JP2024056491A - Current Detector - Google Patents

Abstract

[Problem] To provide a current detection device that can easily detect current and suppresses deterioration of current detection accuracy. [Solution] In the current detection device, a first busbar portion 21 has a first side surface 211, a first recess 212, and a first rectification portion 213. The first side surface 211 intersects with the width direction DW. The first recess 212 is recessed in the width direction DW from the first side surface 211. The first rectification portion 213 extends in the width direction DW while adjacent to the first recess 212, and a current from a battery 12 flows through the first rectification portion 213. Furthermore, the first rectification portion 213 includes a first end 2131 and a second end 2132. A surface that passes through the first end 2131 and is perpendicular to the width direction DW is defined as a first surface S1. Furthermore, a surface that passes through the second end 2132 and is perpendicular to the width direction DW is defined as a second surface S2. The first voltage detection point P1 and the second voltage detection point P2 are disposed in the range from the first surface S1 to the second surface S2 in the width direction DW.

Description

This disclosure relates to a current detection device.

As described in Patent Document 1, a measuring resistor is known that has multiple pairs of voltage measurement contacts for measuring the voltage drop across a resistive element. In this measuring resistor, multiple voltage values are measured simultaneously at multiple pairs of voltage measurement contacts, and a voltage value is derived from these measured values by a weighted average, thereby quantitatively compensating for non-uniformity in the current density.

JP 2016-514841 A

In the measuring resistor described in Patent Document 1, multiple voltage values are used to quantitatively compensate for non-uniformity in current density, improving current detection accuracy. However, according to the inventor's investigation, the use of multiple voltage values complicates current calculation, which increases the calculation load.

The present disclosure aims to provide a current detection device that can easily detect current and suppresses deterioration of current detection accuracy.

The invention described in claim 1 is a current detection device, comprising a first busbar portion (21) formed in a plate shape, a resistive portion (31) connected to the first busbar portion and having an electrical resistance greater than that of the first busbar portion, a second busbar portion (22) connected to the side of the resistive portion opposite to the first busbar portion and having an electrical resistance smaller than that of the resistive portion, and a first terminal portion (6) that outputs a signal corresponding to a first voltage (V1) applied to the first busbar portion side of the resistive portion. a second terminal portion (62) that outputs a signal corresponding to a second voltage (V2) that is a voltage applied to the second busbar portion side of the resistor portion; a substrate (40, 41) on which the first terminal portion and the second terminal portion are arranged; a first connection portion (51) that is connected to the substrate, the resistor portion side of the first busbar portion, and the first terminal portion; a second connection portion (52) that is connected to the substrate, the resistor portion side of the second busbar portion, and the second terminal portion; and a first detection point (P1) that is a contact point between the first terminal portion and the first connection portion. a second detection point (P2) which is a contact point between the second terminal portion and the second connection portion, and a calculation unit (120) which calculates a device current (Ib) which is a current flowing from an external device (12) to the second busbar portion via the first busbar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion, and the first busbar portion has a side surface (211) intersecting a width direction (DW) of the first busbar portion, a recessed portion (212) recessed in the width direction from the side surface, and a recessed portion (213) extending in the width direction while being adjacent to the recessed portion in the width direction. and a rectifying section (213) through which a current from an external device flows. The rectifying section includes a first end (2131) that is the boundary with the recess, and a second end (2132) that is the end opposite the first end. If a surface that passes through the first end and is perpendicular to the width direction is defined as the first surface (S1), and a surface that passes through the second end and is perpendicular to the width direction is defined as the second surface (S2), the first detection point and the second detection point are disposed in the range from the first surface to the second surface in the width direction.

The invention described in claim 11 is a current detection device comprising a first busbar portion (21) formed in a plate shape, a resistive portion (31) connected to the first busbar portion and having an electrical resistance greater than that of the first busbar portion, a second busbar portion (22) connected to the side of the resistive portion opposite to the first busbar portion and having an electrical resistance smaller than that of the resistive portion, and a first terminal portion (61) that outputs a signal corresponding to a first voltage (V1) applied to the first busbar portion side of the resistive portion. a second terminal portion (62) that outputs a signal corresponding to a second voltage (V2) that is a voltage applied to the second bus bar portion side of the resistor portion; a substrate (40, 41) on which the first terminal portion and the second terminal portion are arranged; a first connection portion (51) that is connected to the substrate, the resistor portion side of the first bus bar portion, and the first terminal portion; a second connection portion (52) that is connected to the substrate, the resistor portion side of the second bus bar portion, and the second terminal portion; a first detection point (P1) that is a contact point between the first terminal portion and the first connection portion; and the second terminal portion. and the second connection portion, and a calculation unit (120) that calculates a device current (Ib) that is a current that flows from an external device (12) to the second busbar portion via the first busbar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion. The first busbar portion has a plate surface (215) that intersects with a thickness direction (DT) of the first busbar portion, a hole (216) extending in the thickness direction from the inside of the plate surface, and a hole (216) that is adjacent to the hole in the width direction (DW) of the first busbar portion and extends in the width direction ( DW) and a rectifying section (213) through which a current from an external device flows, the rectifying section includes a first end (2131) that is the boundary with the hole, and a second end (2132) that is the end opposite the first end, and if a surface that passes through the first end and is perpendicular to the width direction is defined as the first surface (S1), and a surface that passes through the second end and is perpendicular to the width direction is defined as the second surface (S2), the first detection point and the second detection point are disposed in the range from the first surface to the second surface in the width direction.

The invention described in claim 12 is a current detection device, comprising a first busbar portion (21) formed in a plate shape, a resistive portion (31) connected to the first busbar portion and having an electrical resistance greater than that of the first busbar portion, a second busbar portion (22) connected to the side of the resistive portion opposite to the first busbar portion and having an electrical resistance smaller than that of the resistive portion, a first terminal portion (61) connected to the first busbar portion and outputting a signal corresponding to a first voltage (V1) which is a voltage applied to the first busbar portion side of the resistive portion, a second terminal portion (62) connected to the second busbar portion and outputting a signal corresponding to a second voltage (V2) which is a voltage applied to the second busbar portion side of the resistive portion, a first detection point (P1) which is a contact point between the first terminal portion and the first busbar portion, a second detection point (P2) which is a contact point between the second terminal portion and the second busbar portion, and a first voltage and and a calculation unit (120) that calculates a device current (Ib) that is a current that flows from an external device (12) to the second busbar portion via the first busbar portion and the resistor portion based on the second voltage and the electrical resistance of the resistor portion. The first busbar portion has a side (211) that intersects with the width direction (DW) of the first busbar portion, a recess (212) that is recessed in the width direction from the side, and a rectification portion (213) that extends in the width direction while adjacent to the recess in the width direction and through which a current from the external device flows. The rectification portion includes a first end (2131) that is a boundary with the recess, and a second end (2132) that is an end opposite to the first end. If a surface that passes through the first end and is perpendicular to the width direction is defined as a first surface (S1), and a surface that passes through the second end and is perpendicular to the width direction is defined as a second surface (S2), the first detection point and the second detection point are disposed in the width direction in the range from the first surface to the second surface.

The range of the current flowing through the rectifier is smaller than that of the non-rectifier portion of the first busbar portion. As a result, the current flowing through the rectifier is rectified. Therefore, the current density of the rectifier is increased. In addition, the first detection point and the second detection point are arranged in the range from the first surface to the second surface in the width direction. As a result, a signal corresponding to the voltage corresponding to the current density increased by the rectifier is output from the first terminal portion and the second terminal portion. Therefore, the sensitivity to the device current is improved. Therefore, the signal-to-noise ratio of the device current is improved, and the deterioration of the current detection accuracy is suppressed. Furthermore, since it is not necessary to measure multiple pairs of voltages, the calculation is prevented from becoming complicated. Therefore, the current can be detected easily and the deterioration of the current detection accuracy is suppressed.

The reference symbols in parentheses attached to each component indicate an example of the correspondence between the component and the specific components described in the embodiments described below.

1 is a configuration diagram of a current detection device according to a first embodiment and a motor generator system in which the current detection device is used; FIG. FIG. 2 is an enlarged cross-sectional view taken along line III-III in FIG. FIG. 4 is an enlarged cross-sectional view taken along line IV-IV in FIG. 4 is a flowchart showing a method for manufacturing the current detection device. 5A to 5C are diagrams showing a preparation step in a manufacturing method of a current detection device. 5A to 5C are diagrams showing a connection step in the manufacturing method of the current detection device. 5A to 5C are diagrams showing a molding step in the manufacturing method of the current detection device. FIG. 9 is an enlarged view of part IX in FIG. 8 . FIG. 11 is a configuration diagram of a current detection device according to a second embodiment and a motor generator system in which the current detection device is used. FIG. 11 is an enlarged cross-sectional view taken along line XI-XI of FIG. FIG. 12 is an enlarged cross-sectional view taken along line XII-XII of FIG. FIG. 13 is a top view of a portion of a current detection device according to a third embodiment. FIG. 13 is a top view of a portion of a current detection device according to a fourth embodiment. FIG. 13 is a top view of a portion of a current detection device according to a fifth embodiment. FIG. 13 is a top view of a portion of a current detection device according to a sixth embodiment. FIG. 13 is a cross-sectional view of a portion of a current detection device according to a seventh embodiment. FIG. 3 is a cross-sectional view of a portion of the current detection device. FIG. 13 is a cross-sectional view of a portion of a current detection device according to an eighth embodiment. FIG. 2 is a cross-sectional view of a portion of the current detection device. FIG. 13 is a configuration diagram of a current detection device according to a ninth embodiment and a motor generator system in which the current detection device is used.

The following embodiments will be described with reference to the drawings. Note that in the following embodiments, parts that are identical or equivalent to each other will be given the same reference numerals and their description will be omitted.

First Embodiment
The current detection device 20 of this embodiment is used, for example, in a motor generator system 10 of a vehicle (not shown). First, the motor generator system 10 will be described.

As shown in FIG. 1, the motor generator system 10 includes a battery 12, an inverter 14, a motor generator 16, and a current detection device 20.

The battery 12 is, for example, a lithium ion secondary battery, a nickel-metal hydride secondary battery, or the like. The inverter 14 is connected to the battery 12. The inverter 14 also converts the direct current that flows from the battery 12 to the inverter 14 via the current detection device 20 described below into an alternating current. The inverter 14 then passes this converted alternating current through the motor generator 16 described below.

The motor generator 16 rotates using the AC current from the inverter 14. This causes, for example, the wheels of a vehicle (not shown) to rotate. The motor generator 16 also generates electricity based on the power input in reverse from the wheels of the vehicle (not shown). The current generated is converted from AC to DC by the inverter 14. The battery 12 is charged by this converted DC current.

The current detection device 20 is connected to the battery 12 and the inverter 14. The current detection device 20 also detects and calculates the current flowing from the battery 12 to the inverter 14.

Specifically, as shown in Figures 1 to 4, the current detection device 20 includes a first busbar portion 21, a first resistor portion 31, a second busbar portion 22, an intermediate portion 25, a third busbar portion 23, a second resistor portion 32, and a fourth busbar portion 24. The current detection device 20 also includes a first substrate 41, a second substrate 42, a first connection portion 51, a second connection portion 52, a third connection portion 53, a fourth connection portion 54, a first terminal portion 61, a second terminal portion 62, a third terminal portion 63, and a fourth terminal portion 64. The current detection device 20 also includes a first voltage detection point P1, a second voltage detection point P2, a third voltage detection point P3, a fourth voltage detection point P4, a first wiring 71, a second wiring 72, a third wiring 73, a fourth wiring 74, a first pin 81, a second pin 82, a third pin 83, and a fourth pin 84. The current detection device 20 also includes a first thermistor 91, a second thermistor 92, a third thermistor 93, and a fourth thermistor 94. The current detection device 20 also includes two first thermistor pins 101, two second thermistor pins 102, two third thermistor pins 103, and two fourth thermistor pins 104. The current detection device 20 also includes a first connector housing 111, a second connector housing 112, and a calculation unit 120.

The first busbar portion 21 is formed into a plate shape from copper or the like. Hereinafter, for convenience, the longitudinal direction DL of the first busbar portion 21 will be simply referred to as the longitudinal direction DL. The width direction DW of the first busbar portion 21 will be simply referred to as the width direction DW. Furthermore, the thickness direction DT of the first busbar portion 21 will be simply referred to as the thickness direction DT.

As shown in Figures 1 and 2, the first busbar portion 21 has a first connection hole 210, a first side surface 211, a first recess 212, and a first straightening portion 213.

Bolts (not shown) are inserted into the first connection hole 210 and the hole provided in the battery 12. This connects the first busbar portion 21 to the battery 12.

The first side surface 211 is a surface of the first busbar portion 21 that is perpendicular to the width direction DW and corresponds to a surface of the first busbar portion 21 that intersects with the width direction DW.

The first recess 212 is recessed in the width direction DW from the first side surface 211 on both sides. Here, the first recess 212 penetrates in the thickness direction DT. Furthermore, the first recess 212 is not in contact with the first resistance portion 31 described below, and is separated from the first resistance portion 31 described below. Here, the number of first recesses 212 is two, but is not limited to this. The number of first recesses 212 only needs to be at least one. Also, the shape of the first recess 212 is a quadrangular prism, but is not limited to this. The shape of the first recess 212 may be a polygonal prism, an arc prism, or the like.

2, the first rectifying portion 213 is adjacent to the first recess 212 in the width direction DW and extends in the width direction DW. A current from the battery 12 flows through the first rectifying portion 213. The first rectifying portion 213 further includes a first end 2131 and a second end 2132. The first end 2131 is the boundary between the first rectifying portion 213 and the first recess 212. The second end 2132 is the end of the first rectifying portion 213 opposite the first end 2131, and here is the boundary between the first rectifying portion 213 and the other first recess 212.

The first resistor 31 is a shunt resistor and is formed in a plate shape from a copper alloy containing manganese, nickel, etc. The first resistor 31 is connected to the first busbar portion 21 in the longitudinal direction DL by welding or the like. The electrical resistance of the first resistor 31 is greater than the electrical resistance of the first busbar portion 21. The length of the first resistor 31 in the thickness direction DT is smaller than the length of the first busbar portion 21 in the thickness direction DT, as shown in FIG. 3.

1 and 2, the second busbar portion 22 is formed in a plate shape from copper or the like. The second busbar portion 22 is connected to the side of the first resistance portion 31 opposite to the first busbar portion 21 in the longitudinal direction DL by welding or the like. The electrical resistance of the second busbar portion 22 is smaller than the electrical resistance of the first resistance portion 31. As shown in FIG. 3, the length of the second busbar portion 22 in the thickness direction DT is the same as the length of the first busbar portion 21 in the thickness direction DT, and is larger than the length of the first resistance portion 31 in the thickness direction DT. Here, "same" includes the manufacturing error range.

Furthermore, as shown in Figures 1 and 2, the second busbar portion 22 has a second side surface 221, a second recess 222, and a second straightening portion 223.

The second side surface 221 is a surface of the second busbar portion 22 that is perpendicular to the width direction DW and corresponds to a surface of the second busbar portion 22 that intersects with the width direction DW.

The second recesses 222 are recessed in the width direction DW from the second side surfaces 221 on both sides. Here, the second recesses 222 penetrate in the thickness direction DT. Furthermore, the second recesses 222 are not in contact with the first resistance portion 31 and are separated from the first resistance portion 31. Here, the number of second recesses 222 is two, but is not limited to this. The number of second recesses 222 only needs to be at least one. Also, the shape of the second recesses 222 is a quadrangular prism, but is not limited to this. The shape of the second recesses 222 may be a polygonal prism, an arc prism, or the like.

2, the second rectification portion 223 is adjacent to the second recess 222 in the width direction DW and extends in the width direction DW. A current flows from the battery 12 through the first busbar portion 21 and the first resistance portion 31 to the second rectification portion 223. The second rectification portion 223 further includes a third end 2231 and a fourth end 2232. The third end 2231 is a boundary between the second rectification portion 223 and the second recess 222. The fourth end 2232 is an end of the second rectification portion 223 opposite the third end 2231, and is the boundary between the second rectification portion 223 and the other second recess 222.

The intermediate portion 25 is formed in a plate shape from copper or the like. The intermediate portion 25 is connected to the second busbar portion 22 in the width direction DW. The electrical resistance of the intermediate portion 25 is smaller than the electrical resistance of the first resistance portion 31. The length of the intermediate portion 25 in the thickness direction DT is the same as the length of the first busbar portion 21 in the thickness direction DT and the length of the second busbar portion 22 in the thickness direction DT, and is larger than the length of the first resistance portion 31 in the thickness direction DT.

The third busbar portion 23 is formed in a plate shape from copper or the like. The third busbar portion 23 is connected to the side of the intermediate portion 25 opposite to the second busbar portion 22 in the width direction DW, and is therefore aligned with the second busbar portion 22 in the width direction DW. The electrical resistance of the third busbar portion 23 is smaller than the electrical resistance of the first resistance portion 31. The length of the third busbar portion 23 in the thickness direction DT is the same as the length of the first busbar portion 21 in the thickness direction DT, the length of the second busbar portion 22 in the thickness direction DT, and the length of the intermediate portion 25 in the thickness direction DT. Therefore, the length of the third busbar portion 23 in the thickness direction DT is greater than the length of the first resistance portion 31 in the thickness direction DT.

Furthermore, as shown in Figures 1 and 2, the third busbar portion 23 has a third side surface 231, a third recess 232, and a third straightening portion 233.

The third side surface 231 is a surface of the third busbar portion 23 that is perpendicular to the width direction DW and corresponds to a surface of the third busbar portion 23 that intersects with the width direction DW.

The third recess 232 is recessed in the width direction DW from the third side surface 231 on both sides. Here, the third recess 232 penetrates in the thickness direction DT. Furthermore, the third recess 232 is not in contact with the second resistance portion 32 described below, and is separated from the second resistance portion 32 described below. Here, the number of the third recesses 232 is two, but is not limited to this. The number of the third recesses 232 needs to be at least one. Also, the shape of the third recess 232 is a quadrangular prism, but is not limited to this. The shape of the third recess 232 may be a polygonal prism, an arc prism, or the like.

As shown in FIG. 2, the third rectification portion 233 is adjacent to the third recess 232 in the width direction DW and extends in the width direction DW. Furthermore, a current flows from the battery 12 through the first busbar portion 21, the first resistor portion 31, the second busbar portion 22, and the intermediate portion 25 to the third rectification portion 233. The third rectification portion 233 includes a fifth end 2331 and a sixth end 2332. The fifth end 2331 is a boundary between the third rectification portion 233 and the third recess 232. The sixth end 2332 is an end of the third rectification portion 233 opposite to the fifth end 2331, and is considered to be a boundary between the third rectification portion 233 and the other third recess 232.

The second resistor 32 is a shunt resistor and is formed in a plate shape from a copper alloy containing manganese and nickel. The second resistor 32 is connected to the third busbar portion 23 in the longitudinal direction DL by welding or the like. The second resistor 32 is arranged apart from the first resistor 31 in the width direction DW. The electrical resistance of the second resistor 32 is the same as the electrical resistance of the first resistor 31 and is greater than the electrical resistance of the first busbar portion 21, the second busbar portion 22, the intermediate portion 25, and the third busbar portion 23. The length of the second resistor 32 in the thickness direction DT is the same as the length of the first resistor 31 in the thickness direction DT. Therefore, the length of the second resistor 32 in the thickness direction DT is smaller than the length of the first busbar portion 21 in the thickness direction DT, the length of the second busbar portion 22 in the thickness direction DT, and the length of the intermediate portion 25 in the thickness direction DT. Therefore, as shown in FIG. 4, the length of the second resistor portion 32 in the thickness direction DT is smaller than the length of the third busbar portion 23 in the thickness direction DT. The electrical resistance of the second resistor portion 32 is the same as the electrical resistance of the first resistor portion 31, but is not limited to this. The electrical resistance of the second resistor portion 32 may be different from the electrical resistance of the first resistor portion 31. The length of the second resistor portion 32 in the thickness direction DT is the same as the length of the first resistor portion 31 in the thickness direction DT, but is not limited to this. The length of the second resistor portion 32 in the thickness direction DT may be different from the length of the first resistor portion 31 in the thickness direction DT.

1 and 2, the fourth busbar portion 24 is formed in a plate shape from copper or the like. The fourth busbar portion 24 is connected to the second resistor portion 32 on the opposite side to the third busbar in the longitudinal direction DL. The fourth busbar portion 24 is spaced apart from the first busbar portion 21 in the width direction DW. The electrical resistance of the fourth busbar portion 24 is smaller than the electrical resistance of the first resistor portion 31 and the electrical resistance of the second resistor portion 32. The length of the fourth busbar portion 24 in the thickness direction DT is the same as the length of the third busbar portion 23 in the thickness direction DT. Therefore, the length of the fourth busbar portion 24 in the thickness direction DT is the same as the length of the first busbar portion 21 in the thickness direction DT, the length of the second busbar portion 22 in the thickness direction DT, and the length of the intermediate portion 25 in the thickness direction DT. The length of the fourth busbar portion 24 in the thickness direction DT is greater than the length of the first resistor portion 31 in the thickness direction DT. In addition, as shown in FIG. 4, the length of the fourth busbar portion 24 in the thickness direction DT is greater than the length of the second resistor portion 32 in the thickness direction DT.

In the thickness direction DT, the length of the first busbar portion 21, the length of the second busbar portion 22, the length of the intermediate portion 25, the length of the third busbar portion 23, and the length of the fourth busbar portion 24 are the same, but this is not limited to the above. In the thickness direction DT, the length of the first busbar portion 21, the length of the second busbar portion 22, the length of the intermediate portion 25, the length of the third busbar portion 23, and the length of the fourth busbar portion 24 may be different from each other.

Furthermore, as shown in Figures 1 and 2, the fourth busbar portion 24 has a second connection hole 240, a fourth side surface 241, a fourth recess 242, and a fourth rectifying portion 243.

A bolt (not shown) is inserted into the second connection hole 240 and the inverter 14. This connects the fourth busbar portion 24 to the inverter 14. Therefore, the battery 12, the first busbar portion 21, the first resistor portion 31, the second busbar portion 22, the intermediate portion 25, the third busbar portion 23, the second resistor portion 32, the fourth busbar portion 24, and the inverter 14 are connected in series.

The fourth side surface 241 is a surface of the fourth busbar portion 24 that is perpendicular to the width direction DW and corresponds to a surface of the fourth busbar portion 24 that intersects with the width direction DW.

The fourth recess 242 is recessed in the width direction DW from the fourth side surface 241 on both sides. Here, the fourth recess 242 penetrates in the thickness direction DT. Furthermore, the fourth recess 242 is not in contact with the second resistance portion 32 and is separated from the second resistance portion 32. Here, the number of the fourth recesses 242 is two, but is not limited to this. The number of the fourth recesses 242 needs to be at least one. Also, the shape of the fourth recess 242 is a quadrangular prism, but is not limited to this. The shape of the fourth recess 242 may be a polygonal prism, an arc prism, or the like.

2, the fourth rectification portion 243 is adjacent to the fourth recess 242 in the width direction DW and extends in the width direction DW. In addition, a current flows from the battery 12 through the first busbar portion 21, the first resistor portion 31, the second busbar portion 22, the intermediate portion 25, the third busbar portion 23, and the second resistor portion 32 to the fourth rectification portion 243. Furthermore, the fourth rectification portion 243 includes a seventh end 2431 and an eighth end 2432. The seventh end 2431 is a boundary between the fourth rectification portion 243 and the fourth recess 242. The eighth end 2432 is an end of the fourth rectification portion 243 opposite to the seventh end 2431, and is here a boundary between the fourth rectification portion 243 and the other fourth recess 242.

The first substrate 41 is a printed circuit board. As shown in FIG. 1 and FIG. 3, the first substrate 41 has a first surface 411, a first back surface 412, a first through hole 413, and a second through hole 414.

The first surface 411 is a surface of the first substrate 41 that is perpendicular to the thickness direction DT and corresponds to a surface of the first substrate 41 that intersects with the thickness direction DT. Furthermore, the first surface 411 is located on the side of the first substrate 41 opposite the first resistor portion 31.

The first back surface 412 is a surface of the first substrate 41 that is perpendicular to the thickness direction DT, and corresponds to a surface of the first substrate 41 that intersects with the thickness direction DT. The first back surface 412 is also a surface of the first substrate 41 that is located on the first resistor portion 31 side, i.e., the side of the first substrate 41 opposite the first surface 411.

The first through hole 413 and the second through hole 414 are holes that penetrate the first surface 411 and the first back surface 412, respectively.

The second substrate 42 is a printed circuit board. As shown in FIG. 1 and FIG. 4, the second substrate 42 has a second surface 421, a second back surface 422, a third through hole 423, and a fourth through hole 424.

The second surface 421 is a surface of the second substrate 42 that is perpendicular to the thickness direction DT and corresponds to a surface of the second substrate 42 that intersects with the thickness direction DT. Furthermore, the second surface 421 is located on the side of the second substrate 42 opposite the second resistor section 32.

The second back surface 422 is a surface of the second substrate 42 that is perpendicular to the thickness direction DT and corresponds to a surface of the second substrate 42 that intersects with the thickness direction DT. The second back surface 422 is located on the second resistor section 32 side of the second substrate 42, that is, on the side of the second substrate 42 opposite to the first surface 411.

The third through hole 423 and the fourth through hole 424 are holes that penetrate the second surface 421 and the second back surface 422, respectively.

The first connection portion 51 is a land, a pad, solder, etc., and is connected to the portion of the first busbar portion 21 on the first resistor portion 31 side and the first back surface 412 as shown in FIG. 3. The second connection portion 52 is a land, a pad, solder, etc., and is connected to the portion of the second busbar portion 22 on the first resistor portion 31 side and the first back surface 412. The third connection portion 53 is a land, a pad, solder, etc., and is connected to the portion of the third busbar portion 23 on the second resistor portion 32 side and the second back surface 422 as shown in FIG. 4. The fourth connection portion 54 is a land, a pad, solder, etc., and is connected to the portion of the fourth busbar portion 24 on the second resistor portion 32 side and the second back surface 422.

The first terminal portion 61 is disposed on the first substrate 41 as shown in FIG. 1 and FIG. 3. A part of the first terminal portion 61 is inserted into the first through hole 413. The first terminal portion 61 protrudes from the first rear surface 412. The portion of the first terminal portion 61 on the first rear surface 412 side is connected to the first connection portion 51. Therefore, the first terminal portion 61 is connected to the first bus bar portion 21 side of the first resistor portion 31 via the first connection portion 51 and the first bus bar portion 21. Therefore, the first terminal portion 61 outputs a signal according to the voltage applied to the first bus bar portion 21 side of the first resistor portion 31.

The second terminal portion 62 is disposed on the first substrate 41. A portion of the second terminal portion 62 is inserted into the second through hole 414. The second terminal portion 62 protrudes from the first back surface 412. The portion of the second terminal portion 62 on the first back surface 412 side is connected to the second connection portion 52. Therefore, the second terminal portion 62 is connected to the second bus bar portion 22 side of the first resistor portion 31 via the second connection portion 52 and the second bus bar portion 22. Therefore, the second terminal portion 62 outputs a signal according to the voltage applied to the second bus bar portion 22 side of the first resistor portion 31.

As shown in Figs. 1 and 4, the third terminal portion 63 is disposed on the second substrate 42. A portion of the third terminal portion 63 is inserted into the third through hole 423. The third terminal portion 63 protrudes from the second rear surface 422. The portion of the third terminal portion 63 on the second rear surface 422 side is connected to the third connection portion 53. Therefore, the third terminal portion 63 is connected to the third bus bar portion 23 side of the second resistor portion 32 via the third connection portion 53 and the third bus bar portion 23. Therefore, the third terminal portion 63 outputs a signal according to the voltage applied to the third bus bar portion 23 side of the second resistor portion 32.

The fourth terminal portion 64 is disposed on the second substrate 42. A portion of the fourth terminal portion 64 is inserted into the fourth through hole 424. The fourth terminal portion 64 protrudes from the second back surface 422. The portion of the fourth terminal portion 64 on the second back surface 422 side is connected to the fourth connection portion 54. Therefore, the fourth terminal portion 64 is connected to the fourth bus bar portion 24 side of the second resistor portion 32 via the fourth connection portion 54 and the fourth bus bar portion 24. Therefore, the fourth terminal portion 64 outputs a signal according to the voltage applied to the fourth bus bar portion 24 side of the second resistor portion 32.

As shown in FIG. 3, the first voltage detection point P1 is a contact point between the first terminal 61 and the first connection 51. The second voltage detection point P2 is a contact point between the second terminal 62 and the second connection 52. As shown in FIG. 4, the third voltage detection point P3 is a contact point between the third terminal 63 and the third connection 53. The fourth voltage detection point P4 is a contact point between the fourth terminal 64 and the fourth connection 54.

Here, as shown in FIG. 2, a surface passing through the first end 2131 and perpendicular to the width direction DW is defined as the first surface S1. A surface passing through the second end 2132 and perpendicular to the width direction DW is defined as the second surface S2. A surface passing through the third end 2231 and perpendicular to the width direction DW is defined as the third surface S3. A surface passing through the fourth end 2232 and perpendicular to the width direction DW is defined as the fourth surface S4. A surface passing through the fifth end 2331 and perpendicular to the width direction DW is defined as the fifth surface S5. A surface passing through the sixth end 2332 and perpendicular to the width direction DW is defined as the sixth surface S6. A surface passing through the seventh end 2431 and perpendicular to the width direction DW is defined as the seventh surface S7. A surface passing through the eighth end 2432 and perpendicular to the width direction DW is defined as the eighth surface S8. In addition, the first surface S1 and the third surface S3 coincide with each other. The second surface S2 and the fourth surface S4 coincide with each other. The fifth surface S5 and the seventh surface S7 are coincident. The sixth surface S6 and the eighth surface S8 are coincident. The first surface S1 and the third surface S3 are not limited to being coincident and may not be coincident. The second surface S2 and the fourth surface S4 are not limited to being coincident and may not be coincident. The fifth surface S5 and the seventh surface S7 are not limited to being coincident and may not be coincident. The sixth surface S6 and the eighth surface S8 are not limited to being coincident and may not be coincident.

The first voltage detection point P1 and the second voltage detection point P2 are arranged in the range from the first surface S1 to the second surface S2 in the width direction DW. The first voltage detection point P1 and the second voltage detection point P2 are arranged in the range from the third surface S3 to the fourth surface S4 in the width direction DW. The third voltage detection point P3 and the fourth voltage detection point P4 are arranged in the range from the fifth surface S5 to the sixth surface S6 in the width direction DW. The third voltage detection point P3 and the fourth voltage detection point P4 are arranged in the range from the seventh surface S7 to the eighth surface S8 in the width direction DW. Note that FIG. 2 shows the positions of the first voltage detection point P1, the second voltage detection point P2, the third voltage detection point P3, and the fourth voltage detection point P4 when viewed from the thickness direction DT.

Returning to FIG. 1, the first wiring 71 is disposed on the first surface 411 and is connected to a portion of the first terminal 61 on the first surface 411 side. The second wiring 72 is disposed on the first surface 411 and is connected to a portion of the second terminal 62 on the first surface 411 side. The third wiring 73 is disposed on the second surface 421 and is connected to a portion of the third terminal 63 on the second surface 421 side. The fourth wiring 74 is disposed on the second surface 421 and is connected to a portion of the fourth terminal 64 on the second surface 421 side.

The first pin 81 is disposed on the first surface 411 and is connected to the first wiring 71. Therefore, the first pin 81 is connected to the first terminal portion 61 via the first wiring 71, and is therefore electrically conductive with the first terminal portion 61.

The second pin 82 is disposed on the first surface 411 and is connected to the second wiring 72. Therefore, the second pin 82 is connected to the second terminal portion 62 via the second wiring 72, and is therefore electrically conductive with the second terminal portion 62.

The third pin 83 is disposed on the second surface 421 and is connected to the third wiring 73. Therefore, the third pin 83 is connected to the third terminal portion 63 via the third wiring 73, and is therefore electrically conductive with the third terminal portion 63.

The fourth pin 84 is disposed on the second surface 421 and is connected to the fourth wiring 74. Therefore, the fourth pin 84 is connected to the fourth terminal portion 64 via the fourth wiring 74, and is therefore electrically conductive with the fourth terminal portion 64.

The first thermistor 91 is disposed on the first surface 411 and outputs a signal corresponding to the temperature of the first resistor section 31. The second thermistor 92 is disposed on the first surface 411 at a position different from the first thermistor 91 and outputs a signal corresponding to the temperature of the first resistor section 31. The third thermistor 93 is disposed on the second surface 421 and outputs a signal corresponding to the temperature of the second resistor section 32. The fourth thermistor 94 is disposed on the second surface 421 at a position different from the third thermistor 93 and outputs a signal corresponding to the temperature of the second resistor section 32.

One of the two first thermistor pins 101 is connected to one electrode of the first thermistor 91 via wiring (not shown) arranged on the first surface 411. The other of the two first thermistor pins 101 is connected to the other electrode of the first thermistor 91 via wiring (not shown) arranged on the first surface 411.

One of the two second thermistor pins 102 is connected to one electrode of the second thermistor 92 via wiring (not shown) arranged on the first surface 411. The other of the two second thermistor pins 102 is connected to the other electrode of the second thermistor 92 via wiring (not shown) arranged on the first surface 411.

One of the two third thermistor pins 103 is connected to one electrode of the third thermistor 93 via wiring (not shown) arranged on the second surface 421. The other of the two third thermistor pins 103 is connected to the other electrode of the third thermistor 93 via wiring (not shown) arranged on the second surface 421.

One of the two fourth thermistor pins 104 is connected to one electrode of the fourth thermistor 94 via wiring (not shown) arranged on the second surface 421. The other of the two fourth thermistor pins 104 is connected to the other electrode of the fourth thermistor 94 via wiring (not shown) arranged on the second surface 421.

The first connector housing 111 is formed in a cylindrical shape from, for example, resin. The first connector housing 111 is disposed on the first board 41. The first connector housing 111 accommodates the first pin 81, the second pin 82, two first thermistor pins 101, and two second thermistor pins 102. As shown in FIG. 3, when the first connector housing 111 is projected in the thickness direction DT, the projected first connector housing 111 does not overlap the first resistor portion 31, the second resistor portion 32, the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54, but is separated from them. The first connector housing 111 projected in the thickness direction DT overlaps with the second busbar portion 22.

The second connector housing 112 is formed into a cylindrical shape using, for example, resin. The second connector housing 112 is disposed on the second board 42. The second connector housing 112 further accommodates the third pin 83, the fourth pin 84, two third thermistor pins 103, and two fourth thermistor pins 104. As shown in FIG. 4, when the second connector housing 112 is projected in the thickness direction DT, the projected second connector housing 112 does not overlap with the first resistor portion 31, the second resistor portion 32, the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54, but is separated from them. Furthermore, the second connector housing 112 projected in the thickness direction DT overlaps with the third busbar portion 23 here.

The calculation unit 120 is mainly composed of an IC and a microcomputer, and includes a CPU, ROM, flash memory, RAM, I/O, a drive circuit, an AD converter, a low-pass filter, a communication circuit, and a bus line connecting these components. As shown in FIG. 1, the calculation unit 120 is disposed outside the first board 41 and the second board 42. The calculation unit 120 is not limited to being disposed outside the first board 41 and the second board 42, and may be disposed on the first board 41 or the second board 42, for example. IC is an abbreviation for Integrated Circuit.

The calculation unit 120 is also connected to the first pin 81, the second pin 82, the third pin 83, the fourth pin 84, the two first thermistor pins 101, the two second thermistor pins 102, the two third thermistor pins 103, and the two fourth thermistor pins 104. Therefore, the calculation unit 120 acquires a signal from the first terminal unit 61 via the first wiring 71 and the first pin 81. The calculation unit 120 acquires a signal from the second terminal unit 62 via the second wiring 72 and the second pin 82. The calculation unit 120 acquires a signal from the third terminal unit 63 via the third wiring 73 and the third pin 83. The calculation unit 120 acquires a signal from the fourth terminal unit 64 via the fourth wiring 74 and the fourth pin 84. The calculation unit 120 also acquires a signal from the first thermistor 91 via a wiring not shown and the first thermistor pin 101. The calculation unit 120 acquires a signal from the second thermistor 92 via a wiring not shown and the second thermistor pin 102. The calculation unit 120 acquires a signal from the third thermistor 93 via a wiring not shown and the third thermistor pin 103. The calculation unit 120 acquires a signal from the fourth thermistor 94 via a wiring not shown and the fourth thermistor pin 104. Then, as described later, the calculation unit 120 calculates the current flowing from the battery 12 based on these acquired signals. The calculation unit 120 also determines whether or not one of the first resistor unit 31 and the second resistor unit 32 is abnormal based on these acquired signals.

The motor generator system 10 is configured as described above. Next, we will explain how the current detection device 20 detects and calculates the current flowing from the battery 12 to the inverter 14.

Here, the following terms are defined to explain the detection and calculation of current by the current detection device 20. The voltage applied to the first busbar portion 21 side of the first resistor portion 31 is defined as a first voltage V1. The voltage applied to the second busbar portion 22 side of the first resistor portion 31 is defined as a second voltage V2. The voltage applied to the third busbar portion 23 side of the second resistor portion 32 is defined as a third voltage V3. The voltage applied to the fourth busbar portion 24 side of the second resistor portion 32 is defined as a fourth voltage V4. The electrical resistance of the first resistor portion 31 is defined as a first resistance R1. The electrical resistance of the second resistor portion 32 is defined as a second resistance R2. The temperature of the first resistor portion 31 is defined as a first temperature T1. The temperature of the second resistor portion 32 is defined as a second temperature T2. The current from the battery 12 is defined as a battery current Ib.

When the battery 12 discharges, a current flows from the battery 12 to the inverter 14 via the first bus bar portion 21, the first resistor portion 31, the second bus bar portion 22, the intermediate portion 25, the third bus bar portion 23, the second resistor portion 32 and the fourth bus bar portion 24.

At this time, the first terminal unit 61 outputs a signal corresponding to the first voltage V1 to the calculation unit 120 via the first wire 71 and the first pin 81. The second terminal unit 62 outputs a signal corresponding to the second voltage V2 to the calculation unit 120 via the second wire 72 and the second pin 82. The third terminal unit 63 outputs a signal corresponding to the third voltage V3 to the calculation unit 120 via the third wire 73 and the third pin 83. The fourth terminal unit 64 outputs a signal corresponding to the fourth voltage V4 to the calculation unit 120 via the fourth wire 74 and the fourth pin 84.

Furthermore, at this time, the first thermistor 91 outputs a signal corresponding to the first temperature T1 to the calculation unit 120 via wiring (not shown) and the first thermistor pin 101. The second thermistor 92 also outputs a signal corresponding to the first temperature T1 to the calculation unit 120 via wiring (not shown) and the second thermistor pin 102. The third thermistor 93 also outputs a signal corresponding to the second temperature T2 to the calculation unit 120 via wiring (not shown) and the third thermistor pin 103. The fourth thermistor 94 also outputs a signal corresponding to the second temperature T2 to the calculation unit 120 via wiring (not shown) and the fourth thermistor pin 104.

At this time, the calculation unit 120 acquires the first voltage V1, the second voltage V2, the third voltage V3, the fourth voltage V4, the first temperature T1, and the second temperature T2. The calculation unit 120 also calculates the corrected first resistance R1_C by correcting the first resistance R1 based on the acquired first temperature T1 and the resistance temperature coefficient of the first resistor unit 31 that is stored in advance. Furthermore, the calculation unit 120 calculates the corrected second resistance R2_C by correcting the second resistance R2 based on the acquired second temperature T2 and the resistance temperature coefficient of the second resistor unit 32 that is stored in advance.

Then, the calculation unit 120 calculates the battery current Ib based on the acquired first voltage V1, second voltage V2, third voltage V3, and fourth voltage V4, and the calculated corrected first resistance R1_C and corrected second resistance R2_C.

For example, the calculation unit 120 calculates the battery current Ib by dividing the difference between the first voltage V1 and the fourth voltage V4 by the sum of the corrected first resistance R1_C and the corrected second resistance R2_C, as shown in the following relational expression (1-1).

For example, the calculation unit 120 calculates the battery current Ib by dividing the difference between the first voltage V1 and the second voltage V2 by the corrected first resistance R1_C, as shown in the following relational expression (1-2).

For example, the calculation unit 120 calculates the battery current Ib by dividing the difference between the third voltage V3 and the fourth voltage V4 by the corrected second resistance R2_C, as shown in the following relational expression (1-3).

Also, for example, the calculation unit 120 calculates the battery current Ib by dividing the difference between the first voltage V1 and the third voltage V3 by the corrected first resistance R1_C, as shown in the following relational expression (1-4).

For example, the calculation unit 120 calculates the battery current Ib by dividing the difference between the second voltage V2 and the fourth voltage V4 by the corrected second resistance R2_C, as shown in the following relational expression (1-5).

Ib=(V1-V4)/(R1_C+R2_C) ...(1-1)
Ib=(V1-V2)/R1_C (1-2)
Ib=(V3-V4)/R2_C (1-3)
Ib=(V1-V3)/R1_C (1-4)
Ib=(V2-V4)/R2_C (1-5)

In the above calculation example, in order to make the calculation of the battery current Ib easier to understand, the calculation unit 120 calculates the battery current Ib by regarding the electrical resistance of the first bus bar portion 21, the second bus bar portion 22, the intermediate portion 25, the third bus bar portion 23, and the fourth bus bar portion 24 as zero. In contrast, the calculation unit 120 is not limited to calculating the battery current Ib by regarding the electrical resistance of the first bus bar portion 21, the second bus bar portion 22, the intermediate portion 25, the third bus bar portion 23, and the fourth bus bar portion 24 as zero. The calculation unit 120 may calculate the battery current Ib by taking into account the electrical resistance of the first bus bar portion 21, the second bus bar portion 22, the intermediate portion 25, the third bus bar portion 23, and the fourth bus bar portion 24.

As described above, the current detection device 20 detects and calculates the battery current Ib. Next, we will explain how the current detection device 20 determines whether or not one of the first resistor unit 31 and the second resistor unit 32 is abnormal.

Specifically, the calculation unit 120 determines whether or not one of the first resistance unit 31 and the second resistance unit 32 is abnormal based on the first voltage V1, the second voltage V2, the third voltage V3, and the fourth voltage V4, and the corrected first resistance R1_C and the corrected second resistance R2_C.

Here, for example, as shown in the above relational expression (1-2), the battery current Ib calculated by dividing the difference between the first voltage V1 and the second voltage V2 by the first resistor R1_C after correction is defined as the first battery current Ib1. Also, as shown in the above relational expression (1-3), the battery current Ib calculated by dividing the difference between the third voltage V3 and the fourth voltage V4 by the second resistor R2_C after correction is defined as the second battery current Ib2.

Then, the calculation unit 120 calculates the absolute value of the difference between the first battery current Ib1 and the second battery current Ib2, |Ib1-Ib2|.

Here, it is assumed that the first resistor section 31 and the second resistor section 32 are normal. At this time, the first battery current Ib1 and the second battery current Ib2 are the same, so the absolute value |Ib1-Ib2| is 0. Furthermore, it is assumed that the first resistor section 31 is abnormal and the second resistor section 32 is normal. At this time, the corrected first resistor R1_C has an abnormal value, so the first battery current Ib1 is different from the second battery current Ib2, so the absolute value |Ib1-Ib2| is larger than when the first resistor section 31 and the second resistor section 32 are normal. Also, it is assumed that the first resistor section 31 is normal and the second resistor section 32 is abnormal. At this time, the corrected second resistor R2_C has an abnormal value, so the second battery current Ib2 is different from the first battery current Ib1, so the absolute value |Ib1-Ib2| is larger than when the first resistor section 31 and the second resistor section 32 are normal.

Therefore, as shown in the following relational expression (1-6), the calculation unit 120 determines whether the absolute value |Ib1-Ib2| is equal to or greater than the threshold value ΔIb_th. As a result, the calculation unit 120 determines whether one of the first resistance unit 31 and the second resistance unit 32 is abnormal. Note that the threshold value ΔIb_th is set by experiment, simulation, or the like so that it can be determined whether one of the first resistance unit 31 and the second resistance unit 32 is abnormal.

|Ib1-Ib2|≧ΔIb_th ... (1-6)

When the absolute value |Ib1-Ib2| is equal to or greater than the threshold value ΔIb_th, the first battery current Ib1 and the second battery current Ib2 are significantly different, and the calculation unit 120 determines that one of the first resistance unit 31 and the second resistance unit 32 is abnormal. When the absolute value |Ib1-Ib2| is less than the threshold value ΔIb_th, the first battery current Ib1 and the second battery current Ib2 are approximately the same, and the calculation unit 120 determines that the first resistance unit 31 and the second resistance unit 32 are normal.

In the above judgment example, the first battery current Ib1 is the battery current Ib shown in the above relational expression (1-2), and the second battery current Ib2 is the battery current Ib shown in the above relational expression (1-3). In contrast, the first battery current Ib1 is not limited to being the battery current Ib shown in the above relational expression (1-2), and the second battery current Ib2 is not limited to being the battery current Ib shown in the above relational expression (1-3). For example, the first battery current Ib1 may be the battery current Ib shown in the above relational expression (1-4), and the second battery current Ib2 may be the battery current Ib shown in the above relational expression (1-5). Also, the first battery current Ib1 may be the battery current Ib shown in the above relational expression (1-1), and the second battery current Ib2 may be the battery current Ib shown in the above relational expressions (1-2) to (1-5). Also, in the above judgment example, in order to make the abnormality judgment easier to understand, the calculation unit 120 performs the abnormality judgment assuming that the electrical resistance of the first bus bar portion 21, the second bus bar portion 22, the intermediate portion 25, the third bus bar portion 23, and the fourth bus bar portion 24 is zero. In contrast, the calculation unit 120 is not limited to performing the abnormality judgment assuming that the electrical resistance of the first bus bar portion 21, the second bus bar portion 22, the intermediate portion 25, the third bus bar portion 23, and the fourth bus bar portion 24 is zero. The calculation unit 120 may perform the abnormality judgment taking into account the electrical resistance of the first bus bar portion 21, the second bus bar portion 22, the intermediate portion 25, the third bus bar portion 23, and the fourth bus bar portion 24.

As described above, the current detection device 20 determines whether or not one of the first resistance portion 31 and the second resistance portion 32 is abnormal. Next, a method for manufacturing the current detection device 20 of this embodiment will be described with reference to the flowchart of FIG. 5. The method for manufacturing the current detection device 20 includes a preparation process S100, a connection process S102, a molding process S104, and an assembly process S106.

In the preparation process S100, as shown in FIG. 6, a first member 141, a resistance member 150, and a second member 142 are prepared. The first member 141 is formed in a plate shape from copper or the like. The length of the first member 141 in the width direction DW is relatively large. The resistance member 150 is formed in a plate shape from a copper alloy containing manganese, nickel, and the like. The length of the resistance member 150 in the width direction DW is the same as the length of the first member 141 in the width direction DW. The second member 142 is formed in a plate shape from copper or the like. The length of the second member 142 in the width direction DW is the same as the length of the first member 141 in the width direction DW and the length of the resistance member 150 in the width direction DW.

Next, in the connection step S102, the first member 141 is connected to the resistance member 150 in the longitudinal direction DL by welding or the like, and the second member 142 is connected to the resistance member 150 on the opposite side to the first member 141 in the longitudinal direction DL. As a result, a connection body is formed in which the first member 141, the resistance member 150, and the second member 142 are integrated, as shown in FIG. 7.

Next, in the forming process S104, as shown in Figures 8 and 9, the first member 141, the resistance member 150, and the second member 142 that have been integrated in the connecting process S102 are punched out in the thickness direction DT by the first punch 151 and the second punch 152. Also, the first member 141, the resistance member 150, and the second member 142 that have been integrated in the connecting process S102 are punched out in the thickness direction DT by the third punch 153 and the fourth punch 154.

The first punches 151 are arranged at intervals in the width direction DW. The length of the first punch 151 in the longitudinal direction DL is greater than the length of the connecting body in the longitudinal direction DL. Therefore, the connecting body is divided into multiple pieces by punching with the first punch 151, and multiple pieces are lined up in the width direction DW.

The second punches 152 are arranged at intervals in the width direction DW. The first punch 151 is disposed between the adjacent second punches 152. The second punch 152 punches out the first member 141 and the resistance member 150 of the integrated first member 141, resistance member 150, and second member 142, and punches out a part of the second member 142. As a result, the first member 141 becomes the first busbar portion 21 and the fourth busbar portion 24. The resistance member 150 becomes the first resistance portion 31 and the second resistance portion 32. The second member 142 becomes the second busbar portion 22, the intermediate portion 25, and the third busbar portion 23. Thus, the first busbar portion 21, the first resistance portion 31, the second busbar portion 22, the intermediate portion 25, the third busbar portion 23, and the fourth busbar portion 24 are formed.

The third punch 153 is formed in a shape corresponding to the first connection hole 210 and the second connection hole 240. Therefore, by punching with the third punch 153, the first connection hole 210 is formed in the first bus bar portion 21. In addition, the second connection hole 240 is formed in the fourth bus bar portion 24.

The fourth punch 154 is formed in a shape corresponding to the first recess 212, the second recess 222, the third recess 232, and the fourth recess 242. Therefore, by punching with the fourth punch 154, the first recess 212 is formed in the first busbar portion 21. In addition, the second recess 222 is formed in the second busbar portion 22. Furthermore, the third recess 232 is formed in the third busbar portion 23. In addition, the fourth recess 242 is formed in the fourth busbar portion 24.

Next, in the assembly process S106, the first connection portion 51 is formed on the first back surface 412 by soldering or the like, and the first connection portion 51 is connected to the portion of the first busbar portion 21 on the first resistor portion 31 side and the first terminal portion 61. As a result, the first terminal portion 61 is connected to the first busbar portion 21 side of the first resistor portion 31 via the first connection portion 51 and the first busbar portion 21. Therefore, the first terminal portion 61 can output a signal according to the first voltage V1. In addition, the first voltage detection point P1 is arranged in the range from the first surface S1 to the second surface S2 in the width direction DW. Furthermore, the first voltage detection point P1 is arranged in the range from the third surface S3 to the fourth surface S4 in the width direction DW.

In addition, the second connection portion 52 is formed on the first back surface 412 by soldering or the like, and the second connection portion 52 is connected to the portion of the second busbar portion 22 on the first resistor portion 31 side and the second terminal portion 62. As a result, the second terminal portion 62 is connected to the second busbar portion 22 side of the first resistor portion 31 via the second connection portion 52 and the second busbar portion 22. Therefore, the second terminal portion 62 can output a signal according to the second voltage V2. In addition, the second voltage detection point P2 is arranged in the range from the first surface S1 to the second surface S2 in the width direction DW. Furthermore, the second voltage detection point P2 is arranged in the range from the third surface S3 to the fourth surface S4 in the width direction DW.

Furthermore, the third connection portion 53 is formed on the second back surface 422 by soldering or the like, and the third connection portion 53 is connected to the portion of the third busbar portion 23 on the second resistor portion 32 side and the third terminal portion 63. As a result, the third terminal portion 63 is connected to the third busbar portion 23 side of the second resistor portion 32 via the third connection portion 53 and the third busbar portion 23. Therefore, the third terminal portion 63 can output a signal according to the third voltage V3. Furthermore, the third voltage detection point P3 is arranged in the range from the fifth surface S5 to the sixth surface S6 in the width direction DW. Furthermore, the third voltage detection point P3 is arranged in the range from the seventh surface S7 to the eighth surface S8 in the width direction DW.

In addition, a fourth connection portion 54 is formed on the second back surface 422 by soldering or the like, and the fourth connection portion 54 is connected to a portion of the fourth bus bar portion 24 on the second resistor portion 32 side and to the fourth terminal portion 64. As a result, the fourth terminal portion 64 is connected to the fourth bus bar portion 24 side of the second resistor portion 32 via the fourth connection portion 54 and the fourth bus bar portion 24. Therefore, the fourth terminal portion 64 can output a signal according to the fourth voltage V4. In addition, the fourth voltage detection point P4 is arranged in the range from the fifth surface S5 to the sixth surface S6 in the width direction DW. Furthermore, the fourth voltage detection point P4 is arranged in the range from the seventh surface S7 to the eighth surface S8 in the width direction DW.

Furthermore, the first board 41 is provided with a first pin 81, a second pin 82, a first thermistor 91, a second thermistor 92, two pins 101 for the first thermistor, and two pins 102 for the second thermistor. The second board 42 is provided with a third pin 83, a fourth pin 84, a third thermistor 93, a fourth thermistor 94, two pins 103 for the third thermistor, and two pins 104 for the fourth thermistor.

Furthermore, suppose that the first connector housing 111 housing the first pin 81, the second pin 82, the two first thermistor pins 101, and the two second thermistor pins 102 is projected in the thickness direction DT. The first connector housing 111 is positioned so that the projected first connector housing 111 does not overlap the first resistor portion 31, the second resistor portion 32, the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54.

The second connector housing 112, which houses the third pin 83, the fourth pin 84, the two third thermistor pins 103, and the two fourth thermistor pins 104, is projected in the thickness direction DT. The second connector housing 112 is positioned so that the projected second connector housing 112 does not overlap the first resistor portion 31, the second resistor portion 32, the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54.

Furthermore, the first pin 81, the second pin 82, the third pin 83, the fourth pin 84, the two first thermistor pins 101, the two second thermistor pins 102, the two third thermistor pins 103, and the two fourth thermistor pins 104 are connected to the calculation unit 120. This completes the current detection device 20.

The current detection device 20 is manufactured as described above. Next, we will explain how the current detection device 20 can easily detect current and suppresses deterioration in current detection accuracy.

As described in Patent Document 1, a measuring resistor is known that has multiple pairs of voltage measurement contacts for measuring the voltage drop across a resistive element. In this measuring resistor, multiple voltage values are measured simultaneously at multiple pairs of voltage measurement contacts, and a voltage value is derived from these measured values by a weighted average, thereby quantitatively compensating for non-uniformity in current density. In the measuring resistor described in Patent Document 1, multiple voltage values are used to quantitatively compensate for non-uniformity in current density, improving current detection accuracy. However, the use of multiple voltage values complicates current calculation. This increases the calculation load.

In contrast, the current detection device 20 of this embodiment includes a first busbar portion 21, a first resistor portion 31, a second busbar portion 22, a first terminal portion 61, and a second terminal portion 62. The current detection device 20 also includes a first substrate 41, a first connection portion 51, a second connection portion 52, a first voltage detection point P1, and a second voltage detection point P2. The first substrate 41 is provided with a first terminal portion 61 and a second terminal portion 62. The first connection portion 51 is connected to the first substrate 41, the first resistor portion 31 side of the first busbar portion 21, and the first terminal portion 61. The second connection portion 52 is connected to the second substrate 42, the first resistor portion 31 side of the second busbar portion 22, and the second terminal portion 62. The first voltage detection point P1 is a contact point between the first terminal portion 61 and the first connection portion 51. The second voltage detection point P2 is the contact point between the second terminal portion 62 and the second connection portion 52. The first voltage detection point P1 corresponds to the first detection point. The second voltage detection point P2 corresponds to the second detection point.

The first busbar portion 21 also has a first side surface 211, a first recess 212, and a first rectifying portion 213. The first side surface 211 intersects with the width direction DW. The first recess 212 is recessed in the width direction DW from the first side surface 211. The first rectifying portion 213 extends in the width direction DW while adjacent to the first recess 212, and a current flows through the first rectifying portion 213 from the battery 12. Furthermore, the first rectifying portion 213 includes a first end 2131 and a second end 2132.

As described above, the plane that passes through the first end 2131 and is perpendicular to the width direction DW is defined as the first plane S1. Furthermore, the plane that passes through the second end 2132 and is perpendicular to the width direction DW is defined as the second plane S2. The first voltage detection point P1 and the second voltage detection point P2 are disposed in the range from the first plane S1 to the second plane S2 in the width direction DW.

The range of the current flowing through the first rectifier 213 is smaller than that of the portion of the first busbar portion 21 that is not the first rectifier 213. As a result, the current flowing through the first rectifier 213 is rectified. Therefore, the current density of the first rectifier 213 is increased. In addition, the first voltage detection point P1 and the second voltage detection point P2 are arranged in the range from the first surface S1 to the second surface S2 in the width direction DW. As a result, a signal corresponding to the voltage corresponding to the current density increased by the first rectifier 213 is output from the first terminal portion 61 and the second terminal portion 62. Therefore, the sensitivity to the battery current Ib is improved. Therefore, the signal-to-noise ratio for the battery current Ib is improved, and the deterioration of the current detection accuracy is suppressed. Furthermore, since it is not necessary to measure multiple pairs of voltages, the calculation is suppressed from becoming complicated. Therefore, the current can be detected easily, and the deterioration of the current detection accuracy is suppressed.

In addition, here, when the connection direction between the battery 12 and the first busbar portion 21 is the longitudinal direction DL, the direction of the current flowing from the battery 12 to the first busbar portion 21 is the longitudinal direction DL. Furthermore, when the connection direction between the battery 12 and the first busbar portion 21 is the width direction DW, the direction of the current flowing from the battery 12 to the first busbar portion 21 is the width direction DW. Therefore, when the connection direction between the battery 12 and the first busbar portion 21 is changed, the direction of the current flowing from the battery 12 to the first busbar portion 21 is changed. Furthermore, when the direction of the current flowing from the battery 12 to the first busbar portion 21 is changed, the current distribution in the first busbar portion 21 changes. When the current distribution in the first busbar portion 21 changes, the current detection accuracy decreases. Therefore, when the connection direction between the battery 12 and the first busbar portion 21 is changed, the current distribution in the first busbar portion 21 changes, and the current detection accuracy decreases.

In contrast, in the current detection device 20 of this embodiment, as described above, the current flowing through the first rectification section 213 is rectified, and the current density of the first rectification section 213 increases. This improves the sensitivity to the battery current Ib. Therefore, the signal-to-noise ratio for the battery current Ib improves, and the deterioration of the current detection accuracy is suppressed. Therefore, even if the connection direction between the battery 12 and the first busbar section 21 is changed, the deterioration of the current detection accuracy is suppressed.

The current detection device 20 of the first embodiment also provides the following effects.

[1-1] The second busbar portion 22 has a second side surface 221, a second recess 222, and a second rectifying portion 223. The second side surface 221 intersects with the width direction DW. The second recess 222 is recessed in the width direction DW from the second side surface 221. The second rectifying portion 223 extends in the width direction DW while adjacent to the second recess 222, and a current flows from the battery 12 via the first busbar portion 21 and the first resistor portion 31. Furthermore, the second rectifying portion 223 includes a third end 2231 and a fourth end 2232.

As described above, the plane passing through the third end 2231 and perpendicular to the width direction DW is defined as the third surface S3. Furthermore, the plane passing through the fourth end 2232 and perpendicular to the width direction DW is defined as the fourth surface S4. The first voltage detection point P1 and the second voltage detection point P2 are disposed in the range from the third surface S3 to the fourth surface S4 in the width direction DW.

This allows for easy current detection and prevents a decrease in current detection accuracy, as described above.

[1-2] The current detection device 20 includes the third busbar portion 23, the second resistor portion 32, the fourth busbar portion 24, the third terminal portion 63, and the fourth terminal portion 64. The current detection device 20 also includes the second board 42, the third connection portion 53, the fourth connection portion 54, the third voltage detection point P3, and the fourth voltage detection point P4. The third terminal portion 63 and the fourth terminal portion 64 are arranged on the second board 42. The third connection portion 53 is connected to the second board 42, the second resistor portion 32 side of the third busbar portion 23, and the third terminal portion 63. The fourth connection portion 54 is connected to the second board 42, the second resistor portion 32 side of the fourth busbar portion 24, and the fourth terminal portion 64. The third voltage detection point P3 is a contact point between the third terminal portion 63 and the third connection portion 53. The fourth voltage detection point P4 is the contact point between the fourth terminal portion 64 and the fourth connection portion 54. The third voltage detection point P3 corresponds to the third detection point. The fourth voltage detection point P4 corresponds to the fourth detection point.

The third busbar portion 23 also has a third side surface 231, a third recess 232, and a third rectifying portion 233. The third side surface 231 intersects with the width direction DW. The third recess 232 is recessed in the width direction DW from the third side surface 231. The third rectifying portion 233 extends in the width direction DW while adjacent to the third recess 232, and a current flows from the battery 12 via the first busbar portion 21, the first resistor portion 31, the second busbar portion 22, and the intermediate portion 25. The third rectifying portion 233 further includes a fifth end 2331 and a sixth end 2332.

As described above, the plane that passes through the fifth end 2331 and is perpendicular to the width direction DW is the fifth surface S5. The plane that passes through the sixth end 2332 and is perpendicular to the width direction DW is the sixth surface S6. The third voltage detection point P3 and the fourth voltage detection point P4 are disposed in the range from the fifth surface S5 to the sixth surface S6 in the width direction DW.

This allows for easy current detection and prevents a decrease in current detection accuracy, as described above.

[1-3] The fourth busbar portion 24 has a fourth side surface 241, a fourth recess 242, and a fourth rectifying portion 243. The fourth side surface 241 intersects with the width direction DW. The fourth recess 242 is recessed in the width direction DW from the fourth side surface 241. The fourth rectifying portion 243 extends in the width direction DW while being adjacent to the fourth recess 242, and a current flows from the battery 12 via the first busbar portion 21, the first resistor portion 31, the second busbar portion 22, the intermediate portion 25, the third busbar portion 23, and the second resistor portion 32. Furthermore, the fourth rectifying portion 243 includes a seventh end 2431 and an eighth end 2432.

As described above, the plane that passes through the seventh end 2431 and is perpendicular to the width direction DW is defined as the seventh surface S7. The plane that passes through the eighth end 2432 and is perpendicular to the width direction DW is defined as the eighth surface S8. The third voltage detection point P3 and the fourth voltage detection point P4 are disposed in the range from the seventh surface S7 to the eighth surface S8 in the width direction DW.

As a result, similar to the above, current detection can be easily performed and a decrease in current detection accuracy is suppressed. In addition, even if the connection direction between the fourth busbar portion 24 and the inverter 14 is changed, a decrease in current detection accuracy is suppressed.

[1-4] The first recess 212 is not in contact with the first resistor portion 31 and is separated from the first resistor portion 31. This makes it difficult for the first resistor portion 31 to be damaged when the first recess 212 is formed. Furthermore, the second recess 222 is not in contact with the first resistor portion 31 and is separated from the first resistor portion 31. This makes it difficult for the first resistor portion 31 to be damaged when the second recess 222 is formed. Furthermore, the third recess 232 is not in contact with the second resistor portion 32 and is separated from the second resistor portion 32. This makes it difficult for the second resistor portion 32 to be damaged when the third recess 232 is formed. Furthermore, the fourth recess 242 is not in contact with the second resistor portion 32 and is separated from the second resistor portion 32. This makes it difficult for the second resistor portion 32 to be damaged when the fourth recess 242 is formed.

[1-5] Here, in the resistance device described in JP 2005-17293 A, if a failure occurs due to a change over time in the first shunt resistor serving as a resistance unit, the battery current is not measured correctly. Also, if a failure occurs due to a change over time in the second shunt resistor serving as a resistance unit, the generator current is not measured correctly. Furthermore, it is not possible to determine that one of the two resistance units is abnormal.

In contrast, the current detection device 20 of this embodiment includes a first busbar portion 21, a first resistor portion 31, a second busbar portion 22, an intermediate portion 25, a third busbar portion 23, a second resistor portion 32, and a fourth busbar portion 24. The current detection device 20 also includes a first terminal portion 61, a second terminal portion 62, a third terminal portion 63, a fourth terminal portion 64, and a calculation unit 120. The calculation unit 120 also calculates the battery current Ib based on the first voltage V1, the second voltage V2, the third voltage V3, and the fourth voltage V4, and the first resistor R1 and the second resistor R2, and determines whether or not one of the first resistor portion 31 and the second resistor portion 32 is abnormal. The battery current Ib is a current that flows from the battery 12 through the first busbar portion 21, the first resistor portion 31, the second busbar portion 22, the intermediate portion 25, the third busbar portion 23, and the second resistor portion 32 to the fourth busbar portion 24, and corresponds to the device current. The battery 12 corresponds to an external device.

As a result, it is determined that one of the first resistor section 31 and the second resistor section 32 is abnormal, making it possible to determine that one of the two resistor sections is abnormal. This improves the redundancy of the current detection device 20.

Even if the first resistor section 31 fails, the second resistor section 32 is used. For example, the third voltage V3, the fourth voltage V4, and the second resistor R2 are used, so that the battery current Ib can be detected. Even if the second resistor section 32 fails, the first resistor section 31 is used. For example, the first voltage V1, the second voltage V2, and the first resistor R1 are used, so that the battery current Ib can be detected. Therefore, the redundancy of the current detection device 20 is improved.

[1-6] The calculation unit 120 calculates the battery current Ib based on a value related to the difference between the first voltage V1 and the fourth voltage V4, for example, V1-V4, and a value related to the sum of the first resistance R1 and the second resistance R2, for example, R1_C+R2_C.

As a result, the resistance value used to calculate the battery current Ib is greater than that of the first resistor R1. Also, the resistance value used to calculate the battery current Ib is greater than that of the second resistor R2. Therefore, when current is flowing from the battery 12, the voltage difference is divided by a value that is greater than when only the first resistor R1 or only the second resistor R2 is used. Therefore, the range of voltage differences that can display the current is increased, and the resolution of the battery current Ib is increased.

In addition, when the battery current Ib is not flowing, the voltage difference is divided by a larger value compared to when only the first resistor R1 and when only the second resistor R2 are used. Therefore, when the battery current Ib is not flowing, the zero point error of the battery current Ib, i.e., the offset error, is smaller compared to when only the first resistor R1 and when only the second resistor R2 are used.

[1-7] The calculation unit 120 calculates the battery current Ib based on a value related to the difference between the first voltage V1 and the second voltage V2, for example, V1-V2, and a value related to the first resistance R1, for example, the corrected first resistance R1_C.

As a result, the battery current Ib is calculated with less influence of the voltage drop due to the second busbar portion 22, the intermediate portion 25, and the third busbar portion 23 compared to when the battery current Ib is calculated using a value related to the difference between the first voltage V1 and the third voltage V3. This makes it easier to calculate the battery current Ib.

[1-8] The calculation unit 120 calculates the battery current Ib based on a value related to the difference between the third voltage V3 and the fourth voltage V4, for example, V3-V4, and a value related to the second resistance R2, for example, the corrected second resistance R2_C.

As a result, the battery current Ib is calculated with less influence of the voltage drop due to the second busbar portion 22, the intermediate portion 25, and the third busbar portion 23 compared to when the battery current Ib is calculated using a value related to the difference between the second voltage V2 and the fourth voltage V4. This makes it easier to calculate the battery current Ib.

[1-9] The current detection device 20 includes a first substrate 41 and a second substrate 42. A first terminal portion 61 and a second terminal portion 62 are arranged on the first substrate 41. A third terminal portion 63 and a fourth terminal portion 64 are arranged on the second substrate 42.

As a result, even if the first substrate 41 is damaged, the third terminal 63 and the fourth terminal 64 arranged on the second substrate 42 different from the first substrate 41 are less likely to be damaged. Even if the first terminal 61 and the second terminal 62 are damaged due to damage to the first substrate 41, the battery current Ib can be detected by using the third terminal 63 and the fourth terminal 64. Even if the second substrate 42 is damaged, the first terminal 61 and the second terminal 62 arranged on the first substrate 41 different from the second substrate 42 are less likely to be damaged. Even if the third terminal 63 and the fourth terminal 64 are damaged due to damage to the second substrate 42, the battery current Ib can be detected by using the first terminal 61 and the second terminal 62. Thus, the redundancy of the current detection device 20 is improved.

[1-10] The current detection device 20 includes a first pin 81, a second pin 82, a third pin 83, a fourth pin 84, a first connector housing 111, and a second connector housing 112. The first connector housing 111 houses the first pin 81 and the second pin 82. The second connector housing 112 houses the third pin 83 and the fourth pin 84.

As a result, even if the first connector housing 111 is damaged, the third pin 83 and the fourth pin 84 housed in the second connector housing 112 different from the first connector housing 111 are less likely to be damaged. Also, even if the first pin 81 and the second pin 82 are damaged due to damage to the first connector housing 111, the battery current Ib can be detected by using the third pin 83 and the fourth pin 84. Furthermore, even if the second connector housing 112 is damaged, the first pin 81 and the second pin 82 housed in the first connector housing 111 different from the second connector housing 112 are less likely to be damaged. Also, even if the third pin 83 and the fourth pin 84 are damaged due to damage to the second connector housing 112, the battery current Ib can be detected by using the first pin 81 and the second pin 82. Therefore, the redundancy of the current detection device 20 is improved.

[1-11] Here, the first resistor 31 and the second resistor 32 generate heat due to the battery current Ib. If the heat from the first resistor 31 and the second resistor 32 is transferred to the first connector housing 111, there is a risk that the first connector housing 111 may be damaged.

Therefore, when the first connector housing 111 is projected in the thickness direction DT, the projected first connector housing 111 does not overlap with the first resistor portion 31 and the second resistor portion 32 but is separated from them.

As a result, the first connector housing 111 is spaced apart from the first resistor portion 31 and the second resistor portion 32 compared to when the first connector housing 111 projected in the thickness direction DT overlaps with the first resistor portion 31 and the second resistor portion 32. This makes it difficult for heat from the first resistor portion 31 and the second resistor portion 32 to be transferred to the first connector housing 111. Therefore, damage to the first connector housing 111 is suppressed.

[1-12] In addition, heat from the first resistor 31 and the second resistor 32 may be transferred to the second connector housing 112, which may damage the second connector housing 112.

Therefore, when the second connector housing 112 is projected in the thickness direction DT, the projected second connector housing 112 is separated from the first resistor portion 31 and the second resistor portion 32 without overlapping them.

As a result, the second connector housing 112 is spaced apart from the first resistor portion 31 and the second resistor portion 32 compared to when the second connector housing 112 projected in the thickness direction DT overlaps with the first resistor portion 31 and the second resistor portion 32. This makes it difficult for heat from the first resistor portion 31 and the second resistor portion 32 to be transferred to the second connector housing 112. Therefore, damage to the second connector housing 112 is suppressed.

[1-13] The current detection device 20 includes a first thermistor 91 and a second thermistor 92. The calculation unit 120 corrects the first resistance R1 based on the first temperature T1. The first thermistor 91 corresponds to the first temperature detection unit. The second thermistor 92 corresponds to the second temperature detection unit.

As a result, even if the first thermistor 91 fails, the calculation unit 120 can correct the first resistance R1 using the first temperature T1 detected by the second thermistor 92. Also, even if the second thermistor 92 fails, the calculation unit 120 can correct the first resistance R1 using the first temperature T1 detected by the first thermistor 91. Thus, the redundancy of the current detection device 20 is improved.

[1-14] The current detection device 20 includes a third thermistor 93 and a fourth thermistor 94. The calculation unit 120 corrects the second resistance R2 based on the second temperature T2. The third thermistor 93 corresponds to the first temperature detection unit. The fourth thermistor 94 corresponds to the second temperature detection unit.

As a result, even if the third thermistor 93 fails, the calculation unit 120 can correct the second resistance R2 using the second temperature T2 detected by the fourth thermistor 94. Also, even if the fourth thermistor 94 fails, the calculation unit 120 can correct the second resistance R2 using the second temperature T2 detected by the third thermistor 93. Therefore, the redundancy of the current detection device 20 is improved.

Second Embodiment
In the second embodiment, the current detection device 20 includes a substrate 40 and a connector housing 110 instead of the first substrate 41, the second substrate 42, the first connector housing 111, and the second connector housing 112, as shown in Figs. 10 to 12. The arrangement of the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54 is different from that of the first embodiment. The arrangement of the first terminal portion 61, the second terminal portion 62, the third terminal portion 63, and the fourth terminal portion 64 is different from that of the first embodiment. The arrangement of the first wiring 71, the second wiring 72, the third wiring 73, and the fourth wiring 74 is different from that of the first embodiment. The arrangement of the first thermistor 91, the second thermistor 92, the third thermistor 93, and the fourth thermistor 94 is different from that of the first embodiment. Other than these, the second embodiment is the same as the first embodiment.

The substrate 40 is a printed circuit board. The substrate 40 has a substrate surface 401, a substrate back surface 402, a first through hole 413, a second through hole 414, a third through hole 423, and a fourth through hole 424.

The substrate surface 401 is a surface of the substrate 40 that is perpendicular to the thickness direction DT and corresponds to a surface of the substrate 40 that intersects with the thickness direction DT. Furthermore, the substrate surface 401 is located on the opposite side of the substrate 40 to the first resistor portion 31 and the second resistor portion 32.

The substrate back surface 402 is a surface of the substrate 40 that is perpendicular to the thickness direction DT, and corresponds to a surface of the substrate 40 that intersects with the thickness direction DT. The substrate back surface 402 is located on the first resistor portion 31 and the second resistor portion 32 side of the substrate 40, that is, on the side of the substrate 40 opposite the substrate front surface 401.

The first through hole 413, the second through hole 414, the third through hole 423 and the fourth through hole 424 are holes that penetrate the front surface 401 and the back surface 402 of the substrate, respectively.

As shown in Figs. 11 and 12, the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54 are arranged on the back surface 402 of the substrate. Furthermore, the first terminal portion 61, the second terminal portion 62, the third terminal portion 63, and the fourth terminal portion 64 are arranged in the first through hole 413, the second through hole 414, the third through hole 423, and the fourth through hole 424 of the substrate 40, respectively. As shown in Fig. 10, the first wiring 71, the second wiring 72, the third wiring 73, and the fourth wiring 74 are arranged on the substrate surface 401. Furthermore, the first thermistor 91, the second thermistor 92, the third thermistor 93, and the fourth thermistor 94 are arranged on the substrate surface 401.

The connector housing 110 is formed in a cylindrical shape from, for example, resin. The connector housing 110 is disposed on the substrate 40. The connector housing 110 accommodates the first pin 81, the second pin 82, the third pin 83, the fourth pin 84, two first thermistor pins 101, two second thermistor pins 102, two third thermistor pins 103, and two fourth thermistor pins 104. When the connector housing 110 is projected in the thickness direction DT, the projected connector housing 110 does not overlap the first resistor portion 31, the second resistor portion 32, the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54, but is separated from them. The connector housing 110 projected in the thickness direction DT overlaps the second busbar portion 22, the intermediate portion 25, and the third busbar portion 23.

The current detection device 20 of the second embodiment is configured as described above. This second embodiment also provides the same effects as the first embodiment. The second embodiment also provides the effects described below.

[2-1] The current detection device 20 includes a substrate 40. A first terminal 61, a second terminal 62, a third terminal 63, and a fourth terminal 64 are arranged on the substrate 40.

This reduces the number of substrates 40 compared to when the first terminal portion 61, the second terminal portion 62, the third terminal portion 63, and the fourth terminal portion 64 are arranged on two or more substrates 40. This reduces the number of components of the current detection device 20, thereby reducing the cost of the current detection device 20.

[2-2] The current detection device 20 includes a first pin 81, a second pin 82, a third pin 83, a fourth pin 84, and a connector housing 110. The connector housing 110 houses the first pin 81, the second pin 82, the third pin 83, and the fourth pin 84.

This reduces the number of connector housings 110 compared to when the first pin 81, the second pin 82, the third pin 83, and the fourth pin 84 are housed in two or more connector housings 110. This reduces the number of parts in the current detection device 20, thereby reducing the cost of the current detection device 20.

[2-3] Here, heat from the first resistor 31 and the second resistor 32 is transferred to the connector housing 110, which may damage the connector housing 110.

Therefore, when the connector housing 110 is projected in the thickness direction DT, the projected connector housing 110 does not overlap with the first resistor portion 31 and the second resistor portion 32 but is separated from them.

As a result, the connector housing 110 is spaced apart from the first resistance portion 31 and the second resistance portion 32 compared to when the connector housing 110 projected in the thickness direction DT overlaps with the first resistance portion 31 and the second resistance portion 32. This makes it difficult for heat from the first resistance portion 31 and the second resistance portion 32 to be transferred to the connector housing 110. Therefore, damage to the connector housing 110 is suppressed.

Third Embodiment
13, the third embodiment differs from the first embodiment in the shapes of the first recess 212, the first flow rectifying portion 213, the second recess 222, the second flow rectifying portion 223, the third recess 232, the third flow rectifying portion 233, the fourth recess 242, and the fourth flow rectifying portion 243. The rest is the same as the first embodiment.

Instead of being recessed in the width direction DW from the first side surface 211 on both sides, the first recess 212 is recessed in the width direction DW from the first side surface 211 on one side. As a result, the second end 2132 of the first straightening portion 213 is located on the first side surface 211 opposite the first recess 212.

Instead of being recessed in the width direction DW from the second side surface 221 on both sides, the second recess 222 is recessed in the width direction DW from the second side surface 221 on one side. Therefore, the fourth end 2232 of the second straightening portion 223 is located on the second side surface 221 opposite the second recess 222.

Instead of being recessed in the width direction DW from the third side surface 231 on both sides, the third recess 232 is recessed in the width direction DW from the third side surface 231 on one side. As a result, the sixth end 2332 of the third straightening portion 233 is located on the third side surface 231 opposite the third recess 232.

The fourth recess 242 is recessed in the width direction DW from the fourth side surface 241 on one side, instead of being recessed in the width direction DW from the fourth side surface 241 on both sides. Therefore, the eighth end 2432 of the fourth straightening portion 243 is located on the fourth side surface 241 opposite the fourth recess 242.

The current detection device 20 of the third embodiment is configured as described above. This third embodiment also achieves the same effects as the first embodiment.

Fourth Embodiment
14, the fourth embodiment differs from the first embodiment in the shapes of a first recess 212, a second recess 222, a third recess 232, and a fourth recess 242. The rest is the same as the first embodiment.

The first recess 212 does not penetrate in the thickness direction DT, but includes a first recess surface 2120. The first recess surface 2120 is perpendicular to the thickness direction DT and faces the thickness direction DT.

The second recess 222 does not penetrate in the thickness direction DT, but includes a second recess surface 2220. The second recess surface 2220 is perpendicular to the thickness direction DT and faces the thickness direction DT.

The third recess 232 does not penetrate in the thickness direction DT, but includes a third recess surface 2320. The third recess surface 2320 is perpendicular to the thickness direction DT and faces the thickness direction DT.

The fourth recess 242 does not penetrate in the thickness direction DT, but instead includes a fourth recess surface 2420. The fourth recess surface 2420 is perpendicular to the thickness direction DT and faces the thickness direction DT.

The current detection device 20 of the fourth embodiment is configured as described above. This fourth embodiment also provides the same effects as the first embodiment.

Fifth Embodiment
In the fifth embodiment, as shown in FIG. 15 , the first busbar portion 21 further has a first plate surface 215. Moreover, the first busbar portion 21 has a first hole 216 instead of the first recess 212. The second busbar portion 22 further has a second plate surface 225. Moreover, the second busbar portion 22 has a second hole 226 instead of the second recess 222. The third busbar portion 23 further has a third plate surface 235. Moreover, the third busbar portion 23 has a third hole 236 instead of the third recess 232. The fourth busbar portion 24 further has a fourth plate surface 245. Moreover, the fourth busbar portion 24 has a fourth hole 246 instead of the fourth recess 242. Moreover, the shapes of the first rectifying portion 213, the second rectifying portion 223, the third rectifying portion 233, and the fourth rectifying portion 243 are different from those of the first embodiment. Other than these, it is the same as the first embodiment.

The first plate surface 215 is a surface of the first busbar portion 21 that is perpendicular to the thickness direction DT and corresponds to a surface of the first busbar portion 21 that intersects with the thickness direction DT.

Two first holes 216 are formed and are aligned in the width direction DW. The first holes 216 extend from the inside of the first plate surface 215. The first holes 216 penetrate the first plate surface 215 on both sides. The first holes 216 are not in contact with the first resistance portion 31 and are separated from the first resistance portion 31. Note that, although the number of first holes 216 is two here, this is not limited to this. The number of first holes 216 may be at least one. The shape of the first holes 216 is a quadrangular prism, but this is not limited to this. The shape of the first holes 216 may be a polygonal prism, a cylinder, or the like.

The first rectifying portion 213 is adjacent to the center side of the first busbar portion 21 in the width direction DW of the first hole 216. The first rectifying portion 213 extends in the width direction DW. The first end 2131 is the boundary between the first rectifying portion 213 and the first hole 216. The second end 2132 is the end of the first rectifying portion 213 opposite the first end 2131, and is the boundary between the first rectifying portion 213 and the other first hole 216.

The second plate surface 225 is a surface of the second busbar portion 22 that is perpendicular to the thickness direction DT and corresponds to a surface of the second busbar portion 22 that intersects with the thickness direction DT.

Two second holes 226 are formed and are aligned in the width direction DW. The second holes 226 extend from the inside of the second plate surface 225. The second holes 226 penetrate the second plate surfaces 225 on both sides. The second holes 226 are not in contact with the first resistance portion 31 and are separated from the first resistance portion 31. Here, the number of second holes 226 is two, but is not limited to this. The number of second holes 226 may be at least one. The shape of the second holes 226 is a quadrangular prism, but is not limited to this. The shape of the second holes 226 may be a polygonal prism, a cylinder, or the like.

The second rectifying portion 223 is adjacent to the center side of the second busbar portion 22 in the width direction DW of the second hole 226. The second rectifying portion 223 extends in the width direction DW. The third end 2231 is the boundary between the second rectifying portion 223 and the second hole 226. The fourth end 2232 is the end of the second rectifying portion 223 opposite the third end 2231, and is the boundary between the second rectifying portion 223 and the other second hole 226.

The third plate surface 235 is a surface of the third busbar portion 23 that is perpendicular to the thickness direction DT and corresponds to a surface of the third busbar portion 23 that intersects with the thickness direction DT.

Two third holes 236 are formed and are aligned in the width direction DW. The third holes 236 extend from the inside of the third plate surface 235. The third holes 236 penetrate the third plate surface 235 on both sides. The third holes 236 are not in contact with the second resistance portion 32 and are separated from the second resistance portion 32. Note that, although the number of third holes 236 is two here, this is not limited to this. The number of third holes 236 may be at least one. The shape of the third holes 236 is a quadrangular prism, but this is not limited to this. The shape of the third holes 236 may be a polygonal prism, a cylinder, or the like.

The third rectifying portion 233 is adjacent to the center side of the third busbar portion 23 in the width direction DW of the third hole 236. The third rectifying portion 233 also extends in the width direction DW. The fifth end 2331 is the boundary between the third rectifying portion 233 and the third hole 236. The sixth end 2332 is the end of the third rectifying portion 233 opposite the fifth end 2331, and here is the boundary between the third rectifying portion 233 and the other third hole 236.

The fourth plate surface 245 is a surface of the fourth busbar portion 24 that is perpendicular to the thickness direction DT and corresponds to a surface of the fourth busbar portion 24 that intersects with the thickness direction DT.

Two fourth holes 246 are formed and are aligned in the width direction DW. The fourth holes 246 extend from the inside of the fourth plate surface 245. The fourth holes 246 penetrate the fourth plate surfaces 245 on both sides. The fourth holes 246 are not in contact with the second resistance portion 32 and are separated from the second resistance portion 32. Here, the number of the fourth holes 246 is two, but is not limited to this. The number of the fourth holes 246 needs to be at least one. The shape of the fourth holes 246 is a quadrangular prism, but is not limited to this. The shape of the fourth holes 246 may be a polygonal prism, a cylinder, or the like.

The fourth rectification portion 243 is adjacent to the center side of the fourth busbar portion 24 in the width direction DW of the fourth hole 246. The fourth rectification portion 243 also extends in the width direction DW. The seventh end 2431 is the boundary between the fourth rectification portion 243 and the fourth hole 246. The eighth end 2432 is the end of the fourth rectification portion 243 opposite the seventh end 2431, and here is the boundary between the fourth rectification portion 243 and the other fourth hole 246.

The current detection device 20 of the fifth embodiment is configured as described above. The fifth embodiment also provides the same effects as the first embodiment.

Sixth Embodiment
As shown in FIG. 16, the sixth embodiment differs from the fifth embodiment in the shapes of a first hole 216, a second hole 226, a third hole 236 and a fourth hole 246.

Instead of penetrating in the thickness direction DT, the first hole 216 does not penetrate in the thickness direction DT and is formed as a bottomed hole. As a result, the first hole 216 includes a first bottom surface 2160. The first bottom surface 2160 is perpendicular to the thickness direction DT and faces the thickness direction DT.

Instead of penetrating in the thickness direction DT, the second hole 226 is formed as a bottomed hole that does not penetrate in the thickness direction DT. As a result, the second hole 226 includes a second bottom surface 2260. The second bottom surface 2260 is perpendicular to the thickness direction DT and faces the thickness direction DT.

Instead of penetrating in the thickness direction DT, the third hole 236 is formed as a bottomed hole that does not penetrate in the thickness direction DT. As a result, the third hole 236 includes a third bottom surface 2360. The third bottom surface 2360 is perpendicular to the thickness direction DT and faces the thickness direction DT.

The fourth hole 246 does not penetrate in the thickness direction DT, but is formed as a bottomed hole. As a result, the fourth hole 246 includes a fourth bottom surface 2460. The fourth bottom surface 2460 is perpendicular to the thickness direction DT and faces the thickness direction DT.

The current detection device 20 of the sixth embodiment is configured as described above. The sixth embodiment also provides the same effects as the fifth embodiment.

Seventh Embodiment
17 and 18, the current detection device 20 does not include the first connection portion 51, the second connection portion 52, the third connection portion 53, and the fourth connection portion 54. Also, the configurations of the first terminal portion 61, the second terminal portion 62, the third terminal portion 63, the fourth terminal portion 64, the first voltage detection point P1, the second voltage detection point P2, the third voltage detection point P3, and the fourth voltage detection point P4 are different from those of the first embodiment. Other than these, the seventh embodiment is similar to the first embodiment.

The first terminal 61 is directly connected to the first resistor 31 side of the first busbar portion 21, instead of being connected to the first resistor 31 side of the first busbar portion 21 via the first connection portion 51. Therefore, the first terminal 61 is connected to the first resistor 31 side of the first busbar portion 21 through the first busbar portion 21, not through the first connection portion 51. Therefore, the first terminal 61 outputs a signal according to the first voltage V1. In this case, the first voltage detection point P1 is the contact point between the first terminal 61 and the first busbar portion 21.

The second terminal 62 is directly connected to the first resistor 31 side of the second busbar portion 22, instead of being connected to the first resistor 31 side of the second busbar portion 22 via the second connection portion 52. Therefore, the second terminal 62 is connected to the second busbar portion 22 side of the first resistor portion 31 via the second busbar portion 22, not via the second connection portion 52. Therefore, the second terminal 62 outputs a signal corresponding to the second voltage V2. Furthermore, in this case, the second voltage detection point P2 is the contact point between the second terminal 62 and the second busbar portion 22.

The third terminal portion 63 is directly connected to the second resistor portion 32 side of the third busbar portion 23, instead of being connected to the second resistor portion 32 side of the third busbar portion 23 via the third connection portion 53. Therefore, the third terminal portion 63 is connected to the third busbar portion 23 side of the second resistor portion 32 via the third busbar portion 23, not via the third connection portion 53. Therefore, the third terminal portion 63 outputs a signal corresponding to the third voltage V3. In this case, the third voltage detection point P3 is the contact point between the third terminal portion 63 and the third busbar portion 23.

The fourth terminal 64 is directly connected to the second resistor 32 side of the fourth busbar portion 24, instead of being connected to the second resistor 32 side of the fourth busbar portion 24 via the fourth connection portion 54. Therefore, the fourth terminal 64 is connected to the fourth busbar portion 24 side of the second resistor portion 32 via the fourth busbar portion 24, not via the fourth connection portion 54. Therefore, the fourth terminal 64 outputs a signal according to the fourth voltage V4. Furthermore, in this case, the fourth voltage detection point P4 is the contact point between the fourth terminal 64 and the fourth busbar portion 24.

The current detection device 20 of the seventh embodiment is configured as described above. The seventh embodiment also provides the same effects as the first embodiment.

Eighth embodiment
19 and 20 , the eighth embodiment differs from the seventh embodiment in the shapes of the first bus bar portion 21, the second bus bar portion 22, the third bus bar portion 23, and the fourth bus bar portion 24. Also, the shapes of the first terminal portion 61, the second terminal portion 62, the third terminal portion 63, and the fourth terminal portion 64 differ from the seventh embodiment. Other than these, the eighth embodiment is similar to the seventh embodiment.

The first busbar portion 21 further has a first busbar portion hole 217. The first busbar portion hole 217 is formed in a portion of the first busbar portion 21 on the first resistor portion 31 side and penetrates in the thickness direction DT. The first busbar portion hole 217 also communicates with the first through hole 413.

The first terminal portion 61 is formed in a screw shape. A part of the first terminal portion 61 is inserted into the first through hole 413 and the first busbar portion hole 217, thereby connecting the first terminal portion 61 and the first busbar portion 21.

The second busbar portion 22 further has a second busbar portion hole 227. The second busbar portion hole 227 is formed in a portion of the second busbar portion 22 on the first resistor portion 31 side and penetrates in the thickness direction DT. The second busbar portion hole 227 also communicates with the second through hole 414.

The second terminal portion 62 is formed in a screw shape. In addition, a part of the second terminal portion 62 is inserted into the second through hole 414 and the second bus bar portion hole 227, thereby connecting the second terminal portion 62 and the second bus bar portion 22.

The third busbar portion 23 further has a third busbar portion hole 237. The third busbar portion hole 237 is formed in a portion of the third busbar portion 23 on the second resistor portion 32 side and penetrates in the thickness direction DT. The third busbar portion hole 237 also communicates with the third through hole 423.

The third terminal portion 63 is formed in a screw shape. In addition, a part of the third terminal portion 63 is inserted into the third through hole 423 and the third busbar portion hole 237, thereby connecting the third terminal portion 63 and the third busbar portion 23.

The fourth busbar portion 24 further has a fourth busbar portion hole 247. The fourth busbar portion hole 247 is formed in a portion of the fourth busbar portion 24 on the second resistor portion 32 side and penetrates in the thickness direction DT. The fourth busbar portion hole 247 also communicates with the fourth through hole 424.

The fourth terminal portion 64 is formed in a screw shape. In addition, a part of the fourth terminal portion 64 is inserted into the fourth through hole 424 and the fourth bus bar portion hole 247, thereby connecting the fourth terminal portion 64 and the fourth bus bar portion 24.

The current detection device 20 of the eighth embodiment is configured as described above. This eighth embodiment also provides the same effects as the seventh embodiment.

Ninth embodiment
In the ninth embodiment, as shown in FIG. 21 , the current detection device 20 does not include the intermediate portion 25, the third busbar portion 23, the fourth busbar portion 24, and the second substrate 42. The current detection device 20 does not include the third connection portion 53, the fourth connection portion 54, the third terminal portion 63, the fourth terminal portion 64, the third voltage detection point P3, the fourth voltage detection point P4, the third wiring 73, and the fourth wiring 74. The current detection device 20 does not include the third pin 83, the fourth pin 84, the third thermistor 93, the fourth thermistor 94, the third thermistor pin 103, the fourth thermistor pin 104, and the second connector housing 112. The second busbar portion 22 has a second connection hole 240 in addition to the second side surface 221, the second recess 222, and the second rectification portion 223. Furthermore, bolts (not shown) are inserted into the second connection hole 240 of the second bus bar portion 22 and the hole provided in the inverter 14. This connects the second bus bar portion 22 to the inverter 14. Therefore, the battery 12, the first bus bar portion 21, the first resistor portion 31, the second bus bar portion 22, and the inverter 14 are connected in series. Other than this, the present embodiment is similar to the first embodiment. Even with this configuration, current can be easily detected and a decrease in current detection accuracy is suppressed, similar to the first embodiment.

Other Embodiments
The present disclosure is not limited to the above-described embodiments, and appropriate modifications can be made to the above-described embodiments. Furthermore, in each of the above-described embodiments, it goes without saying that the elements constituting the embodiments are not necessarily essential, except in cases where they are particularly clearly stated as essential or where they are clearly considered essential in principle.

The calculation unit and the method described in the present disclosure may be realized by a dedicated computer provided by configuring a processor and a memory programmed to execute one or more functions embodied in a computer program. Alternatively, the calculation unit and the method described in the present disclosure may be realized by a dedicated computer provided by configuring a processor with one or more dedicated hardware logic circuits. Alternatively, the calculation unit and the method described in the present disclosure may be realized by one or more dedicated computers configured by combining a processor and a memory programmed to execute one or more functions with a processor configured with one or more hardware logic circuits. In addition, the computer program may be stored in a computer-readable non-transient tangible recording medium as instructions executed by the computer.

In each of the above embodiments, the current detected and calculated by the current detection device 20 is the current flowing from the battery 12 to the inverter 14. In contrast, the current detected and calculated by the current detection device 20 is not limited to the current flowing from the battery 12 to the inverter 14. The current detected and calculated by the current detection device 20 may be, for example, the current flowing from the inverter 14 to the motor generator 16.

The above embodiments may be combined as appropriate.

DISCLOSURE OF THE PRESENT ART
[Claim 1]
A current detection device,
A first bus bar portion (21) formed in a plate shape;
a resistive portion (31) connected to the first bus bar portion and having an electrical resistance greater than the electrical resistance of the first bus bar portion;
a second busbar portion (22) connected to the resistor portion on the opposite side to the first busbar portion and having an electrical resistance smaller than the electrical resistance of the resistor portion;
a first terminal portion (61) that outputs a signal corresponding to a first voltage (V1) that is a voltage applied to the first busbar portion side of the resistor portion;
a second terminal portion (62) that outputs a signal corresponding to a second voltage (V2) that is a voltage applied to the second busbar portion side of the resistor portion;
a substrate (40, 41) on which the first terminal portion and the second terminal portion are arranged;
a first connection portion (51) connected to the substrate, the resistor portion side of the first busbar portion, and the first terminal portion;
a second connection portion (52) connected to the substrate, the resistor portion side of the second busbar portion, and the second terminal portion;
a first detection point (P1) which is a contact point between the first terminal portion and the first connection portion;
a second detection point (P2) which is a contact point between the second terminal portion and the second connection portion;
a calculation unit (120) that calculates a device current (Ib) that is a current flowing from an external device (12) to the second bus bar portion via the first bus bar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion;
Equipped with
The first bus bar portion is
A side surface (211) intersecting with a width direction (DW) of the first bus bar portion;
A recess (212) recessed in the width direction from the side surface;
a rectifying section (213) extending in the width direction while adjacent to the recess in the width direction and through which a current from the external device flows;
having
The rectifying unit is
A first end (2131) which is a boundary with the recess;
A second end (2132) that is the end opposite to the first end;
Including,
A surface that passes through the first end and is perpendicular to the width direction is defined as a first surface (S1), and a surface that passes through the second end and is perpendicular to the width direction is defined as a second surface (S2).
A current detection device in which the first detection point and the second detection point are arranged in the width direction in a range from the first surface to the second surface.
[Claim 2]
The current detection device according to claim 1 , wherein the recess is not in contact with the resistor portion and is separated from the resistor portion.
[Claim 3]
The current detection device according to claim 1 , wherein the recess penetrates the first busbar portion in a thickness direction (DT).
[Claim 4]
The current detection device according to claim 1 or 2, wherein the recess includes a recess surface (2120) facing in a thickness direction (DT) of the first busbar portion.
[Claim 5]
The side surface is a first side surface,
The recess is a first recess,
The rectification unit is a first rectification unit,
The second bus bar portion is
A second side surface (221) intersecting the width direction;
A second recess (222) recessed in the width direction from the second side surface;
a second rectification portion (223) extending in the width direction while being adjacent to the second recess in the width direction, and through which a current flows from the external device via the first bus bar portion and the resistor portion;
having
The second rectification unit is
A third end (2231) which is a boundary with the second recess;
A fourth end (2232) which is the end opposite to the third end;
Including,
A plane that passes through the third end and is perpendicular to the width direction is defined as a third plane (S3), and a plane that passes through the fourth end and is perpendicular to the width direction is defined as a fourth plane (S4).
5 . The current detection device according to claim 1 , wherein the first detection points and the second detection points are arranged in a range from the third surface to the fourth surface in the width direction.
[Claim 6]
The resistor portion is a first resistor portion,
an intermediate portion (25) connected to the second busbar portion and having an electrical resistance smaller than that of the first resistance portion;
a third bus bar portion (23) connected to a side of the intermediate portion opposite to the second bus bar portion and aligned with the second bus bar portion in the width direction;
a second resistor portion (32) connected to the third bus bar portion, spaced apart from the first resistor portion in the width direction, and having an electrical resistance greater than that of the third bus bar portion;
a fourth bus bar portion (24) connected to a side of the second resistance portion opposite to the third bus bar portion, spaced apart from the first bus bar portion in the width direction, and having an electrical resistance smaller than the electrical resistance of the second resistance portion;
a third terminal portion (63) that outputs a signal corresponding to a third voltage (V3) that is a voltage applied to the third busbar portion side of the second resistor portion;
a fourth terminal portion (64) that outputs a signal corresponding to a fourth voltage (V4) that is a voltage applied to the fourth bus bar portion side of the second resistor portion;
Equipped with
5. The current detection device according to claim 1, wherein the calculation unit calculates the device current based on the first voltage, the second voltage, the third voltage, and the fourth voltage, as well as the electrical resistance of the first resistor section and the electrical resistance of the second resistor section.
[Claim 7]
The first terminal portion, the second terminal portion, the third terminal portion, and the fourth terminal portion are arranged on the substrate (40),
The current detection device is
a third connection portion (53) connected to the substrate, the second resistor portion side of the third busbar portion, and the third terminal portion;
a fourth connection portion (54) connected to the substrate, the second resistor portion side of the fourth busbar portion, and the fourth terminal portion;
a third detection point (P3) which is a contact point between the third terminal portion and the third connection portion;
a fourth detection point (P4) which is a contact point between the fourth terminal portion and the fourth connection portion;
The current sensing device of claim 6 further comprising:
[Claim 8]
The substrate is a first substrate (41),
The current detection device is
a second substrate (42) on which the third terminal portion and the fourth terminal portion are arranged;
a third connection portion (53) connected to the second substrate, the second resistor portion side of the third busbar portion, and the third terminal portion;
a fourth connection portion (54) connected to the second substrate, the second resistor portion side of the fourth bus bar portion, and the fourth terminal portion;
a third detection point (P3) which is a contact point between the third terminal portion and the third connection portion;
a fourth detection point (P4) which is a contact point between the fourth terminal portion and the fourth connection portion;
The current sensing device of claim 6 further comprising:
[Claim 9]
The side surface is a first side surface,
The recess is a first recess,
The rectification unit is a first rectification unit,
The third bus bar portion is
A second side surface (231) intersecting the width direction;
A second recess (232) recessed in the width direction from the second side surface;
a second rectification portion (233) extending in the width direction while being adjacent to the second recess in the width direction, and through which a current flows from the external device via the first bus bar portion, the first resistor portion, the second bus bar portion, and the intermediate portion;
having
The second rectification unit is
A third end (2331) which is a boundary with the second recess;
A fourth end (2332) which is the end opposite to the third end;
Including,
A plane that passes through the third end and is perpendicular to the width direction is defined as a third plane (S5), and a plane that passes through the fourth end and is perpendicular to the width direction is defined as a fourth plane (S6).
The current detection device according to claim 7 , wherein the third detection point and the fourth detection point are arranged in a range from the third surface to the fourth surface in the width direction.
[Claim 10]
The side surface is a first side surface,
The recess is a first recess,
The rectification unit is a first rectification unit,
The fourth bus bar portion is
A second side surface (241) intersecting the width direction;
A second recess (242) recessed in the width direction from the second side surface;
a second rectification portion (243) extending in the width direction while being adjacent to the second recess in the width direction, and through which a current flows from the external device via the first bus bar portion, the first resistor portion, the second bus bar portion, the intermediate portion, the third bus bar portion, and the second resistor portion;
having
The second rectification unit is
A third end (2431) which is a boundary with the second recess;
a fourth end (2432) that is the end opposite to the third end;
Including,
A surface that passes through the third end and is perpendicular to the width direction is defined as a third surface (S7), and a surface that passes through the fourth end and is perpendicular to the width direction is defined as a fourth surface (S8).
The current detection device according to claim 7 , wherein the third detection point and the fourth detection point are arranged in a range from the third surface to the fourth surface in the width direction.
[Claim 11]
A current detection device,
A first bus bar portion (21) formed in a plate shape;
a resistive portion (31) connected to the first bus bar portion and having an electrical resistance greater than the electrical resistance of the first bus bar portion;
a second busbar portion (22) connected to the resistor portion on the opposite side to the first busbar portion and having an electrical resistance smaller than the electrical resistance of the resistor portion;
a first terminal portion (61) that outputs a signal corresponding to a first voltage (V1) that is a voltage applied to the first busbar portion side of the resistor portion;
a second terminal portion (62) that outputs a signal corresponding to a second voltage (V2) that is a voltage applied to the second busbar portion side of the resistor portion;
a substrate (40, 41) on which the first terminal portion and the second terminal portion are arranged;
a first connection portion (51) connected to the substrate, the resistor portion side of the first busbar portion, and the first terminal portion;
a second connection portion (52) connected to the substrate, the resistor portion side of the second busbar portion, and the second terminal portion;
a first detection point (P1) which is a contact point between the first terminal portion and the first connection portion;
a second detection point (P2) which is a contact point between the second terminal portion and the second connection portion;
a calculation unit (120) that calculates a device current (Ib) that is a current flowing from an external device (12) to the second bus bar portion via the first bus bar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion;
Equipped with
The first bus bar portion is
A plate surface (215) intersecting with a thickness direction (DT) of the first bus bar portion;
A hole (216) extending from the inside of the plate surface in the thickness direction;
a rectification portion (213) extending in the width direction (DW) while adjacent to the hole and the first busbar portion in the width direction (DW), and through which a current from the external device flows;
having
The rectifying unit is
A first end (2131) that is a boundary with the hole;
A second end (2132) that is the end opposite to the first end;
Including,
A plane that passes through the first end and is perpendicular to the width direction is defined as a first plane (S1), and a plane that passes through the second end and is perpendicular to the width direction is defined as a second plane (S2).
A current detection device in which the first detection point and the second detection point are arranged in the width direction in a range from the first surface to the second surface.
[Claim 12]
A current detection device,
A first bus bar portion (21) formed in a plate shape;
a resistive portion (31) connected to the first bus bar portion and having an electrical resistance greater than the electrical resistance of the first bus bar portion;
a second busbar portion (22) connected to the resistor portion on the opposite side to the first busbar portion and having an electrical resistance smaller than the electrical resistance of the resistor portion;
a first terminal portion (61) connected to the first bus bar portion and configured to output a signal corresponding to a first voltage (V1) applied to the first bus bar portion side of the resistor portion;
a second terminal portion (62) connected to the second bus bar portion and configured to output a signal corresponding to a second voltage (V2) applied to the second bus bar portion side of the resistor portion;
a first detection point (P1) which is a contact point between the first terminal portion and the first bus bar portion;
a second detection point (P2) which is a contact point between the second terminal portion and the second bus bar portion;
a calculation unit (120) that calculates a device current (Ib) that is a current flowing from an external device (12) to the second bus bar portion via the first bus bar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion;
Equipped with
The first bus bar portion is
A side surface (211) intersecting with a width direction (DW) of the first bus bar portion;
A recess (212) recessed from the side surface in the width direction;
a rectifying portion (213) extending in the width direction while adjacent to the recess in the width direction and through which a current from the external device flows;
having
The rectifying unit includes:
A first end (2131) which is a boundary with the recess;
a second end (2132) opposite the first end,
A plane that passes through the first end and is perpendicular to the width direction is defined as a first plane (S1), and a plane that passes through the second end and is perpendicular to the width direction is defined as a second plane (S2).
A current detection device in which the first detection point and the second detection point are arranged in the width direction in a range from the first surface to the second surface.

21 First busbar portion 22 Second busbar portion 23 Third busbar portion 24 Fourth busbar portion 31 First resistor portion 32 Second resistor portion 61 First terminal portion 62 Second terminal portion 63 Third terminal portion 64 Fourth terminal portion 120 Calculation portion

Claims (12)

A current detection device,
A first bus bar portion (21) formed in a plate shape;
a resistive portion (31) connected to the first bus bar portion and having an electrical resistance greater than the electrical resistance of the first bus bar portion;
a second busbar portion (22) connected to the resistor portion on the opposite side to the first busbar portion and having an electrical resistance smaller than the electrical resistance of the resistor portion;
a first terminal portion (61) that outputs a signal corresponding to a first voltage (V1) that is a voltage applied to the first busbar portion side of the resistor portion;
a second terminal portion (62) that outputs a signal corresponding to a second voltage (V2) that is a voltage applied to the second busbar portion side of the resistor portion;
a substrate (40, 41) on which the first terminal portion and the second terminal portion are arranged;
a first connection portion (51) connected to the substrate, the resistor portion side of the first busbar portion, and the first terminal portion;
a second connection portion (52) connected to the substrate, the resistor portion side of the second busbar portion, and the second terminal portion;
a first detection point (P1) which is a contact point between the first terminal portion and the first connection portion;
a second detection point (P2) which is a contact point between the second terminal portion and the second connection portion;
a calculation unit (120) that calculates a device current (Ib) that is a current flowing from an external device (12) to the second bus bar portion via the first bus bar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion;
Equipped with
The first bus bar portion is
A side surface (211) intersecting with a width direction (DW) of the first bus bar portion;
A recess (212) recessed in the width direction from the side surface;
a rectifying section (213) extending in the width direction while adjacent to the recess in the width direction and through which a current from the external device flows;
having
The rectifying unit is
A first end (2131) which is a boundary with the recess;
A second end (2132) that is the end opposite to the first end;
Including,
A plane that passes through the first end and is perpendicular to the width direction is defined as a first plane (S1), and a plane that passes through the second end and is perpendicular to the width direction is defined as a second plane (S2).
A current detection device in which the first detection point and the second detection point are arranged in the width direction in a range from the first surface to the second surface. The current detection device according to claim 1, wherein the recess is not in contact with the resistor portion and is separated from the resistor portion. The current detection device according to claim 1 or 2, wherein the recess penetrates the first busbar portion in a thickness direction (DT). The current detection device according to claim 1 or 2, wherein the recess includes a recess surface (2120) facing the thickness direction (DT) of the first busbar portion. The side surface is a first side surface,
The recess is a first recess,
The rectification unit is a first rectification unit,
The second bus bar portion is
A second side surface (221) intersecting the width direction;
A second recess (222) recessed in the width direction from the second side surface;
a second rectification portion (223) extending in the width direction while being adjacent to the second recess in the width direction, and through which a current flows from the external device via the first bus bar portion and the resistor portion;
having
The second rectification unit is
A third end (2231) which is a boundary with the second recess;
A fourth end (2232) which is the end opposite to the third end;
Including,
A plane that passes through the third end and is perpendicular to the width direction is defined as a third plane (S3), and a plane that passes through the fourth end and is perpendicular to the width direction is defined as a fourth plane (S4).
The current detection device according to claim 1 , wherein the first detection points and the second detection points are arranged in a range from the third surface to the fourth surface in the width direction. The resistor portion is a first resistor portion,
an intermediate portion (25) connected to the second busbar portion and having an electrical resistance smaller than that of the first resistance portion;
a third bus bar portion (23) connected to a side of the intermediate portion opposite to the second bus bar portion and aligned with the second bus bar portion in the width direction;
a second resistor portion (32) connected to the third bus bar portion, spaced apart from the first resistor portion in the width direction, and having an electrical resistance greater than that of the third bus bar portion;
a fourth bus bar portion (24) connected to a side of the second resistance portion opposite to the third bus bar portion, spaced apart from the first bus bar portion in the width direction, and having an electrical resistance smaller than the electrical resistance of the second resistance portion;
a third terminal portion (63) that outputs a signal corresponding to a third voltage (V3) that is a voltage applied to the third busbar portion side of the second resistor portion;
a fourth terminal portion (64) that outputs a signal corresponding to a fourth voltage (V4) that is a voltage applied to the fourth bus bar portion side of the second resistor portion;
Equipped with
The current detection device according to claim 1 , wherein the calculation unit calculates the device current based on the first voltage, the second voltage, the third voltage, and the fourth voltage, as well as the electrical resistance of the first resistor section and the electrical resistance of the second resistor section. The first terminal portion, the second terminal portion, the third terminal portion, and the fourth terminal portion are arranged on the substrate (40),
The current detection device is
a third connection portion (53) connected to the substrate, the second resistor portion side of the third busbar portion, and the third terminal portion;
a fourth connection portion (54) connected to the substrate, the second resistor portion side of the fourth busbar portion, and the fourth terminal portion;
a third detection point (P3) which is a contact point between the third terminal portion and the third connection portion;
a fourth detection point (P4) which is a contact point between the fourth terminal portion and the fourth connection portion;
The current sensing device of claim 6 further comprising: The substrate is a first substrate (41),
The current detection device is
a second substrate (42) on which the third terminal portion and the fourth terminal portion are arranged;
a third connection portion (53) connected to the second substrate, the second resistor portion side of the third busbar portion, and the third terminal portion;
a fourth connection portion (54) connected to the second substrate, the second resistor portion side of the fourth bus bar portion, and the fourth terminal portion;
a third detection point (P3) which is a contact point between the third terminal portion and the third connection portion;
a fourth detection point (P4) which is a contact point between the fourth terminal portion and the fourth connection portion;
The current sensing device of claim 6 further comprising: The side surface is a first side surface,
The recess is a first recess,
The rectification unit is a first rectification unit,
The third bus bar portion is
A second side surface (231) intersecting the width direction;
A second recess (232) recessed in the width direction from the second side surface;
a second rectification portion (233) extending in the width direction while being adjacent to the second recess in the width direction, and through which a current flows from the external device via the first bus bar portion, the first resistor portion, the second bus bar portion, and the intermediate portion;
having
The second rectification unit is
A third end (2331) which is a boundary with the second recess;
A fourth end (2332) which is the end opposite to the third end;
Including,
A plane that passes through the third end and is perpendicular to the width direction is defined as a third plane (S5), and a plane that passes through the fourth end and is perpendicular to the width direction is defined as a fourth plane (S6).
The current detection device according to claim 7 , wherein the third detection point and the fourth detection point are arranged in a range from the third surface to the fourth surface in the width direction. The side surface is a first side surface,
The recess is a first recess,
The rectification unit is a first rectification unit,
The fourth bus bar portion is
A second side surface (241) intersecting the width direction;
A second recess (242) recessed in the width direction from the second side surface;
a second rectification portion (243) extending in the width direction while being adjacent to the second recess in the width direction, and through which a current flows from the external device via the first bus bar portion, the first resistor portion, the second bus bar portion, the intermediate portion, the third bus bar portion, and the second resistor portion;
having
The second rectification unit is
A third end (2431) which is a boundary with the second recess;
a fourth end (2432) that is the end opposite to the third end;
Including,
A surface that passes through the third end and is perpendicular to the width direction is defined as a third surface (S7), and a surface that passes through the fourth end and is perpendicular to the width direction is defined as a fourth surface (S8).
The current detection device according to claim 7 , wherein the third detection point and the fourth detection point are arranged in a range from the third surface to the fourth surface in the width direction. A current detection device,
A first bus bar portion (21) formed in a plate shape;
a resistive portion (31) connected to the first bus bar portion and having an electrical resistance greater than the electrical resistance of the first bus bar portion;
a second busbar portion (22) connected to the resistor portion on the opposite side to the first busbar portion and having an electrical resistance smaller than the electrical resistance of the resistor portion;
a first terminal portion (61) that outputs a signal corresponding to a first voltage (V1) that is a voltage applied to the first busbar portion side of the resistor portion;
a second terminal portion (62) that outputs a signal corresponding to a second voltage (V2) that is a voltage applied to the second busbar portion side of the resistor portion;
a substrate (40, 41) on which the first terminal portion and the second terminal portion are arranged;
a first connection portion (51) connected to the substrate, the resistor portion side of the first busbar portion, and the first terminal portion;
a second connection portion (52) connected to the substrate, the resistor portion side of the second busbar portion, and the second terminal portion;
a first detection point (P1) which is a contact point between the first terminal portion and the first connection portion;
a second detection point (P2) which is a contact point between the second terminal portion and the second connection portion;
a calculation unit (120) that calculates a device current (Ib) that is a current flowing from an external device (12) to the second bus bar portion via the first bus bar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion;
Equipped with
The first bus bar portion is
A plate surface (215) intersecting with a thickness direction (DT) of the first bus bar portion;
A hole (216) extending from the inside of the plate surface in the thickness direction;
a rectification portion (213) extending in the width direction (DW) while adjacent to the hole and the first busbar portion in the width direction (DW), and through which a current from the external device flows;
having
The rectifying unit is
A first end (2131) that is a boundary with the hole;
A second end (2132) that is the end opposite to the first end;
Including,
A plane that passes through the first end and is perpendicular to the width direction is defined as a first plane (S1), and a plane that passes through the second end and is perpendicular to the width direction is defined as a second plane (S2).
A current detection device in which the first detection point and the second detection point are arranged in the width direction in a range from the first surface to the second surface. A current detection device,
A first bus bar portion (21) formed in a plate shape;
a resistive portion (31) connected to the first bus bar portion and having an electrical resistance greater than the electrical resistance of the first bus bar portion;
a second busbar portion (22) connected to the resistor portion on the opposite side to the first busbar portion and having an electrical resistance smaller than the electrical resistance of the resistor portion;
a first terminal portion (61) connected to the first bus bar portion and configured to output a signal corresponding to a first voltage (V1) applied to the first bus bar portion side of the resistor portion;
a second terminal portion (62) connected to the second bus bar portion and configured to output a signal corresponding to a second voltage (V2) applied to the second bus bar portion side of the resistor portion;
a first detection point (P1) which is a contact point between the first terminal portion and the first bus bar portion;
a second detection point (P2) which is a contact point between the second terminal portion and the second bus bar portion;
a calculation unit (120) that calculates a device current (Ib) that is a current flowing from an external device (12) to the second bus bar portion via the first bus bar portion and the resistance portion based on the first voltage, the second voltage, and the electrical resistance of the resistance portion;
Equipped with
The first bus bar portion is
A side surface (211) intersecting with a width direction (DW) of the first bus bar portion;
A recess (212) recessed in the width direction from the side surface;
a rectifying section (213) extending in the width direction while adjacent to the recess in the width direction and through which a current from the external device flows;
having
The rectifying unit is
A first end (2131) which is a boundary with the recess;
a second end (2132) opposite the first end,
A surface that passes through the first end and is perpendicular to the width direction is defined as a first surface (S1), and a surface that passes through the second end and is perpendicular to the width direction is defined as a second surface (S2).
A current detection device in which the first detection point and the second detection point are arranged in the width direction in a range from the first surface to the second surface.

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