transmission line, the current-voltage conversion circuit, and the first switching section; and housing the first detection resistor, the third detection resistor, the second switching section, and the output terminal. a terminal unit, a first connection cable, and a second connection cable, the sensor unit and the relay unit are connected via the first connection cable, and the voltage-current conversion circuit is connected to the first connection cable. It is connected between the magnetoelectric conversion unit and the one end of the feedback winding via wiring that constitutes a connection cable, and the first switching unit is connected to the above via another wiring that constitutes the first connection cable. It is connected to the other end of the feedback winding, the relay unit and the terminating unit are connected via the second connection cable, and the first switching unit is connected to the other wiring that constitutes the first connection cable. a connection in which the one first element is connected between the other end of the feedback winding connected via and the second switching section connected via wiring constituting the second connection cable state, and the second switching unit switches to a connection state in which the one second element is connected between the wiring constituting the second connection cable and the output terminal.

In the current sensor according to claims 1 and 4, since the current value of the detection current is small, the negative feedback current is also small. , a second detection resistor and an amplifier converts the detection current into a second detection voltage having a sufficient voltage value at the second detection rate and outputs the second detection voltage. If the current also increases and can be converted into the first detection voltage with a sufficient voltage value only by the first detection resistor, a circuit for voltage conversion configured by the first detection resistor without including an amplifier is used for detection. The current is converted into a first detection voltage having a sufficient voltage value at a first detection rate and output.

Therefore, according to this current sensor, the detection rate can be switched, and at one detection rate (first detection rate), the configuration does not include an amplifier, that is, without being affected by noise generated in the amplifier. The detected current can be converted to a first detected voltage and output.

In the current sensor according to claim 9, since the current value of the detection current is small, the negative feedback current is also small. A circuit including two detection resistors and an amplifier converts the detection current into a second detection voltage having a sufficient voltage value at the second detection rate and outputs the second detection voltage. If the first sense resistor alone can be converted into a first sense voltage having a sufficient voltage value, a circuit composed of the first sense resistor without an amplifier will increase the sense current at the first sense rate. It is converted into a first detection voltage having a sufficient voltage value and is output. In addition, since the current value of the detection current is even larger, the negative feedback current is also larger. A circuit comprising a third sense resistor of a value converts the sensed current into a third sensed voltage at a third sensed rate, which is less than the first sensed rate, and outputs the third sensed voltage.

Therefore, according to this current sensor, a detected current having a large current value can be converted into the first detected voltage and the third detected voltage and output without an amplifier. That is, according to this current sensor, three detection rates can be switched, and two of them (the first detection rate and the third detection rate) have a configuration that does not include an amplifier, that is, a current generated by an amplifier. The detection current can be converted into the first detection voltage and the third detection voltage and output without being affected by noise.

In the current sensor according to claim 3, when a negative feedback current with a large current value flows (at the first detection rate), both the voltage-current conversion circuit and the first detection resistor generate a large amount of heat. (because the voltage-current conversion circuit is housed in the relay unit and the first detection resistor is housed in the termination unit), the heat generated by the voltage-current conversion circuit and the first detection resistor is different. Units can be distributed. As a result, according to this current sensor, both the temperature rise in the relay unit and the temperature rise in the terminal unit can be kept low. Also, it is possible to avoid the influence of the heat generated by the first detection resistor on the voltage-current conversion circuit. In addition, it is possible to avoid the influence of the heat generated by the first detection resistor on the magnetic core, magnetoelectric conversion section, and feedback winding provided in the sensor unit.

In the current sensor according to claim 8, when a negative feedback current having a large current value flows (at the first detection rate), the voltage-current conversion circuit and the first detection resistor, which both generate a large amount of heat, are placed in different units. Due to the housed configuration (because of the configuration in which the voltage-current conversion circuit is housed in the relay unit and the first detection resistor is housed in the termination unit), each heat generated by the voltage-current conversion circuit and the first detection resistor is stored in different units. can be distributed in As a result, according to this current sensor, both the temperature rise in the relay unit and the temperature rise in the terminal unit can be kept low. Further, according to this current sensor, since the voltage-current conversion circuit and the current-voltage conversion circuit (the circuit composed of the second detection resistor and the amplifier) are housed in a relay unit different from the first detection resistor, Heat generation of the first sense resistor to the voltage-to-current conversion circuit and amplifier of the current-to-voltage conversion circuit, unlike the configuration housed in the termination unit, which tends to have a higher average temperature due to the heat generation of the first sense resistor. It is possible to avoid the influence of

In the current sensor according to claim 14, when a large negative feedback current flows (at the first detection rate or the third detection rate), the voltage-current conversion circuit, the first detection resistor and the Because the voltage-current conversion circuit of the third detection resistor and the first detection resistor and the third detection resistor are housed in different units (the voltage-current conversion circuit is housed in the relay unit and the first detection resistor is Since the resistor and the third detection resistor are housed in the terminal unit), the heat generated in the voltage-current conversion circuit and the heat generated in the first detection resistor and the third detection resistor can be distributed to different units. As a result, according to this current sensor, it is possible to suppress both the temperature rise in the relay unit and the temperature rise in the termination unit to be low while switching between three detection rates. Further, according to this current sensor, the voltage-current conversion circuit and the current-voltage conversion circuit (the circuit composed of the second detection resistor and the amplifier) are housed in a relay unit different from the first detection resistor and the third detection resistor. Therefore, the voltage-current conversion circuit and the current-voltage conversion circuit differ from the configuration housed in the termination unit where the average temperature tends to be higher due to the heat generation of the first detection resistor and the third detection resistor. It is possible to avoid the influence of the heat generation of the first detection resistor and the third detection resistor on the amplifier.

According to the current sensor of claim 2, the resistance value of the detection resistor that converts the negative feedback current into the corresponding detection voltage of the first detection voltage and the second detection voltage supplies the negative feedback current to the detection resistor. Since it is defined by the characteristic impedance of the line, the waveform distortion of the detected voltage can be kept low.

According to the current sensor of claims 5 and 10, the resistance value of the first detection resistor that converts the negative feedback current into the first detection voltage is defined by the characteristic impedance of the line that supplies the negative feedback current to the first detection resistor. Therefore, the waveform distortion of the first detection voltage can be kept low.

According to the current sensors of claims 6 and 11, the resistance value of the second detection resistor that converts the negative feedback current into a voltage is the characteristic of the line that supplies the negative feedback current to the current-voltage conversion circuit including the second detection resistor. Since it is defined by the impedance, waveform distortion of the voltage converted by the second detection resistor can be kept low.

According to the current sensor of claims 7 and 12, the resistance value of the first detection resistor is equal to the characteristic impedance of the line that transmits the voltage converted by the current-voltage conversion circuit including the second detection resistor to the first detection resistor. Since it is defined, the waveform distortion of the second detection voltage output from the first detection resistor can be further suppressed.

According to the current sensor of claim 13, the resistance value of the third detection resistor that converts the negative feedback current into the third detection voltage is defined by the characteristic impedance of the line that supplies the negative feedback current to the third detection resistor. Therefore, the waveform distortion of the third detection voltage can be kept low.

1 is a configuration diagram of a current sensor 1A; FIG. FIG. 3 is a configuration diagram showing an example in which the constituent elements of the current sensor 1A are divided into a sensor unit 51 and a termination unit 52 and arranged. 3 is a configuration diagram of a current sensor 1B; FIG. 2 is a configuration diagram of a current sensor 1C; FIG. 2 is a configuration diagram of a current sensor 1D; FIG. 2 is a configuration diagram of a current sensor 1E; FIG. 2 is a configuration diagram of a current sensor 1F; FIG.

Hereinafter, embodiments of a current sensor will be described with reference to the accompanying drawings.

First, the configuration of a current sensor 1A as a current sensor will be described with reference to FIG.

As shown in FIG. 1, the current sensor 1A includes a magnetic core 2, a magnetoelectric conversion section 3, a feedback winding 4, a voltage-to-current conversion circuit 5, and a plurality of voltage conversion sections (in this example, two voltage conversion sections 6a , 6b), a first switching section 7 (hereinafter also simply referred to as a switching section 7), and an output terminal 9, and configured as a zero-flux current sensor. Further, the current sensor 1A outputs an output voltage Vo from the output terminal 9, the voltage value of which changes according to the current value of the detection current I1 flowing through the electric wire 61 to be detected, which is an example of a detection conductor inserted inside the magnetic core 2. Output.

As an example, the magnetic core 2 is formed into a split type that can be opened and closed around the base end (lower end in FIG. 1), and can clamp the live electric wire 61 to be detected (inside the electric wire 61 to be detected). can be inserted). It should be noted that the magnetic core 2 is not limited to the split type, and may be of a penetrating type (non-split type).

The magnetoelectric conversion unit 3 is composed of, for example, a magnetoelectric conversion element such as a Hall element or a flux gate. Moreover, the magnetoelectric conversion part 3 is arrange|positioned by the base end part of the magnetic core 2 as an example. In addition, the magnetoelectric conversion unit 3 detects the magnetic flux generated inside the magnetic core 2 in the operating state, and generates a voltage V1 having a voltage value corresponding to the magnetic flux density (specifically, proportional or substantially proportional). Output. In this case, the magnetic flux generated inside the magnetic core 2 includes the magnetic flux φ1 generated by the detection current I1 flowing through the electric wire 61 to be detected inserted through the magnetic core 2, and the negative feedback current in the feedback winding 4, which will be described later. It is the composite magnetic flux (φ1-φ2) of the magnetic flux φ2 (magnetic flux in the opposite direction to the magnetic flux φ1) generated by the flow of I2.

The feedback winding 4 is formed by winding a wire around the magnetic core 2 a predetermined number of turns n (the number of turns n. In this example, n=50 as an example). The voltage-to-current conversion circuit 5 is composed of an operational amplifier or the like, and receives the voltage V1 from the magnetoelectric conversion section 3, generates a negative feedback current I2 based on this voltage V1, and supply. In this case, the voltage-current conversion circuit 5 is adjusted so that the voltage V1 approaches zero volts, that is, the magnetic flux density of the combined magnetic flux (φ1-φ2) generated inside the magnetic core 2 detected by the magnetoelectric conversion unit 3 is The current value of the negative feedback current I2 is controlled so as to approach zero (in other words, the magnetic flux φ2 cancels out the magnetic flux φ1). That is, the negative feedback current I2 is a value obtained by dividing the detection current I1 by the number of turns n (I2=I1/n).

The switching unit 7 includes, for example, two changeover switches 7a and 7b having a one-circuit two-contact structure. is connected between the other end 4 b of the feedback winding 4 and the output terminal 9 . Specifically, the change-over switch 7a is connected between the other end 4b of the feedback winding 4 and input portions 11 and 21 of the voltage converting portions 6a and 6b, which will be described later, to switch the other end of the feedback winding 4 The negative feedback current I2 output from 4b is selectively switched to be output to either one of the voltage converters 6a and 6b. Moreover, the changeover switch 7b is connected between the output terminals 12, 22, which will be described later, of the voltage conversion sections 6a, 6b and the output terminal 9, and is switched in conjunction with the changeover switch 7a. Specifically, when the changeover switch 7a is switched to connect the other end 4b of the feedback winding 4 and the input section 11 of the voltage conversion section 6a, the changeover switch 7b switches to the output section 12 of the voltage conversion section 6a. and the output terminal 9 are connected. Further, when the selector switch 7a is switched to connect the other end 4b of the feedback winding 4 and the input section 21 of the voltage conversion section 6b, the selector switch 7b connects the output section 22 of the voltage conversion section 6b and the output terminal. 9 to be connected. With this configuration, the switching unit 7 detects the detected voltage output from one of the voltage conversion units 6a and 6b to which the negative feedback current I2 is supplied (when the negative feedback current I2 is supplied to the voltage conversion unit 6a, , the second detection voltage Vd2 output from the voltage conversion unit 6b is applied to the output terminal 9 when the first detection voltage Vd1 output from the voltage conversion unit 6a and the negative feedback current I2 are supplied to the voltage conversion unit 6b. It is output as an output voltage Vo. The switching unit 7 (switches 7a and 7b in this example) is composed of a mechanical switch such as a relay, or a switch composed of a semiconductor element such as an analog switch.

The voltage conversion section 6a is a first voltage conversion section, and when the input section 11 is connected to the changeover switch 7a of the changeover section 7 and the negative feedback current I2 is output from the changeover switch 7a to the input section 11, This negative feedback current I2 is converted into the first detection voltage Vd1, and the first detection voltage Vd1 is output from the output section 12 as it is. In this example, as an example, the voltage conversion unit 6a is configured with a first detection resistor 13 having a predetermined resistance value R1 (eg, 50Ω). One end of the first detection resistor 13 is connected to the input section 11 and the output section 12, and the other end is connected to the reference potential portion (ground G) of the current sensor 1A, forming a current-voltage conversion circuit. With this configuration, the voltage conversion unit 6a converts the negative feedback current I2 input to the input unit 11 into the first detection voltage Vd1 (=I2×R1) by the first detection resistor 13 (resistance value R1), and Output from the output unit 12 . Also, the first detection voltage Vd1 is expressed as (I1×R1/n) using a first detection rate (R1/n) defined by the resistance value R1 and the number of turns n. In this example, since R1=50Ω and n=50, the voltage converter 6a converts the detected current I1 into the first detected voltage Vd1 at the first detection rate (numerical value "1").

The voltage conversion section 6b is a second voltage conversion section, and when the input section 21 is connected to the changeover switch 7b of the changeover section 7 and the negative feedback current I2 is output from the changeover switch 7b to the input section 21, This negative feedback current I2 is converted into a second detection voltage Vd2 and output from the output section 22. FIG. In this example, as an example, the voltage conversion unit 6b multiplies the input voltage by the second detection resistor 23 having a predetermined resistance value R2 (for example, 50Ω) by k (k is a predetermined real number exceeding 1. In this example, an amplifier (for example, a wideband amplifier composed of an operational amplifier) 24 that amplifies and outputs a numerical value "10" as an example, and an output resistor 25 connected between the output terminal of the amplifier 24 and the output section 22 (resistance value Ro. In this example, as an example, it is 50Ω), and is configured as a current-voltage conversion circuit. The second detection resistor 23 has one end connected to the input terminal of the input section 21 and the amplifier 24 and the other end connected to the ground G. With this configuration, the voltage conversion section 6 b converts the negative feedback current I2 input to the input section 21 into the second detection voltage Vd2 (=I2×R2×k) and outputs it from the output section 12 . Further, the second detection voltage Vd2 is obtained by using the second detection rate (R2/n×k) defined by the resistance value R2, the number of turns n, and the numerical value k (the amplification factor k of the amplifier 24) (I1×R2 /n×k). In this example, since R2=50Ω, n=50, and k=10, the voltage conversion unit 6b detects the detected current I1 is converted to a second detection voltage Vd2.

Next, the usage and operation of the current sensor 1A will be described with reference to the drawings. The current sensor 1A is used by connecting its output terminal 9 to a measuring instrument (for example, a waveform observation device such as an oscilloscope) having a high input impedance (for example, 1 MΩ or more). Thereby, in this measuring instrument, it is possible to observe the waveform of the detected current I1 detected by the current sensor 1A.

In a state in which the electric wire 61 to be detected through which the detection current I1 is flowing is inserted inside the magnetic core 2, the magnetoelectric converter 3 detects the magnetic flux generated inside the magnetic core 2, A voltage value V1 is output. In this case, inside the magnetic core 2, there are a magnetic flux φ1 generated by the detection current I1 flowing through the electric wire 61 to be detected, and a negative feedback current I2 (output from the voltage-current conversion circuit 5) to the feedback winding 4. A magnetic flux having a difference (φ1-φ2) from the magnetic flux φ2 generated by the flow of the current) is generated.

Based on the voltage V1 input from the magnetoelectric conversion unit 3, the voltage-current conversion circuit 5 generates a voltage inside the magnetic core 2 detected by the magnetoelectric conversion unit 3 so that the voltage V1 becomes zero volts. The negative feedback current I2 is generated and output to the feedback winding 4 while controlling the current value of the negative feedback current I2 so that the magnetic flux density of the existing magnetic flux (φ1-φ2) becomes zero. As a result, the current value of the negative feedback current I2 is a value obtained by dividing the current value of the detection current I1 by the number of turns n of the feedback winding 4 .

In the current sensor 1A, the switching unit 7 is switched according to the magnitude of the current value of the detected current I1 to be detected. Specifically, when the current value of the detected current I1 is large, the voltage conversion unit 6a is switched to a connection state in which the voltage conversion unit 6a is connected between the other end 4b of the feedback winding 4 and the output terminal 9 via the switching unit 7. Section 7 is switched. On the other hand, when the current value of the detected current I1 is small, the switching unit 7 is put into a connection state in which the voltage conversion unit 6b is connected between the other end 4b of the feedback winding 4 and the output terminal 9 via the switching unit 7. can be switched.

Regarding the first switching unit 7 and the second switching unit 8, the user of the current sensor 1A determines whether the current value of the detected current I1 is large or small, and based on the result of this determination, the first switching unit 7 and the second switching unit 8 are provided in the current sensor 1A, for example. The first switching unit 7 and the second switching unit 8 can be switched by operating an operation unit (not shown) provided (that is, manually). A processing unit (not shown) configured with a converter or the like is provided, and the processing unit detects the voltage value of the output voltage Vo via the A/D converter, and based on the magnitude of the detected voltage value of the output voltage Vo The first switching unit 7 and the second switching unit 8 can be switched by pressing (a configuration in which the detection rate is automatically switched).

First, since the current value of the detected current I1 is large, when the switching unit 7 is switched to the connection state in which the voltage conversion unit 6a is connected between the other end 4b of the feedback winding 4 and the output terminal 9, , the voltage conversion unit 6a converts the negative feedback current I2 input via the changeover switch 7a of the switching unit 7 into the first detection voltage Vd1 only by the first detection resistor 13, and the output unit 12 to the switching unit 7 is output to the output terminal 9 via the selector switch 7b. Thus, in the current sensor 1A, since the current value of the detection current I1 is large, the negative feedback current I2 is also large. converts the negative feedback current I2 into the first detection voltage Vd1 only by the first detection resistor 13 (that is, without being affected by noise generated by the amplifier), that is, the detection current I1 is converted into a first detection voltage Vd1 (=I1×R1/n) at a first detection rate (R1/n, numerical value “1” in this example) and output.

On the other hand, since the current value of the detected current I1 is small, when the switching unit 7 is switched to the connection state in which the voltage conversion unit 6b is connected between the other end 4b of the feedback winding 4 and the output terminal 9, , the voltage conversion unit 6b converts the negative feedback current I2 input through the switch 7a of the switching unit 7 into the second detection voltage Vd2 by the second detection resistor 23 and the amplifier 24, that is, the detection current I1 is converted into a first detection voltage Vd1 (=I1×R2/n×k) at a second detection rate (R2/n×k, numerical value “10” in this example), which is higher than the first detection rate, and the output section 22 to the output terminal 9 via the switch 7b of the switching unit 7. FIG. As described above, in the current sensor 1A, since the current value of the detection current I1 is small, the negative feedback current I2 is also small. Although affected by noise generated by the amplifier 24, the voltage conversion unit 6b converts the negative feedback current I2 into a second detection voltage Vd2 having a sufficient voltage value and outputs the second detection voltage Vd2.

As described above, in the current sensor 1A, since the current value of the detection current I1 is small, the negative feedback current I2 is also small. The voltage conversion unit 6b converts the detection current I1 into a second detection voltage Vd2 having a sufficient voltage value at the second detection rate and outputs the second detection voltage Vd2. If the voltage can be converted into a voltage with a sufficient voltage value only by the detection resistor, the voltage conversion unit 6a that does not include an amplifier converts the detection current I1 at a first detection rate that is lower than the second detection rate. The first detection voltage Vd1 having a sufficient voltage value is converted and output.

Therefore, according to this current sensor 1A, at any detection rate, the detection voltage detected by the detection resistor is amplified by an amplifier (operational amplifier) and output as an output voltage, unlike the conventional current sensor adopting the configuration. , the detected current I1 having a large current value can be converted to the first detected voltage Vd1 having a sufficient voltage value by the voltage conversion section 6a having a configuration that does not include an amplifier, and then output. That is, according to the current sensor 1A, the detection rate can be switched, and at one detection rate (first detection rate), the configuration does not include an amplifier, that is, without being affected by noise generated in the amplifier. , can output the first detection voltage Vd1.

In addition, in a current sensor configured to be used by connecting an output terminal to a measuring instrument, a sensor unit containing a magnetic core, a magnetoelectric converter, and a feedback winding, a voltage converter, and a connector of the measuring instrument A configuration is known in which the output terminal connected to the terminal unit is divided into two and the terminal unit is arranged on the surface, and the units are connected with a connection cable (coaxial cable, shielded cable, etc.). Applying the current sensor 1A results in FIG. In this case, since the magnetoelectric conversion unit 3 is susceptible to temperature changes, the voltage-to-current conversion circuit 5, which is composed of an operational amplifier or the like, generates a large amount of heat when outputting a large negative feedback current I2. is not accommodated in the same sensor unit 51 as the magnetoelectric converter 3, but is accommodated in the terminal unit 52. FIG.

However, unlike the second detection resistor 23 through which the negative feedback current I2 with a small current value flows, the first detection resistor 13 housed in the termination unit 52 carries a negative feedback current I2 with a larger current value. It also generates a lot of heat. Therefore, when the negative feedback current I2 having a large current value flows (at the first detection rate), the voltage-to-current conversion circuit 5 and the first detection resistor 13, both of which generate a large amount of heat, are accommodated in the same termination unit 52. 2, the temperature rise in the termination unit 52 may increase, which is not preferable.

Therefore, the current sensor 1B shown in FIG. 3 adopts a configuration having a relay unit 53 in addition to the sensor unit 51 and the terminal unit 52 . The current sensor 1B will be described below. The same reference numerals are assigned to the same configurations as those of the current sensor 1A and the current sensor shown in FIG. 2, and overlapping descriptions are omitted.

The current sensor 1B, as shown in FIG. ing. The sensor unit 51 accommodates the magnetic core 2, the magnetoelectric converter 3, and the feedback winding 4. The termination unit 52 accommodates the voltage converters 6a and 6b and the switching unit 7, and has output terminals on its surface. 9 is arranged, and the voltage-current conversion circuit 5 is housed in the relay unit 53 . The relay unit 53 is connected to the sensor unit 51 via a first connection cable CB1 (coaxial cable, shielded cable, etc.), and the terminal unit 52 is connected to the relay unit 53 and a second connection cable CB2 (coaxial cable, shielded cable, etc.). etc.). Further, the relay unit 53 has a transmission line TL1 for connecting the other end 4b of the feedback winding 4 in the sensor unit 51 and the switching section 7 in the termination unit 52 via respective connection cables CB1 and CB2. are housed. In addition, the voltage-to-current conversion circuit 5 in the relay unit 53 connects the magnetoelectric converter 3 in the sensor unit 51 and one end 4a of the feedback winding 4 via two wires forming the first connection cable CB1. , and one end of the transmission line TL1 is connected to the other end 4b of the feedback winding 4 via another wiring that constitutes the first connection cable CB1. Also, the other end of the transmission line TL1 is connected to the switching section 7 in the termination unit 52 via the wiring that constitutes the second connection cable CB2.

As described above, the current sensor 1B differs from the current sensor 1A in that each component is housed separately in the sensor unit 51, the relay unit 53, and the terminal unit 52. However, the basic configuration (magnetic core 2, The configuration including the magnetoelectric conversion section 3, the feedback winding 4, the voltage-to-current conversion circuit 5, the two voltage conversion sections 6a and 6b, the switching section 7, and the output terminal 9) is the same as that of the current sensor 1A. Works the same as 1A.

In this case, the relay unit 53 receives the voltage V1 from the magnetoelectric converter 3 of the sensor unit 51 via the first connection cable CB1, and the negative feedback current I2 output from the voltage-current conversion circuit 5 via the first connection cable. It is output to one end 4a of the feedback winding 4 in the sensor unit 51 via CB1. Further, the relay unit 53 inputs the negative feedback current I2 output from the other end 4b of the feedback winding 4 in the sensor unit 51 via the first connection cable CB1, and inputs the negative feedback current I2 via the transmission line TL1 to the second connection cable. Output to CB2. On the other hand, in the termination unit 52, the switching section 7 switches the negative feedback current I2 input via the second connection cable CB2 to either one of the voltage conversion sections 6a and 6b in the same manner as the current sensor 1A. At the same time, the detected voltage (first detected voltage Vd1 or second detected voltage Vd2) output from one of the voltage converters is output to the output terminal 9 .

As a result, the current sensor 1B detects the detection current I1 flowing through the electric wire 61 to be detected at the first detection voltage Vd1 and the second detection voltage Vd1 at any one selected from the first detection rate and the second detection rate. One of the detected voltages Vd2 is converted into one of the detected voltages corresponding to the one detection rate and output from the output terminal 9 as the output voltage Vo.

Therefore, with this current sensor 1B, as with the current sensor 1A, the detection rate can be switched, and at one detection rate (first detection rate), the current is generated with a configuration that does not include an amplifier, that is, with an amplifier. The detection current I1 can be converted into the first detection voltage Vd1 having a sufficient voltage value and output without being affected by noise. Further, according to the current sensor 1B, when the negative feedback current I2 having a large current value flows (at the first detection rate), the voltage-to-current conversion circuit 5 and the first detection resistor 13 both generate large amounts of heat. Since the voltage-current conversion circuit 5 is housed in the relay unit 53 and the first detection resistor 13 is housed in the termination unit 52, the voltage-current conversion circuit 5 and the first detection resistor 13 are housed in different units. Each heat generated in the detection resistor 13 can be distributed to different units. As a result, according to the current sensor 1B, both the temperature rise in the relay unit 53 and the temperature rise in the termination unit 52 can be kept low. Moreover, the influence of the heat generation of the first detection resistor 13 on the voltage-current conversion circuit 5 can be avoided. Further, the magnetic core 2, the magnetoelectric conversion section 3, and the feedback winding 4 provided in the sensor unit 51 can be prevented from being affected by the heat generated by the first detection resistor 13. FIG.

Further, the current sensors 1A and 1B have one voltage conversion section 6a as a first voltage conversion section (a voltage conversion section in which a current-voltage conversion circuit is configured by only detection resistors), and a second voltage conversion section. Although it is configured to have one voltage conversion unit 6b as (a voltage conversion unit in which a current-voltage conversion circuit is configured by a detection resistor and an amplifier), it is not limited to this configuration. Although not shown, it has two or more first voltage converters that form a current-voltage conversion circuit only with a detection resistor, and a second voltage converter that forms a current-voltage conversion circuit with a detection resistor and an amplifier. As a configuration having two or more, the switching unit 7 having the changeover switches 7a and 7b of the one-circuit n-contact structure (n is 3 or more) is any one first element (voltage conversion unit) of these voltage conversion units. is connected between the other end 4 b of the feedback winding 4 and the output terminal 9 .

In the current sensor 1B described above, when the negative feedback current I2 having a large current value flows (at the first detection rate), the voltage-current conversion circuit 5 and the first detection resistor 13 both generate large amounts of heat. Although the configuration in which only the voltage-current conversion circuit 5 is housed in the relay unit 53 is adopted, the configuration in which the voltage-current conversion circuit 5 and the first detection resistor 13 are housed in different units is not limited to this. For example, like the current sensor 1C shown in FIG. 6a, 6b, switching unit 7 and output terminal 9), only voltage conversion unit 6a and output terminal 9 are housed in termination unit 52, and the remaining components (voltage-to-current conversion circuit 5, voltage conversion unit 6b and switching 7) can be accommodated in the relay unit 53. FIG. The current sensor 1C will be described below. It should be noted that the same reference numerals are assigned to the same configurations as those of the current sensor 1B, and overlapping descriptions will be omitted.

The relay unit 53 of the current sensor 1C receives the voltage V1 from the magnetoelectric conversion section 3 of the sensor unit 51 via the first connection cable CB1, and receives the negative feedback current I2 output from the voltage-current conversion circuit 5 as the first It is output to one end 4a of the feedback winding 4 in the sensor unit 51 via the connection cable CB1. Also, the relay unit 53 inputs the negative feedback current I2 output from the other end 4b of the feedback winding 4 in the sensor unit 51 via the first connection cable CB1.

In this case, since the switches 7a and 7b of the switching unit 7 are switched in conjunction with each other, when the switch 7a is in a switching state in which the negative feedback current I2 is switched to one end of the transmission line TL1 and output, the switch 7b is in a switching state in which the other end of the transmission line TL1 is connected to the termination unit 52 via the second connection cable CB2. Further, when the changeover switch 7a is in a switching state in which the negative feedback current I2 is switched to the input section 21 of the voltage conversion section 6b and output, the changeover switch 7b switches the output section 22 of the voltage conversion section 6b through the second connection cable CB2. It will be in a switching state to connect to the termination unit 52 . With this configuration, in the relay unit 53, the switching section 7 switches the negative feedback current I2 to the first element of either the second voltage converting section 6b or the transmission line TL1 to output (supply) the first element, and is the second voltage converter 6b, the second detected voltage Vd2 as a signal output from the second voltage converter 6b. The negative feedback current I2 as a signal output from TL1 is output (supplied) to the first voltage converter 6a of the termination unit 52 via the second connection cable CB2.

On the other hand, in the termination unit 52, when the first voltage converter 6a inputs the negative feedback current I2 from the relay unit 53 via the second connection cable CB2, the first detection resistor 13 (resistance value R1) detects It is converted to a voltage Vd1 (=I2×R1) and output to the output terminal 9 as an output voltage Vo. This first detection voltage Vd1 is expressed as (I1×R1/n) using the first detection rate (R1/n).

Further, when the second detection voltage Vd2 is input from the relay unit 53 via the second connection cable CB2, the first voltage conversion section 6a outputs the second detection voltage Vd2 to the output terminal 9 as the output voltage Vo.

In this case, when the resistance value Ro of the output resistor 25 of the voltage conversion section 6b is a negligibly small value with respect to the resistance value R1 of the first detection resistor 13 constituting the first voltage conversion section 6a, the first voltage The conversion unit 6a outputs the second detection voltage Vd2 as it is to the output terminal 9 as the output voltage Vo. That is, the detected current I1 is converted into the second detected voltage Vd2 (=I1×R2/n×k) at the second detection rate (R2/n×k) and output as the output voltage Vo. On the other hand, as in this example, the resistance value Ro (50 Ω in this example) of the output resistor 25 of the voltage conversion unit 6b is equal to the resistance value R1 (50 Ω in this example) of the first detection resistor 13 constituting the first voltage conversion unit 6a. ), the first voltage converter 6a outputs the second detection voltage Vd2 divided by the first detection resistor 13 and the output resistor 25 to the output terminal 9 as the output voltage Vo. That is, the detection current I1 is the second detection rate (R2/n×k×R1/(R1+Ro)) different from the second detection rate described above, and the second detection voltage Vd2 and the first detection voltage Vd1 (= I1*R2/n*k*R1/(R1+Ro)) and output as the output voltage Vo. Therefore, in this current sensor 1C, by setting k=20, it is possible to match the second detection rate with the second detection rate (numerical value "10") in the current sensors 1A and 1B.

Therefore, in the current sensor 1C, like the current sensor 1A, the detection rate can be switched, and at one detection rate (first detection rate), the current is generated with a configuration that does not include an amplifier, that is, with an amplifier. The detection current I1 can be converted into the first detection voltage Vd1 having a sufficient voltage value and output without being affected by noise. Further, according to the current sensor 1C, when the negative feedback current I2 having a large current value flows (at the first detection rate), the voltage-to-current conversion circuit 5 and the first detection resistor 13 both generate large amounts of heat. Since the voltage-current conversion circuit 5 is housed in the relay unit 53 and the first detection resistor 13 is housed in the termination unit 52, the voltage-current conversion circuit 5 and the first detection resistor 13 are housed in different units. Each heat generated in the detection resistor 13 can be distributed to different units. As a result, according to the current sensor 1C, both the temperature rise in the relay unit 53 and the temperature rise in the termination unit 52 can be kept low. Further, according to the current sensor 1C, the voltage-current conversion circuit 5 and the current-voltage conversion circuit (the circuit composed of the second detection resistor 23 and the amplifier 24: the voltage conversion section 6b) are different from the first detection resistor 13. Since it is housed in the relay unit 53, the voltage-current conversion circuit 5 and It is possible to avoid the influence of the heat generated by the first detection resistor 13 on the amplifier 24 of the current-voltage conversion circuit.

Further, in each of the current sensors 1A, 1B, and 1C described above, as an example of a configuration in which a plurality of detection rates can be switched, a configuration in which two detection rates of a first detection rate and a second detection rate can be switched is adopted. However, it is also possible to adopt a configuration in which the three detection rates are switchable. Based on the current sensors 1B and 1C having the sensor unit 51, the relay unit 53 and the terminal unit 52, the current sensors 1D and 1E configured to switch between three detection rates will be described below. The same reference numerals are assigned to the same configurations as those of the current sensors 1B and 1C, and overlapping descriptions are omitted.

First, based on the current sensor 1B, a current sensor 1D that can switch between three detection rates will be described with reference to FIG. The configuration of the termination unit 52, which is different from that of the current sensor 1B, will be described below.

In addition to the voltage converters 6a and 6b, the switcher 7 and the output terminal 9, the terminal unit 52 accommodates the voltage converter 6c (another first voltage converter). Further, the changeover switches 7a and 7b constituting the changeover section 7 are configured, for example, as changeover switches having a 1-circuit, 3-contact structure, and the changeover section 7 selects any one of the three voltage conversion sections 6a, 6b, and 6c. switch to a connection state in which two first elements are connected between the second connection cable CB2 and the output terminal 9.

When the input section 31 is connected to the first switching section 7 and the negative feedback current I2 is output from the first switching section 7 to the input section 31, the voltage conversion section 6c converts the negative feedback current I2 into the third detection voltage. It is converted to Vd3 and output from the output section 32 as the output voltage Vo. The voltage conversion section 6c as the first voltage conversion section is configured by, as an example in this example, a third detection resistor 33 having a predetermined resistance value R3 (for example, 5Ω). The third detection resistor 33 has one end connected to the input section 31 and the output section 32, and the other end connected to a reference potential portion (ground G) in the current sensor 1D. With this configuration, the voltage conversion unit 6c converts the negative feedback current I2 input to the input unit 31 into the third detection voltage Vd3 (=I2×R3) by the third detection resistor 33 (resistance value R3), It is output from the output section 12 as it is as the output voltage Vo. Also, the third detection voltage Vd3 is expressed as (I1×R3/n) using a third detection rate (R3/n) defined by the resistance value R3 and the number of turns n. In this example, since R3=5Ω and n=50, the voltage conversion unit 6c converts the detection current I1 into the third detection voltage Vd3 at the third detection rate (numerical value “0.1”). .

With this configuration, in the current sensor 1D, the first detection rate (numerical value "1") and the second detection rate (numerical value "10") in the current sensors 1A and 1B, and the third detection rate (numerical value "0 .1") to convert the negative feedback current I2 to the output voltage Vo. Therefore, according to the current sensor 1D, three detection rates can be switched, and two of them (the first detection rate and the third detection rate) have a configuration that does not include an amplifier, that is, an amplifier. The detection current I1 can be converted into the first detection voltage Vd1 and the third detection voltage Vd3 and output without being affected by the generated noise. Also, in the current sensor 1D, similarly to the current sensor 1B, the heat generated in the voltage-current conversion circuit 5 and the heat generated in the first detection resistor 13 and the third detection resistor 33 are distributed to different units. Therefore, both the temperature rise in the relay unit 53 and the temperature rise in the termination unit 52 can be kept low. Moreover, the influence of the heat generation of the first detection resistor 13 and the third detection resistor 33 on the voltage-current conversion circuit 5 can be avoided.

Next, a current sensor 1E configured to switch between three detection rates based on the current sensor 1C will be described with reference to FIG. The configuration of the termination unit 52, which is different from that of the current sensor 1C, will be described below.

In addition to the voltage conversion section 6a and the output terminal 9, the termination unit 52 accommodates a voltage conversion section 6c (another first voltage conversion section) and a second switching section 8 (hereinafter simply referred to as a switching section 8). It is Similarly to the switching section 7, the switching section 8 is composed of switching switches 8a and 8b having a one-circuit two-contact structure. , 31, and the selector switch 8b is arranged between the output terminals 12, 32 and the output terminal 9 of the voltage converters 6a, 6c. With this configuration, in the switching unit 8, the switches 8a and 8b are interlocked to switch, so that the second element of any one of the two voltage conversion units 6a and 6c is connected to the second connection cable CB2 and the output terminal. 9 to a connected state. Also, the voltage conversion unit 6c is configured in the same manner as the current sensor 1D described above.

In the current sensor 1E having this configuration, the switching unit 7 has a current-voltage conversion circuit composed of a second detection resistor 23 and an amplifier 24 to convert the negative feedback current I2 output from the other end 4b of the feedback winding 4. Switching and outputting (supplying) to any one of the first elements of the voltage conversion unit 6b and the transmission line TL1, the signal output from the one first element is sent to the switching unit via the second connection cable CB2. 8 is output (supplied). Further, the switching unit 8 converts the signal supplied from the switching unit 7 to the second element of any one of the first detection resistor 13 (voltage conversion unit 6a) and the third detection resistor 33 (voltage conversion unit 6c). , and the signal output from the one second element is output to the output terminal 9 .

Specifically, the current sensor 1E is in a switching state in which the switching unit 7 switches to the transmission line TL1 as one of the first elements, and the switching unit 8 switches to the first detection resistor 13 as one of the second elements. In the state, the first detection resistor 13 converts the negative feedback current I2 supplied from the transmission line TL1 into the first detection voltage Vd1 and outputs it to the output terminal 9 as the output voltage Vo. Further, the current sensor 1E is in a switching state in which the switching unit 7 is switched to the voltage converting unit 6b (current-voltage converting circuit including the second detection resistor 23 and the amplifier 24) as one of the first elements, and the switching unit 8 is switched to the first detection resistor 13 as one of the second elements, the voltage conversion unit 6b and the first detection resistor 13 pass the negative feedback current I2 to the first detection resistor 13 having a resistance value R2 larger than that of the first detection resistor 13. The second detection resistor 23 converts the voltage into a voltage and amplifies it to convert it into a second detection voltage Vd2, which is output to the output terminal 9 as an output voltage Vo. In the switching state in which the switching unit 7 switches to the transmission line TL1 as one of the first elements, and in the switching state in which the switching unit 8 switches to the third detection resistor 33 as one of the second elements, the current sensor 1E The third detection resistor 33 converts the negative feedback current I2 into a third detection voltage Vd3 with a resistance value R3 smaller than that of the first detection resistor 13, and outputs the third detection voltage Vd3 to the output terminal 9 as an output voltage Vo.

With this configuration, in the current sensor 1E, the two detection rates of the current sensor 1C, the first detection rate (numerical value "1") and the second detection rate (numerical value "10"), are added to the third detection rate (numerical value "0.1 ”) to convert the detected current I1 into the output voltage Vo.

Also, in the current sensor 1E, similarly to the current sensor 1C, the detection rate can be switched, and the two detection rates (the first detection rate and the third detection rate) have a configuration that does not include an amplifier. That is, the detection current I1 can be converted into the first detection voltage Vd1 and the third detection voltage Vd3 and output without being affected by noise generated by the amplifier. Also, in the current sensor 1E, similarly to the current sensor 1C, the heat generated in the voltage-current conversion circuit 5 and the heat generated in the first detection resistor 13 and the third detection resistor 33 are distributed to different units. Therefore, both the temperature rise in the relay unit 53 and the temperature rise in the termination unit 52 can be kept low. Further, according to the current sensor 1E, the voltage-current conversion circuit 5 and the current-voltage conversion circuit (the circuit composed of the second detection resistor 23 and the amplifier 24: the voltage conversion section 6b) are connected to the first detection resistor 13 and the third Since it is housed in the relay unit 53 different from the detection resistor 33, it is housed in the termination unit 52 where the average temperature tends to be higher due to the heat generation of the first detection resistor 13 and the third detection resistor 33. Unlike the configuration shown in FIG.

Further, as described for the current sensor 1A, the other current sensors 1B to 1E are also provided with a processing unit (not shown) composed of a CPU and an A/D converter, and the processing unit is an A/D converter. along with detecting the voltage value of the output voltage Vo via and switching the switching unit 7 (further switching unit 8 in the current sensor 1E) based on the magnitude of the detected voltage value of the output voltage Vo (the detection rate is automatically Automatic switching processing of the switching detection rate) can also be executed.

Further, the current sensors 1A to 1E are provided with a processing unit having a D/A converter in addition to the CPU and the A/D converter, and the processing unit performs the automatic switching process of the detection rate as well as the voltage It is also possible to execute an offset adjustment process for adjusting the offset of the operational amplifier that constitutes the current conversion circuit 5 and the offset of the operational amplifier that constitutes the amplifier 24 . Based on the current sensor 1E, the current sensor 1F having this processing unit will be described below with reference to FIG. It should be noted that the same reference numerals are assigned to the same configurations as those of the current sensor 1E, and overlapping descriptions will be omitted.

This current sensor 1F includes a buffer 16 and a processing section 17 in addition to the configuration of the current sensor 1E described above. The buffer 16 detects the voltage of the second connection cable CB2 with high input impedance and outputs it to the processing section 17 .

The processing unit 17 includes a CPU 17a, an A/D converter (simply denoted as "A/D" in FIG. 7) 17b, and two D/A converters (simply denoted as "D/A" in FIG. ) 17c and 17d. The A/D converter 17b converts the voltage output from the buffer 16 (for example, a voltage having the same voltage value as the voltage of the second connection cable CB2) into voltage data D1 indicating the voltage value, and outputs the data to the CPU 17a. do.

The CPU 17a outputs a control signal S1 for switching the switching section 7 and a control signal S2 for switching the switching section 8 in the detection rate automatic switching process. This control signal S2 is output to the termination unit 52 via the second connection cable CB2. Further, in the offset adjustment process, the CPU 17a outputs adjustment data D2 for adjusting the offset of the operational amplifier that constitutes the voltage-current conversion circuit 5 to the D/A converter 17c. is output to the D/A converter 17d. The D/A converter 17 c converts the adjustment data D 2 input from the CPU 17 a into an adjustment voltage S 3 and outputs it to the offset adjustment terminal of the operational amplifier that constitutes the voltage-current conversion circuit 5 . Further, the D/A converter 17d converts the adjustment data D3 input from the CPU 17a into an adjustment voltage S4, and outputs the adjustment voltage S4 to the offset adjustment terminal of the operational amplifier constituting the amplifier 24. FIG.

Next, the offset adjustment processing will be specifically described.

First, the offset adjustment of the operational amplifier that constitutes the voltage-current conversion circuit 5 will be described. In this case, in a state where the electric wire 61 to be detected is not inserted into the magnetic core 2, the CPU 17a first outputs the control signal S1 for switching to the transmission line TL1 side to the switching section 7, and switches to the voltage conversion section 6a side. A control signal S2 for switching is output to the switching unit 8. As a result, the negative feedback current I2 resulting from the offset of the operational amplifier constituting the voltage-current conversion circuit 5 is output from the relay unit 53 to the sensor unit 51, and then output to the termination unit 52 via the relay unit 53. is converted into the first detection voltage Vd1 in the voltage conversion section 6a.

The CPU 17a detects the voltage value of the first detection voltage Vd1 based on the voltage data D1 input via the buffer 16 and the A/D converter 17b, and when the voltage value of the first detection voltage Vd1 becomes zero. The adjustment data D2 for the adjustment voltage S3 is changed so as to be closer, and is output to the D/A converter 17c. The D/A converter 17c converts this adjustment data D2 into an adjustment voltage S3 and outputs it to the offset adjustment terminal of the operational amplifier forming the voltage-current conversion circuit 5. FIG. The CPU 17a repeats changing the adjustment data D2 to the D/A converter 17c until the voltage value of the detected first detection voltage Vd1 becomes zero. Further, the CPU 17a stores the adjustment data D2 at the time when the voltage value of the first detection voltage Vd1 becomes zero, and continues to output this adjustment data D2 to the D/A converter 17c. As a result, the voltage value of the adjustment voltage S3 to the offset adjustment terminal of the operational amplifier constituting the voltage-current conversion circuit 5 is maintained at the voltage value when the voltage value of the first detection voltage Vd1 becomes zero. That is, the offset of the operational amplifier forming the voltage-current conversion circuit 5 is maintained at zero. This completes the offset adjustment of the operational amplifier forming the voltage-current conversion circuit 5 .

Note that (the voltage data D1 of) the first detection voltage Vd1 detected by the CPU 17a via the buffer 16 and the A/D converter 17b includes not only the offset of the operational amplifier constituting the voltage-current conversion circuit 5, Since the voltage generated due to the offset generated in the magnetoelectric conversion section 3 is also included, in the offset adjustment of the operational amplifier that constitutes the voltage-current conversion circuit 5, as a result, the calculation that constitutes the voltage-current conversion circuit 5 Offset adjustment in the amplifier and magnetoelectric conversion section 3 as a whole is completed.

Next, the offset adjustment of the operational amplifier that constitutes the amplifier 24 will be described. In this case, as described above, in a state in which the offset adjustment is completed in the entire operational amplifier and the magnetoelectric conversion section 3 that constitute the voltage-current conversion circuit 5 and the electric wire 61 to be detected is not inserted into the magnetic core 2, First, the CPU 17a outputs a control signal S1 for switching to the voltage conversion section 6b side to the switching section 7, and outputs a control signal S2 for switching to the voltage conversion section 6a side to the switching section 8. FIG. As a result, the voltage conversion unit 6b converts the negative feedback current I2 output from the voltage-current conversion circuit 5 in the state where the offset adjustment is completed into the second detection voltage Vd2, and outputs the second detection voltage Vd2. Since the negative feedback current I2 at this time is zero amperes, the second detection voltage Vd2 is a voltage resulting from the offset of the operational amplifier that constitutes the amplifier 24. FIG.

The CPU 17a detects the voltage value of the second detection voltage Vd2 based on the voltage data D1 input via the buffer 16 and the A/D converter 17b, and when the voltage value of the second detection voltage Vd2 becomes zero. The adjustment data D3 for the adjustment voltage S4 is changed so as to be closer, and is output to the D/A converter 17d. The D/A converter 17d converts this adjustment data D3 into an adjustment voltage S4 and outputs it to the offset adjustment terminal of the operational amplifier forming the amplifier 24. FIG. The CPU 17a repeats changing the adjustment data D3 to the D/A converter 17d until the voltage value of the detected second detection voltage Vd2 becomes zero. Further, the CPU 17a stores the adjustment data D3 at the time when the voltage value of the second detection voltage Vd2 becomes zero, and continues to output the adjustment data D3 to the D/A converter 17d. As a result, the voltage value of the adjustment voltage S4 to the offset adjustment terminal of the operational amplifier constituting the amplifier 24 is maintained at the voltage value when the voltage value of the second detection voltage Vd2 becomes zero. In other words, the offset of the operational amplifier that constitutes the amplifier 24 is maintained at zero. This completes the offset adjustment of the operational amplifier that constitutes the amplifier 24 .

Next, the detection rate automatic switching process will be specifically described. The current sensor 1F based on the current sensor 1E has a third detection rate when the negative feedback current I2 is supplied to the voltage conversion section 6c in the termination unit 52 via the transmission line TL1 of the relay unit 53. (numerical value “0.1”) and the first detection rate (numerical value “1”) when the negative feedback current I2 is supplied to the voltage conversion section 6a in the termination unit 52 via the transmission line TL1 of the relay unit 53. , the second detection rate (numerical value "10"), there are three detection rates. Therefore, the current sensor 1F has a detection range with the lowest third detection rate (the maximum detection range capable of detecting the largest detection current I1) and a detection range with the second lowest first detection rate (the second largest detection range). It has three detection ranges: an intermediate detection range capable of detecting the current I1) and a detection range of the highest second detection rate (minimum detection range capable of detecting the smallest detection current I1).

In this detection rate automatic switching process, the CPU 17a detects voltages in the current detection range (detection voltages Vd1, Vd2, Vd3 ), the detected voltage is within a predetermined range-up voltage range for the output voltage Vo (for example, a voltage range in which the maximum voltage value of the output voltage Vo is 90% or more) or a range It is determined whether or not it is included in a down voltage range (for example, a voltage range of 10% or less of the maximum voltage value of the output voltage Vo).

As a result of this determination, the CPU 17a outputs a control signal S1 to the switching unit 7 when the detected voltage is included in the range-up voltage range and there is a detection range above the current detection range, and A control signal S2 is output to the switching section 8, and the switching section 7 and the switching section 8 are interlocked and switched so that the detection range becomes higher (so that the detection rate is lowered by one step). Further, the CPU 17a outputs a control signal S1 to the switching unit 7 when the detection voltage is included in the range-down voltage range and a detection range below the current detection range exists as a result of this determination. At the same time, a control signal S2 is output to the switching section 8, and the switching section 7 and the switching section 8 are interlocked to switch to a lower detection range (to increase the detection rate by one step). As a result of this determination, when the detected voltage is not included in either the range-up voltage range or the range-down voltage range, the CPU 17a outputs the control signal S1 to the switching unit 7 and the switching unit 8. The current detection range is maintained (that is, the current detection rate is maintained) by maintaining the current state of the control signal S2 (that is, without switching the switching units 7 and 8).

In this current sensor 1F, as described above, the relay unit 53 and the terminal unit 52 are connected by disposing the buffer 16 and the processing unit 17 in the relay unit 53 containing the voltage-current conversion circuit 5 and the amplifier 24. The signal line of the second connection cable CB2 to be connected is only the signal line for the control signal S2 in addition to the signal line for transmitting the negative feedback current I2 and the detection voltage (any of the detection voltages Vd1, Vd2, and Vd3). can be done.

In each of the current sensors 1A, 1B, 1C, 1E, and 1F described above, the resistance value R1 of the first detection resistor 13 and the resistance value R2 of the second detection resistor 23 are set to 50Ω as an example because the first detection resistor 13 functions as a terminating resistor for a line from the other end 4b of the feedback winding 4 to the voltage conversion section 6a including the first detection resistor 13 (hereinafter also referred to as a first line for distinction), and also serves as a second detection resistor. Since the resistor 23 functions as a terminating resistor for a line (hereinafter also referred to as a second line for distinction) from the other end 4b of the feedback winding 4 to the voltage conversion section 6b including the second detection resistor 23, the impedance For matching, it is defined to be equivalent to each characteristic impedance (50Ω) of the first line and the second line.

In this case, in the current sensor 1A shown in FIGS. 1 and 2, the first line is from the other end 4b of the feedback winding 4 to the selector switch 7a (the current sensor 1A is divided into a sensor unit 51 and a termination unit 52). When they are connected to each other by the connection cable CB, it reaches the input section 11 of the voltage conversion section 6a via the connection cable CB and the changeover switch 7a (substantially the first detection resistor of the voltage conversion section 6a). 13). The second line is from the other end 4b of the feedback winding 4 to the input section 21 of the voltage conversion section 6b (substantially It is a line up to the second detection resistor 23 of the voltage conversion unit 6b).

Further, in the current sensor 1B shown in FIG. 3 and the current sensor 1D shown in FIG. 5, the first line means the first connection cable CB1, the transmission line TL1, the second connection cable CB2 from the other end 4b of the feedback winding 4. , and the line to the input section 11 of the voltage conversion section 6a via the switch 7a. The second line is the input section 21 of the voltage conversion section 6b from the other end 4b of the feedback winding 4 via the first connection cable CB1, the transmission line TL1, the second connection cable CB2, and the switch 7a. This is the line leading up to

In addition, in the current sensor 1C shown in FIG. 4, the first line includes the other end 4b of the feedback winding 4, the first connection cable CB1, the changeover switch 7a, the transmission line TL1, the changeover switch 7b, and the second connection cable. This line extends through CB2 to the input section 11 of the voltage conversion section 6a. The second line is a line from the other end 4b of the feedback winding 4 to the input section 21 of the voltage conversion section 6b via the first connection cable CB1 and the switch 7a.

Further, in the current sensor 1E shown in FIG. 6 and the current sensor 1F shown in FIG. This line extends through the switch 7b, the second connection cable CB2, and the switch 8a to the input section 11 of the voltage conversion section 6a. The second line is a line from the other end 4b of the feedback winding 4 to the input section 21 of the voltage conversion section 6b via the first connection cable CB1 and the switch 7a.

With this configuration, according to the current sensors 1A, 1B, 1C, 1D, 1E, and 1F described above, the resistance value R1 of the first detection resistor 13 that converts the negative feedback current I2 into the first detection voltage Vd1 is Since it is defined by the characteristic impedance (50Ω) of the first line that supplies the negative feedback current I2 to the first detection resistor 13, the waveform distortion of the first detection voltage Vd1 can be kept low. Further, when the detection current I1 is an AC signal, the negative feedback current I2 becomes an AC signal with the same frequency as the detection current I1. The combined impedance of the parallel circuit of the resistor 13 and this stray capacitance is converted into the first detection voltage Vd1. In this case, the conversion to the first detection voltage Vd1 in this parallel circuit is affected by the parameter represented by the multiplication value (C·R1) of the capacitance value C of the stray capacitance and the resistance value R1 of the first detection resistor 13. Accordingly, the higher the frequency of the negative feedback current I2, the lower the voltage value of the first detection voltage Vd1 (that is, the detection band of the negative feedback current I2 is limited). However, according to each of the current sensors 1A, 1B, 1C, 1D, 1E, and 1F, the resistance value R1 of the first detection resistor 13 forming the parallel circuit is as low as 50Ω, so the multiplication value (C The influence of the detection band limitation due to R1) can be reduced, and the detection band of the negative feedback current I2 can be expanded to higher frequencies.

Further, according to each of the current sensors 1A, 1B, 1C, 1D, 1E, and 1F, the second detection resistor 23 (second line terminal resistance) is defined by the characteristic impedance (50Ω) of the second line that supplies the negative feedback current I2 to the second detection resistor 23, the voltage across the second detection resistor 23, As a result, the waveform distortion of the second detection voltage Vd2 output from the voltage conversion section 6b can be kept low.

Further, in each of the current sensors 1A, 1B, 1C, 1D, 1E, and 1F, the first detection voltage Vd1 is output to the outside from the output terminal 9 as it is as the output voltage Vo at the first detection rate. The waveform distortion of the output voltage Vo at the 1 detection rate can be kept low. In each of the current sensors 1A, 1B, and 1D, when the second detection rate is used, the second detection voltage Vd2 is directly output from the output terminal 9 as the output voltage Vo to the outside. Waveform distortion of the output voltage Vo can be kept low.

Further, in each of the current sensors 1C, 1E, and 1F, at the second detection rate, the second detection voltage Vd2 is output from the output terminal 9 via the line terminated by the first detection resistor 13 as another resistor. As shown in FIG. 4, this line (in the current sensor 1C, from the output section 22 of the voltage conversion section 6b, through the switch 7b and the second connection cable CB2, the first It is a line leading to the detection resistor 13, and in the current sensors 1E and 1F, as shown in FIGS. to the first detection resistor 13. Hereinafter, in order to distinguish from the first and second lines that transmit the negative feedback current I2, the voltage transmission line is also referred to as a voltage transmission line, as shown in FIGS. In addition, it substantially overlaps with a portion of the first line described above. Therefore, the characteristic impedance of this voltage transmission line is defined to be the same as the characteristic impedance of the first line. Therefore, the second detection voltage Vd2 output from the voltage conversion unit 6b to this line is transmitted to the first detection resistor 13 while the waveform distortion is kept low, and is output as the output voltage Vo. Therefore, in each of the current sensors 1C, 1E and 1F as well, the waveform distortion of the output voltage Vo at the second detection rate can be kept low.

Further, in each of the current sensors 1C, 1E, and 1F, when the resistance value Ro of the output resistor 25 of the voltage conversion section 6b is defined to be equal to the characteristic impedance of the voltage transmission line (50Ω in this example), the voltage conversion section The output impedance of 6b will match the characteristic impedance of the voltage transmission line. Therefore, according to each of the current sensors 1C, 1E, and 1F having this configuration, the second detection rate output from the voltage conversion unit 6b at the second detection rate (R2/n.times.k.times.R1/(R1+Ro)) The voltage Vd2 can be transmitted to the first detection resistor 13 via the voltage transmission line with waveform distortion further suppressed.

Regarding the voltage transmission line described above, the characteristic impedance at a portion that does not overlap with a portion of the first line (the portion from the output portion 22 of the voltage conversion portion 6b to the changeover switch 7b) is the characteristic impedance of the first line. Even when there is no choice but to adopt a configuration that cannot be made equal, it is possible to suppress the waveform distortion of the output voltage Vo to a low level because the main part (the second connection cable CB2) is common.

In addition, in the current sensors 1D, 1E, and 1F of this example, as described above, the line (from the other end 4b of the feedback winding 4 to the third detection resistor 33) through which the negative feedback current I2 is transmitted at the third detection rate. (hereinafter also referred to as a third line for distinction) overlaps substantially the entire first line through which the negative feedback current I2 is transmitted at the first detection rate. Therefore, its characteristic impedance is configured to be equivalent to the characteristic impedance (50Ω) of the first line. On the other hand, the resistance value R3 of the third detection resistor 33, which functions as a terminating resistor for the third line, is 5Ω in this example. Therefore, at the third detection rate, the resistance value R3 of the third detection resistor 33 does not match the characteristic impedance of the third line.

However, when emphasis is placed on reducing the waveform distortion of the output voltage Vo at the third detection rate rather than reducing the waveform distortion of the output voltage Vo at the first detection rate or the second detection rate, the third detection It is of course possible to employ a configuration in which the resistance value R3 of the resistor 33 is defined as the characteristic impedance (50Ω) of the third line.

1A, 1B, 1C, 1D, 1E, 1F current sensor
2 magnetic core
3 Magnetoelectric converter
4 feedback winding
5 voltage-current conversion circuit 6a, 6b voltage conversion unit
7 first switching unit
8 second switching unit
9 output terminal 13 first detection resistor 23 second detection resistor 33 third detection resistor 61 detection conductor I1 detection current I2 negative feedback current Vd1 first detection voltage Vd2 second detection voltage Vd3 third detection voltage Vo output voltage

Claims (14)

A magnetic core through which a detection conductor is inserted, a magnetoelectric conversion section arranged in the magnetic core, a feedback winding wound around the magnetic core, and a magnetic flux generated in the magnetic core by a detection current flowing through the detection conductor. A current sensor comprising: a voltage-to-current converter circuit that generates a negative feedback current that cancels
1 for converting the negative feedback current output from the other end of the feedback winding into a voltage using a first detection resistor, thereby converting the detection current into a first detection voltage at a first detection rate and outputting the first detection voltage; Alternatively, by converting the negative feedback current into a voltage using two or more first voltage conversion units and a second detection resistor and amplifying the voltage with an amplifier, the detection current is made larger than the first detection rate having one or more second voltage converters that convert to a second detection voltage at a second detection rate and output the voltage;
switching to a connection state in which any one element of the one or more first voltage conversion units and the one or more second voltage conversion units is connected between the other terminal and the output terminal A current sensor with a switching unit. The resistance value of the detection resistor included in the arbitrary one element of the first detection resistor and the second detection resistance is the characteristic of the line from the other end of the feedback winding to the arbitrary one element. 2. The current sensor of claim 1, wherein the current sensor is defined as an impedance. a sensor unit containing the magnetic core, the magnetoelectric conversion unit, and the feedback winding;
a relay unit containing the voltage-current conversion circuit and the transmission line;
a termination unit housing the switching unit, the first voltage conversion unit, the second voltage conversion unit, and the output terminal;
a first connection cable;
and a second connection cable,
The sensor unit and the relay unit are connected via the first connection cable, and the voltage-to-current conversion circuit connects the magnetoelectric conversion section and the feedback winding via wiring that constitutes the first connection cable. and the one end of the transmission line is connected to the other end of the feedback winding via another wiring that constitutes the first connection cable,
The relay unit and the terminating unit are connected via the second connection cable, and the switching unit connects the other end of the transmission path and the 3. The current sensor according to claim 1, wherein the current sensor is switched to a connection state in which said arbitrary one element is connected between it and an output terminal. A magnetic core through which a detection conductor is inserted, a magnetoelectric conversion section arranged in the magnetic core, a feedback winding wound around the magnetic core, and a magnetic flux generated in the magnetic core by a detection current flowing through the detection conductor. A current sensor comprising: a voltage-to-current converter circuit that generates a negative feedback current that cancels
A first detection resistor that converts the supplied current into a voltage, a second detection resistor that converts the supplied current into a voltage, an amplifier that amplifies and outputs the voltage converted by the second detection voltage, a transmission line, and a switch has a part
The switching unit converts the negative feedback current output from the other end of the feedback winding to any one of a current-voltage conversion circuit including the second detection resistor and the amplifier and the transmission line. While switching and supplying to the element, supplying the signal output from the one element to the first detection resistor,
In a switching state in which the switching unit switches to the transmission line as the one element, the first detection resistor converts the negative feedback current into a voltage, thereby detecting the detection current at a first detection rate. converted to a voltage and output to the output terminal;
In a switching state in which the switching unit switches to the current-voltage conversion circuit as the one element, the current-voltage conversion circuit and the first detection resistor convert the negative feedback current into a voltage and amplify it, thereby A current sensor that converts a detected current into a second detected voltage at a second detection rate higher than the first detection rate and outputs the second detected voltage to the output terminal. The resistance value of the first detection resistor is defined as the characteristic impedance of the line from the other end of the feedback winding to the first detection resistor in a switching state in which the switching unit switches to the transmission line as the one element. 5. The current sensor according to claim 4, wherein The resistance value of the second detection resistor is the characteristic impedance of the line from the other end of the feedback winding to the current-voltage conversion circuit in the switching state in which the switching unit switches to the current-voltage conversion circuit as the one element. 5. The current sensor of claim 4, defined as: 7. The current sensor according to claim 6, wherein the resistance value of said first detection resistor is defined by the characteristic impedance of a line from said current-voltage conversion circuit to said first detection resistor. a sensor unit containing the magnetic core, the magnetoelectric conversion unit, and the feedback winding;
a relay unit housing the voltage-current conversion circuit, the transmission line, the current-voltage conversion circuit, and the switching unit;
a termination unit housing the first detection resistor and the output terminal;
a first connection cable;
and a second connection cable,
The sensor unit and the relay unit are connected via the first connection cable, and the voltage-to-current conversion circuit connects the magnetoelectric conversion section and the feedback winding via wiring that constitutes the first connection cable. is connected between the one end, and the switching unit is connected to the other end of the feedback winding via another wiring that constitutes the first connection cable;
The relay unit and the terminating unit are connected via the second connection cable, and the switching unit is the feedback winding connected via the other wiring constituting the first connection cable. 8. The connection state is switched to a connection state in which the one element is connected between the other end and the first detection resistor connected via a wiring constituting the second connection cable. current sensor. A magnetic core through which a detection conductor is inserted, a magnetoelectric conversion section arranged in the magnetic core, a feedback winding wound around the magnetic core, and a magnetic flux generated in the magnetic core by a detection current flowing through the detection conductor. A current sensor comprising: a voltage-to-current converter circuit that generates a negative feedback current that cancels
A first detection resistor that converts the supplied current into a voltage, a second detection resistor that converts the supplied current into a voltage, an amplifier that amplifies and outputs the voltage converted by the second detection voltage, and the supplied current has a third detection resistor, a transmission line, a first switching unit and a second switching unit for converting to voltage,
The first switching unit converts the negative feedback current output from the other end of the feedback winding to any one of a current-voltage conversion circuit including the second detection resistor and the amplifier and the transmission line. Switching and supplying to one first element, and supplying a signal output from the one first element to the second switching unit,
The second switching section switches and supplies the signal supplied from the first switching section to any one of the first detection resistor and the third detection resistor and supplies the second element to the one. outputting the signal output from the second element of to the output terminal;
In a switching state in which the first switching unit switches to the transmission line as the one first element and in a switching state in which the second switching unit switches to the first detection resistor as the one second element, 1 detection resistor converts the negative feedback current into a voltage, thereby converting the detection current into a first detection voltage at a first detection rate and outputting the first detection voltage to the output terminal;
In a switching state in which the first switching unit switches to the current-voltage conversion circuit as the one first element, and in a switching state in which the second switching unit switches to the first detection resistor as the one second element, The current-voltage conversion circuit and the first detection resistor convert the negative feedback current into a voltage and amplify it, thereby converting the detection current into a second detection voltage at a second detection rate higher than the first detection rate. converted and output to the output terminal;
In a switching state in which the first switching unit switches to the transmission line as the one first element and in a switching state in which the second switching unit switches to the third detection resistor as the one second element, 3 A current sensor in which a detection resistor converts the negative feedback current into a voltage, thereby converting the detection current into a third detection voltage at a third detection rate smaller than the first detection rate, and outputting the voltage to the output terminal. . The resistance value of the first detection resistor is a switching state in which the first switching section switches to the transmission line as the one first element, and the second switching section switches the one second element to the first detection. 10. The current sensor of claim 9, defined by the characteristic impedance of a line from said other end of said feedback winding to said first sensing resistor in a switched state of resistance. The resistance value of the second detection resistor is the switching state in which the first switching unit switches to the current-voltage conversion circuit as the one first element, and the second switching unit switches to the one second element as the one second element. 10. The current sensor according to claim 9, wherein the characteristic impedance of the line from the other end of the feedback winding to the current-voltage conversion circuit in a switching state in which 1 detection resistor is switched. 12. The current sensor according to claim 11, wherein the resistance value of said first detection resistor is defined by the characteristic impedance of a line from said current-voltage conversion circuit to said first detection resistor. The resistance value of the third detection resistor is a switching state in which the first switching unit is switched to the transmission line as the one first element, and the second switching unit is in the third detection as the one second element. 10. The current sensor of claim 9, defined by the characteristic impedance of a line from said other end of said feedback winding to said third sensing resistor in a switched state of resistance. a sensor unit containing the magnetic core, the magnetoelectric conversion unit, and the feedback winding;
a relay unit housing the voltage-current conversion circuit, the transmission line, the current-voltage conversion circuit, and the first switching unit;
a termination unit housing the first detection resistor, the third detection resistor, the second switching section, and the output terminal;
a first connection cable;
and a second connection cable,
The sensor unit and the relay unit are connected via the first connection cable, and the voltage-to-current conversion circuit connects the magnetoelectric conversion section and the feedback winding via wiring that constitutes the first connection cable. connected between the one end, and the first switching unit is connected to the other end of the feedback winding via another wiring that constitutes the first connection cable,
the relay unit and the terminal unit are connected via the second connection cable;
The first switching unit is connected to the other end of the feedback winding connected via the other wiring that configures the first connection cable and the wiring that configures the second connection cable. switching to a connection state in which the one first element is connected between the second switching unit;
14. The second switching unit according to any one of claims 9 to 13, wherein the second switching unit switches to a connection state in which the one second element is connected between the wiring that constitutes the second connection cable and the output terminal. current sensor.

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