JP2020022288A - Electric power conversion device - Google Patents

Abstract

To provide an electric power conversion device which inhibits deterioration of current detection accuracy of a current sensor.SOLUTION: An electric power conversion device has: a reactor 315; a case 330 which houses the reactor; and a current sensor which is disposed adjacent to the reactor. The case is formed with passages 333a, 333b for flowing a liquid refrigerant, and a part of the passage is located between the reactor and the current sensor.SELECTED DRAWING: Figure 4

Description

  The disclosure described in this specification relates to a power conversion device including a current sensor.

  BACKGROUND ART As disclosed in Patent Document 1, there is known a power converter in which a reactor and a current sensor are provided on a cooling surface of a cooler.

JP 2017-152612 A

  In the power converter disclosed in Patent Document 1, the reactor and the current sensor are arranged on a cooling surface. Therefore, heat radiation generated in the reactor by the heat generated by energization acts on the current sensor. As a result, the temperature of the current sensor increases. Due to the thermal expansion, there is a possibility that a displacement between the current sensor and a detection target of the current sensor may occur. As a result, the current detection accuracy of the current sensor may be reduced.

  Therefore, an object of the present disclosure is to provide a power conversion device in which a decrease in current detection accuracy of a current sensor is suppressed.

One of the disclosures is a reactor (314-316),
A case (330) for storing the reactor,
A current sensor (325 to 327) arranged adjacent to the reactor,
Channels (333, 333a, 333b) for flowing a liquid refrigerant are formed in the case,
A part of the flow path is located between the reactor and the current sensor.

  According to this, the action of the heat radiation generated in the reactors (314 to 316) by the heat generated by the energization on the current sensors (325 to 327) is suppressed by the refrigerant flowing through the flow paths (333, 333a, 333b). This suppresses a decrease in the current detection accuracy of the current sensors (325 to 327).

  It should be noted that the reference numbers in parentheses described above merely indicate the correspondence with the configurations described in the embodiments described below, and do not limit the technical scope at all.

It is a circuit diagram showing an in-vehicle system. FIG. 2 is a top view of the converter according to the first embodiment. FIG. 2 is a bottom view of the converter according to the first embodiment. FIG. 4 is a sectional view taken along the line IV-IV shown in FIGS. 2 and 3. It is a bottom view of the converter concerning a 2nd embodiment. It is a bottom view of the converter concerning a 3rd embodiment. It is a top view which shows the modification of a converter. It is a bottom view which shows the modification of a converter. FIG. 9 is a circuit diagram showing a modified example of the converter. FIG. 9 is a circuit diagram showing a modified example of the converter. It is a top view which shows the modification of a converter. It is a bottom view which shows the modification of a converter. It is sectional drawing which shows the modification of a converter. It is a bottom view which shows the modification of a converter. It is a bottom view which shows the modification of a converter. It is a bottom view which shows the modification of a converter.

  Hereinafter, embodiments will be described with reference to the drawings.

(1st Embodiment)
<In-vehicle system>
First, an in-vehicle system 100 provided with a power converter 300 will be described with reference to FIG. This in-vehicle system 100 constitutes a system for an electric vehicle. The in-vehicle system 100 includes a battery 200, a power conversion device 300, and a motor 400.

  The in-vehicle system 100 has a plurality of ECUs (not shown). These ECUs transmit and receive signals to and from each other via bus wiring. The plurality of ECUs cooperate to control the electric vehicle. Regeneration and power running of the motor 400 according to the SOC of the battery 200 are controlled by the control of the plurality of ECUs. SOC is an abbreviation for state of charge. ECU is an abbreviation for electronic control unit.

  The ECU has at least one arithmetic processing unit (CPU) and at least one memory device (MMR) as a storage medium for storing programs and data. The ECU is provided by a microcomputer having a computer-readable storage medium. The storage medium is a non-transitional substantial storage medium that temporarily stores a computer-readable program. The storage medium can be provided by a semiconductor memory or a magnetic disk or the like. Hereinafter, components of the in-vehicle system 100 will be individually outlined.

  Battery 200 has a plurality of secondary batteries. These plurality of secondary batteries form a battery stack connected in series. The SOC of the battery stack corresponds to the SOC of the battery 200. As the secondary battery, a lithium ion secondary battery, a nickel hydride secondary battery, an organic radical battery, or the like can be used.

  Power conversion device 300 performs power conversion between battery 200 and motor 400. Power conversion device 300 converts the DC power of battery 200 into AC power at a voltage level suitable for powering motor 400. Power conversion device 300 converts AC power generated by power generation (regeneration) of motor 400 into DC power at a voltage level suitable for charging battery 200. The power converter 300 will be described later in detail.

  The motor 400 is connected to an output shaft of an electric vehicle (not shown). The rotational energy of the motor 400 is transmitted to the traveling wheels of the electric vehicle via the output shaft. Conversely, the rotational energy of the running wheels is transmitted to the motor 400 via the output shaft.

  The motor 400 runs by AC power supplied from the power converter 300. As a result, the driving force is applied to the traveling wheels. Further, the motor 400 regenerates by the rotational energy transmitted from the running wheels. The AC power generated by this regeneration is converted into DC power by the power converter 300 and stepped down. This DC power is supplied to battery 200. The DC power is also supplied to various electric loads mounted on the electric vehicle.

<Power converter>
Next, the power converter 300 will be described. The power conversion device 300 includes a converter 310 and an inverter 370. Converter 310 boosts the DC power of battery 200 to a voltage level suitable for powering motor 400. Inverter 370 converts this DC power into AC power. This AC power is supplied to the motor 400. Inverter 370 converts AC power generated by motor 400 into DC power. Converter 310 reduces this DC power to a voltage level suitable for charging battery 200.

  As shown in FIG. 1, converter 310 is electrically connected to battery 200 via first power line 301 and second power line 302. Converter 310 is electrically connected to inverter 370 via third power line 303 and fourth power line 304.

  First power line 301 is connected to the positive electrode of battery 200. Second power line 302 is connected to the negative electrode of battery 200. A first smoothing capacitor 305 is connected to the first power line 301 and the second power line 302. One of the two electrodes of the first smoothing capacitor 305 is connected to the first power line 301, and the other is connected to the second power line 302.

  The third power line 303 and the fourth power line 304 are connected to a three-phase leg of a converter 310 described later and a second smoothing capacitor 306. One of the two electrodes of the second smoothing capacitor 306 is connected to the third power line 303, and the other is connected to the fourth power line 304. The configuration of converter 310 will be described later in detail.

  Inverter 370 has three or more phases of legs connected in parallel between third power line 303 and fourth power line 304. Each of these three or more legs has two switch elements connected in series. A bus bar is connected to a midpoint between these two switch elements. This bus bar is electrically connected to the stator coil of motor 400. The description and illustration of the configuration of the inverter 370 are omitted.

<Converter circuit configuration>
As shown in FIG. 1, converter 310 has an X-phase leg 311, a Y-phase leg 312, a Z-phase leg 313, an X-phase reactor 314, a Y-phase reactor 315, and a Z-phase reactor 316. Converter 310 has an X-phase power supply bus bar 319, a Y-phase power supply bus bar 320, a Z-phase power supply bus bar 321, an X-phase connection bus bar 322, a Y-phase connection bus bar 323, and a Z-phase connection bus bar 324. Converter 310 has an X-phase current sensor 325, a Y-phase current sensor 326, and a Z-phase current sensor 327.

  As described above, the converter 310 of the present embodiment includes the three-phase legs of the X phase to the Z phase, the reactor, the power supply bus bar, the connection bus bar, and the current sensor. The components of these three phases are independently driven and controlled by the ECU and a gate driver (not shown). Alternatively, the three-phase components are synchronously driven and controlled by the ECU and the gate driver. In FIG. 1, in order to clearly show the power supply bus bar and the connection bus bar, these are shown thicker than the other lines.

  Each of X-phase leg 311 to Z-phase leg 313 has a high-side switch 317 and a low-side switch 318, and a high-side diode 317a and a low-side diode 318a. These X-phase legs 311 to Z-phase legs 313 are each sealed with a resin to form a package. Each package of these X-phase legs 311 to Z-phase legs 313 is housed in a cooler 350 schematically shown in FIG. Refrigerant flows inside the cooler 350. Thereby, heat generation in each of the X-phase leg 311 to the Z-phase leg 313 is suppressed. Note that the cooler 350 may or may not be provided with the legs included in the inverter 370 described above. The legs of the inverter 370 are also sealed with a resin to form a package.

  In the present embodiment, an n-channel IGBT is employed as the high-side switch 317 and the low-side switch 318. As shown in FIG. 1, the collector electrode of the high-side switch 317 is connected to the third power line 303. The emitter electrode of the high side switch 317 and the collector electrode of the low side switch 318 are connected. The emitter electrode of the low side switch 318 is connected to the fourth power line 304. Thus, the high-side switch 317 and the low-side switch 318 are connected in series from the third power line 303 to the fourth power line 304.

  The cathode electrode of the high-side diode 317a is connected to the collector electrode of the high-side switch 317. The anode electrode of the high-side diode 317a is connected to the emitter electrode of the high-side switch 317. Thus, the high-side diode 317a is connected in anti-parallel to the high-side switch 317.

  Similarly, the cathode electrode of the low-side diode 318a is connected to the collector electrode of the low-side switch 318. The anode electrode of the low-side diode 318a is connected to the emitter electrode of the low-side switch 318. As a result, the low-side diode 318a is connected in anti-parallel to the low-side switch 318.

  Note that MOSFETs can be used as the high-side switch 317 and the low-side switch 318 instead of IGBTs. The type of switch employed is not particularly limited. However, when MOSFETs are used as these switches, the above-mentioned diodes may not be provided.

  Further, the semiconductor element constituting converter 310 can be manufactured using a semiconductor such as Si and a wide gap semiconductor such as SiC. The constituent material of the semiconductor element is not particularly limited.

  More specifically, the types and constituent materials of the switches included in the X-phase leg 311, the Y-phase leg 312, and the Z-phase leg 313 may be different. For example, the switch included in the X-phase leg 311 may be a MOSFET configured from SiC, and the switch included in each of the Y-phase leg 312 and the Z-phase leg 313 may be an IGBT configured from Si.

  As shown in FIG. 1, X-phase reactor 314 is connected to first power line 301 via X-phase power supply bus bar 319. The X-phase reactor 314 is connected to the midpoint between the high-side switch 317 and the low-side switch 318 of the X-phase leg 311 via the X-phase connection bus bar 322.

  Similarly, Y-phase reactor 315 is connected to first power line 301 via Y-phase power supply bus bar 320. The Y-phase reactor 315 is connected to a middle point between the high-side switch 317 and the low-side switch 318 of the Y-phase leg 312 via a Y-phase connection bus bar 323.

  Z-phase reactor 316 is connected to first power line 301 via Z-phase power supply bus bar 321. The Z-phase reactor 316 is connected to a midpoint between the high-side switch 317 and the low-side switch 318 of the Z-phase leg 313 via a Z-phase connection bus bar 324.

  The high-side switch 317 and the low-side switch 318 of the X-phase leg 311 to the Z-phase leg 313 are opened and closed by the ECU and the gate driver. The ECU generates a control signal and outputs it to the gate driver. The gate driver amplifies the control signal and outputs it to the gate electrode of the switch. Thus, the ECU raises or lowers the voltage level of the DC power input to converter 310.

  The ECU generates a pulse signal as a control signal. The ECU adjusts the step-up / step-down level of the DC power by adjusting the on-duty ratio and the frequency of the pulse signal. The ECU adjusts the step-up / step-down level by selecting the number of legs to be driven from the X-phase leg 311 to the Z-phase leg 313. This step-up / step-down level is determined according to the target torque of motor 400 and the SOC of battery 200.

  When boosting the DC power of battery 200, the ECU alternately opens and closes high-side switch 317 and low-side switch 318, respectively. Conversely, when the DC power supplied from the inverter 370 is stepped down, the ECU fixes the control signal output to the low-side switch 318 at a low level. At the same time, the ECU sequentially switches the control signal output to the high side switch 317 between a high level and a low level.

  The X-phase current sensor 325 to the Z-phase current sensor 327 are provided on the X-phase connection bus bar 322 to the Z-phase connection bus bar 324. Each of the X-phase current sensor 325 to the Z-phase current sensor 327 includes a magnetoelectric conversion unit that converts a transmitted magnetic flux into an electric signal, and a fixing unit that fixes the magnetoelectric conversion unit to the connection bus bar.

  The magnetoelectric conversion unit includes an IC chip including a bridge circuit formed of, for example, a Hall element or a magnetoresistive element, and a printed circuit board on which the IC chip is mounted. The fixing portion has, for example, a resin case for housing the printed circuit board, and a conductive relay bus bar integrally connected to the case.

  When the current sensor has the above configuration, each of the X-phase connection bus bar 322 to the Z-phase connection bus bar 324 is divided into two. And the connection bus bar divided into two is bridge | crosslinked by the said relay bus bar. As a result, the magnetoelectric converter is mechanically fixed to the connection bus bar, and a common DC current flows to each of the relay bus bar and the connection bus bar. The measured magnetic field generated from the DC current flowing through the relay bus bar passes through the bridge circuit. The bridge circuit converts the magnetic field to be measured transmitted through the bridge circuit into an electric signal. This electric signal is input to the ECU as a current flowing through the connection bus bar.

  The Hall element and the magnetoresistive element constituting the above-described bridge circuit have anisotropy with respect to the component of the magnetic field to be measured that passes through itself. That is, the Hall element and the magnetoresistive element have a property of converting a magnetic field to be measured in a horizontal direction and a vertical direction, which will be described later, into an electric signal, but not converting a magnetic field to be measured in a height direction into an electric signal. For this purpose, the relative positions of the magnetoelectric converter and the relay bus bar are determined so that the measured magnetic field having the horizontal and vertical components passes through the Hall element and the magnetoresistive element constituting the bridge circuit.

  The relative position between the magnetoelectric converter and the relay bus bar is determined by the above-mentioned resin case. Therefore, when the case thermally expands, the relative position between the relay bus bar and the magnetoelectric conversion unit may be changed. Due to the change in the relative position, the current detection accuracy of the current sensor may be reduced. Therefore, it is preferable that the temperature rise of the current sensor be suppressed. The suppression of the temperature rise of the current sensor is performed by a flow path 333 described later and a refrigerant flowing therethrough.

  Unlike the above configuration, when the fixing portion of the current sensor has only the case, the magnetoelectric conversion portion is fixed to the connection bus bar by the case. In this configuration, the magnetoelectric converter detects a magnetic field generated from the connection bus bar. The relative position between the magnetoelectric converter and the connecting bus bar is determined by the case.

  Each of the X-phase connection busbars 322 to 324 provided with the X-phase current sensor 325 to the Z-phase current sensor 327 is housed in a resin terminal block 360 shown in FIG. The terminal block 360 has a plurality of grooves for accommodating the three-phase connecting bus bars. The walls defining the grooves are located between the three-phase connecting bus bars.

<Mechanical configuration of converter>
Next, the configuration of converter 310 will be described. In this regard, hereinafter, three directions that are orthogonal to each other are referred to as a horizontal direction, a vertical direction, and a height direction.

  The converter 310 has a case 330 for accommodating these three-phase components and the first smoothing capacitor 305 in addition to the above-described three-phase leg, reactor, power supply bus bar, connection bus bar, and current sensor. As shown in FIG. 2, the case 330 also houses a cooler 350 that houses the three-phase legs, and a terminal block 360 that houses the three-phase connection bus bar and the current sensor. Note that the second smoothing capacitor 306 may or may not be housed in the case 330. When housed, the second smoothing capacitor 306 is arranged adjacent to the first smoothing capacitor 305. Further, as described above, legs provided in inverter 370 may be stored in cooler 350.

  The case 330 has a housing 331 and a cover 332. The material for forming the housing 331 and the cover 332 is a metal such as aluminum. The housing 331 is manufactured by, for example, aluminum die casting. The cover 332 is manufactured by, for example, pressing a metal plate.

  The cover 332 is welded to the housing 331. Thus, a flow path 333 described later is configured by the housing 331 and the cover 332.

  2 to 4 schematically show the configuration of the housing 331. The housing 331 has a mounting wall 334 and a side wall 335 that stands in the height direction from the edge of the mounting surface 334a of the mounting wall 334. The side wall 335 forms an annular shape in the circumferential direction around the height direction. The first smoothing capacitor 305, the X-phase reactor 314 to the Z-phase reactor 316, the cooler 350, and the terminal block 360 are provided in a region surrounded by the annular side wall 335. Hereinafter, a region surrounded by the side wall 335 is referred to as an inner space.

  Although not shown, bolt holes for bolting the first smoothing capacitor 305, the cooler 350, and the terminal block 360 are formed in the side wall 335. Bolt holes are also formed in each of the first smoothing capacitor 305, the cooler 350, and the terminal block 360. Bolts are passed through the bolt holes of the first smoothing capacitor 305, the cooler 350, and the terminal block 360 and the bolt holes of the side wall 335. Thus, each of the first smoothing capacitor 305, the cooler 350, and the terminal block 360 is bolted to the side wall 335.

  The first smoothing capacitor 305, the cooler 350, and the terminal block 360 are separated from the mounting surface 334a in the height direction while being bolted to the side wall 335. Although not shown, a gel-like heat transfer material having heat conductivity and insulation is provided between the first smoothing capacitor 305 and the mounting surface 334a, and between the terminal block 360 and the mounting surface 334a. The first smoothing capacitor 305 and the terminal block 360 can conduct heat with the mounting wall 334 via the heat transfer material. The heat transfer material may not be provided between the terminal block 360 and the mounting surface 334a.

  As shown in FIGS. 2 and 4, the mounting wall 334 has a trapezoidal wall 336 protruding toward the inner space along the height direction. The trapezoidal wall portion 336 has an upper wall 337 separated from the mounting surface 334a toward the inner space along the height direction, and a connecting wall 338 that integrally connects the upper wall 337 and the mounting wall 334. . The connecting wall 338 forms an annular shape around the height direction.

  The top surface 337a of the upper wall 337 and the inner annular surface 338a of the connection wall 338 are located on the inner space side. The inner annular surface 338a has an annular shape in the circumferential direction around the height direction. The inner annular surface 338a faces the first smoothing capacitor 305 and the terminal block 360 in the lateral direction. The inner annular surface 338a faces the cooler 350 in the vertical direction.

  A bottom surface 337b on the back side of the top surface 337a of the upper wall 337 and an outer annular surface 338b on the back side of the inner annular surface 338a of the connection wall 338 define a part of the flow path 333. The outer annular surface 338b has an annular shape in the circumferential direction around the height direction. Hereinafter, a region surrounded by the outer annular surface 338b is referred to as an outer space.

  The upper wall 337 has a first storage hole 339, a second storage hole 340, and a third storage hole 341 that are recessed in a direction from the top surface 337a toward the bottom surface 337b. The inner wall surface 337c on the inner space side of the portion of the upper wall 337 that separates the first storage hole 339 to the third storage hole 341 defines a storage space for storing the reactor. The outer wall surface 337d on the back side of the inner wall surface 337c of each of the first storage hole 339 to the third storage hole 341 partitions a part of the flow path 333.

  As shown in FIG. 2, X-phase reactor 314 to Z-phase reactor 316 are stored in first to third storage holes 339 to 341. A resin material (not shown) is potted in these storage holes. By solidifying the resin material, the X-phase reactor 314 to the Z-phase reactor 316 are fixed in the first to third storage holes 339 to 341, respectively. Needless to say, the method of fixing the reactor to the storage hole is not limited to the above example.

  The first storage hole 339 to the third storage hole 341 in which the X-phase reactor 314 to the Z-phase reactor 316 are stored are spaced apart in the vertical direction. Further, these three storage holes and the cooler 350 are also arranged side by side in the vertical direction. Further, the first smoothing capacitor 305 and the terminal block 360 are arranged side by side in the horizontal direction. Three storage holes and a cooler 350 are located between the first smoothing capacitor 305 and the terminal block 360. The vertical direction corresponds to the arrangement direction.

  Due to the above-described arrangement, the connecting wall 338 of the trapezoidal wall portion 336 having the first storage hole 339 to the third storage hole 341 is formed between the X-phase reactor 314 to the Z-phase reactor 316 and the cooler 350. Has been interposed. Similarly, connecting walls 338 are interposed between X-phase reactors 314 to Z-phase reactor 316 and first smoothing capacitor 305, and between X-phase reactors 314 to Z-phase reactor 316 and first smoothing capacitor 305, respectively. Have been.

  FIG. 3 shows the back side of the mounting surface 334a of the mounting wall 334. The inner surface 332a of the cover 332 is welded to the back surface 334b on the back side of the mounting surface 334a.

  As shown in FIG. 4, the inner surface 332a faces the height direction. On the other hand, the back surface 334b is locally and selectively recessed toward the inner space. Therefore, when the cover 332 is welded to the mounting wall 334, a part of the rear surface 334b is separated from the inner surface 332a in the height direction. A part of a flow path 333 for flowing a liquid refrigerant such as water is formed between the back surface 334b and the inner surface 332a.

  In addition, as described above, a part of the mounting wall 334 protrudes toward the inner space side to form the trapezoidal wall portion 336. An outer space is formed on the back surface 334b side by the connecting wall 338 of the trapezoidal wall portion 336. The opening of the outer space is covered by the cover 332. Thereby, a part of the flow path 333 for flowing the above-mentioned refrigerant is also formed between the trapezoidal wall portion 336 and the cover 332.

  In the following, for the sake of clarity, a portion of the flow channel 333 that is partitioned between the back surface 334b and the inner surface 332a is referred to as a first flow channel 333a. A portion of the flow channel 333 that is defined between the inner surface 332a and the surface of the trapezoidal wall portion 336 on the back surface 334b side is referred to as a second flow channel 333b.

  In FIG. 3, in order to clarify the positions where the flow paths 333 are formed, parts of the mounting wall 334 that divide the flow path 333 are shown in white, and parts that do not divide the flow path 333 are shown by hatching. . In order to show the positional relationship between the flow path 333 and the members housed in the case 330, the outlines of these members are shown by broken lines. However, in order to avoid complication of the notation due to the overlap with the flow path 333, the illustration of the cover 332, and the three-phase power supply bus bar and the connection bus bar are omitted.

<First flow path>
As shown in FIG. 3, the first flow path 333a includes a supply flow path 333c to which the refrigerant is supplied from a refrigerant supply pump mounted on the vehicle, a cooling flow path 333d through which the refrigerant supplied from the supply flow path 333c flows, Having. Further, the first flow path 333a has an upstream flow path 333e that connects the cooling flow path 333d and the second flow path 333b, and a downstream flow path 333f to which the refrigerant is supplied from the second flow path 333b.

  The first smoothing condenser 305 is arranged alongside the cooling channel 333d in the height direction. The heat generated in the first smoothing condenser 305 is transferred to the refrigerant flowing through the cooling flow path 333d via the heat transfer material and the mounting wall 334. As a result, heat generation of the first smoothing capacitor 305 is suppressed.

  The refrigerant that has exchanged heat with the first smoothing condenser 305 is supplied to the second flow path 333b via the upstream flow path 333e. Then, the refrigerant flowing through the second flow path 333b is supplied to the downstream flow path 333f. The refrigerant supplied to the downstream flow path 333f is supplied to the cooler 350 via a pipe (not shown).

<Second flow path>
As shown in FIG. 3 and FIG. 4, the second flow path 333b is defined (configured) by wall surfaces described below. That is, the second flow path 333b includes a bottom surface 337b of the upper wall 337, an outer annular surface 338b of the connection wall 338 annularly connected to the bottom surface 337b, an outer wall surface 337d of each of the first storage hole 339 to the third storage hole 341, and , And an inner surface 332 a of the cover 332.

  The outer wall surface 337d is composed of a first side surface 337e and a second side surface 337f that are vertically separated from each other, a first connection surface 337g and a second connection surface 337h that are horizontally separated from each other, and a bottom surface that faces in the height direction. 337i. In the circumferential direction around the height direction, the first side surface 337e, the second connection surface 337h, the second side surface 337f, and the first connection surface 337g are sequentially connected to form an annular shape. These four surfaces define a part of the second flow path 333b. On the other hand, the bottom surface 337i is in contact with the inner surface 332a. Alternatively, the bottom surface 337i is disposed so close to the inner surface 332a that it cannot constitute a flow path that contributes to the effective flow of the refrigerant. Therefore, the bottom surface 337i does not partition a part of the second flow path 333b.

  Note that the first side surface 337e is farther from the cooler 350 than the second side surface 337f. In other words, the second side surface 337f is located closer to the cooler 350 than the first side surface 337e. The first connection surface 337g is farther from the first smoothing capacitor 305 than the second connection surface 337h. In other words, the second connection surface 337h is located closer to the first smoothing capacitor 305 than the first connection surface 337g. In other words, the first connection surface 337g is located closer to the terminal block 360 in which the X-phase current sensors 325 to Z-phase current sensor 327 are housed than the second connection surface 337h.

  As shown in FIG. 3, the first storage holes 339 to the third storage holes 341 are arranged to be separated in the vertical direction. Each of the first storage hole 339 to the third storage hole 341 is separated from the outer annular surface 338b in the horizontal and vertical directions. Thereby, between the outer wall surface 337d of each of the first storage hole 339 to the third storage hole 341 and the outer annular surface 338b of the connection wall 338, and the outer wall surface 337d of each of the first storage hole 339 to the third storage hole 341. A second flow path 333b is defined between the two.

  More specifically, a first lateral flow path extending in the lateral direction is formed between the outer annular surface 338b and the first side surface 337e of the first storage hole 339. A second lateral flow path extending in the lateral direction is formed between the second side surface 337f of the first storage hole 339 and the first side surface 337e of the second storage hole 340. A third lateral flow path extending in the lateral direction is formed between the second side surface 337f of the second storage hole 340 and the first side surface 337e of the third storage hole 341. Between the second side surface 337f of the third storage hole 341 and the outer annular surface 338b, a fourth lateral flow path extending in the lateral direction is formed. Thus, the second flow path 333b has a total of four horizontal flow paths extending in the horizontal direction.

  Further, a first vertical flow path extending in the vertical direction is defined between the first connection surface 337g and the outer annular surface 338b of each of the first storage hole 339 to the third storage hole 341. A second vertical flow path extending in the vertical direction is defined between the second connection surface 337h of each of the first storage hole 339 to the third storage hole 341 and the outer annular surface 338b. Thus, the second flow path 333b has a total of two horizontal flow paths extending in the vertical direction. These two vertical channels communicate with each of the four horizontal channels.

  In the circumferential direction around the height direction, the first horizontal flow path, the second vertical flow path, the fourth horizontal flow path, and the first vertical flow path are connected to form an annular flow path. The first storage hole 339 to the third storage hole 341 are located in this annular flow path. Thereby, each of the first storage hole 339 to the third storage hole 341 is surrounded by the annular flow path in the circumferential direction around the height direction. A cutout communicating with the upstream flow path 333e is formed in a portion of the outer annular surface 338b that defines a part of the second vertical flow path. A cutout communicating with the downstream flow path 333f is formed in a portion of the outer annular surface 338b that defines a part of the fourth horizontal flow path.

  The depth in the height direction of a total of six flow passages extending in the vertical and horizontal directions and constituting the second flow passage 333 b is determined by the bottom surface 337 b of the upper wall 337 and the inner surface 332 a of the cover 332. As shown in FIG. 4, the upper wall 337 is located on the inner space side. As described above, each of the first storage hole 339 to the third storage hole 341 is surrounded by a part (annular flow path) of the second flow path 333b in the circumferential direction around the height direction.

  Therefore, as shown in FIG. 4, a part of second flow path 333b is located between X-phase reactors 314 to Z-phase reactor 316 and terminal block 360 that houses X-phase current sensors 325 to Z-phase current sensor 327. are doing. Part of the second flow path 333b is located between the X-phase reactor 314 to the Z-phase reactor 316 and the first smoothing capacitor 305. Further, a part of the second flow path 333b is located between the X-phase reactor 314 to the Z-phase reactor 316 and the cooler 350.

<Effects>
Thus, the second flow path 333b through which the refrigerant flows is interposed between the X-phase reactors 314 to 316 and the terminal block 360 that houses the X-phase current sensors 325 to Z-phase current sensors 327. Thereby, the effect of heat radiation generated from X-phase reactors 314 to 316 by the heat generated by energization on X-phase current sensors 325 to Z-phase current sensor 327 is suppressed.

  Therefore, the temperature rise of the X-phase current sensor 325 to the Z-phase current sensor 327 is suppressed. Due to the thermal expansion due to the temperature rise, a change in the relative position between the relay bus bar (connecting bus bar) that emits the magnetic field to be measured and the magnetoelectric converter is suppressed. As a result, a change in the direction of the magnetic field to be measured passing through the magnetoelectric conversion unit is suppressed. A decrease in the current detection accuracy of the current sensor is suppressed.

  In addition, electromagnetic noise is emitted from X-phase reactor 314 to Z-phase reactor 316 by energization. The action of the electromagnetic noise on the X-phase current sensor 325 to the Z-phase current sensor 327 is suppressed by the part of the case 330 that partitions the second flow path 333b. This also suppresses a decrease in the current detection accuracy of the current sensor.

  A part of the second flow path 333b is defined by a wall surface of a trapezoidal wall portion 336 in which a first storage hole 339 to a third storage hole 341 for storing the X-phase reactor 314 to the Z-phase reactor 316 are formed. According to this, an increase in the physique of the case 330 is suppressed as compared with a configuration in which a part of the second flow path is partitioned by a wall surface different from the trapezoidal wall portion.

  Four surfaces of a first side surface 337e, a second side surface 337f, a first connection surface 337g, and a second connection surface 337h of the outer wall surface 337d of each of the first storage hole 339 to the third storage hole 341 constitute a second flow path 333b. Is partly divided. Thereby, heat exchange between the X-phase reactor 314 to the Z-phase reactor 316 stored in the first storage hole 339 to the third storage hole 341 and the refrigerant is promoted.

  A second flow path 333b is interposed between the X-phase reactors 314 to 316 and the first smoothing capacitor 305. Thereby, the effect of the heat radiation generated from X-phase reactor 314 to Z-phase reactor 316 on first smoothing capacitor 305 is suppressed. A change in the capacitance of the capacitor due to a rise in temperature is suppressed.

(2nd Embodiment)
Next, a second embodiment will be described with reference to FIG. The power converter according to each embodiment described below has many points in common with those according to the above-described embodiments. Therefore, the description of the common parts will be omitted below, and different parts will be mainly described. In the following, the same elements as those described in the above embodiment are denoted by the same reference numerals.

  In the first embodiment, an example is shown in which the first side surface 337e and the second side surface 337f of the outer wall surface 337d and the first connection surface 337g and the second connection surface 337h each define a part of the second flow path 333b. Was. On the other hand, in the present embodiment, one of the first connection surface 337g and the second connection surface 337h and the two surfaces of the first side surface 337e and the second side surface 337f define a part of the second flow path 333b. .

  As shown in FIG. 5, the second connection surface 337h of the first storage hole 339 is connected to the outer annular surface 338b. The first connection surface 337g of the first storage hole 339 defines a part of the second channel 333b. A third vertical channel extending in the vertical direction is defined between the first connection surface 337g of the first storage hole 339 and the outer annular surface 338b.

  The first connection surface 337g of the second storage hole 340 is connected to the outer annular surface 338b. The second connection surface 337h of the second storage hole 340 defines a part of the second flow path 333b. A fourth vertical channel extending in the vertical direction is defined between the second connection surface 337h of the second storage hole 340 and the outer annular surface 338b.

  The second connection surface 337h of the third storage hole 341 is connected to the outer annular surface 338b. The first connection surface 337g of the third storage hole 341 defines a part of the second flow path 333b. A fifth vertical channel extending in the vertical direction is defined between the first connection surface 337g of the third storage hole 341 and the outer annular surface 338b.

  The third vertical flow path and the fourth vertical flow path are separated in the horizontal direction. Similarly, the fourth vertical channel and the fifth vertical channel are separated in the horizontal direction. The third vertical channel and the fifth vertical channel are spaced apart in the vertical direction. In the vertical direction, the fourth vertical channel is located between the third vertical channel and the fifth vertical channel.

  The third vertical flow path communicates the first horizontal flow path and the second horizontal flow path on the first connection surface 337g side of the first storage hole 339. The fourth vertical flow path communicates the second horizontal flow path and the third horizontal flow path on the second connection surface 337h side of the second storage hole 340. The fifth vertical flow path communicates the third horizontal flow path with the fourth horizontal flow path on the first connection surface 337g side of the third storage hole 341.

  As described above, the second flow path 333b meanders between any two storage holes arranged in the vertical direction. And the route is one.

  According to this, unlike the configuration in which the second flow path branches and includes a plurality of paths, the decrease in the amount and speed of the refrigerant flowing in the second flow path 333b is suppressed. A decrease in the cooling performance of the reactor via the refrigerant is suppressed.

  Further, since the second flow path 333b meanders, a change in the flow direction of the refrigerant in the second flow path 333b occurs. This change in the flow direction is caused by collision of the refrigerant with the wall surface that defines the second flow path 333b. Due to this collision, heat exchange between the refrigerant and the case 330 is promoted. As a result, a reduction in the cooling performance of the reactor housed in case 330 is suppressed.

  In particular, as indicated by an arrow in FIG. 5, the refrigerant flowing in the first horizontal flow path collides with the terminal block 360 side of the outer annular surface 338b, thereby changing its flow direction to the third vertical flow path. . The refrigerant flowing in the third horizontal flow path collides with the terminal block 360 side of the outer annular surface 338b, thereby changing the flow direction to the fifth vertical flow path.

  Due to this collision, the temperature rise on the terminal block 360 side of the outer annular surface 338b is suppressed. The temperature rise of the X-phase current sensors 325 to 327 housed in the terminal block 360 is suppressed. Note that the refrigerant flowing through the second lateral flow path and the fourth lateral flow path collides with the outer annular surface 338b on the first smoothing condenser 305 side. Due to this collision, temperature rises of the outer annular surface 338b on the first smoothing capacitor 305 side and the first smoothing capacitor 305 are suppressed.

  The power conversion device 300 according to the present embodiment includes components equivalent to the power conversion device 300 according to the first embodiment. It goes without saying that the same operation and effect can be obtained. The same applies to the following embodiments and modified examples.

(Third embodiment)
Next, a third embodiment will be described with reference to FIG.

  In the second embodiment, as shown in FIG. 5, an example is shown in which all of the second storage hole 340 and the third storage hole 341 are located within the vertical projection area of the first storage hole 339.

  On the other hand, in the present embodiment, the second storage hole 340 is separated from the upstream flow path 333e along the lateral direction. Therefore, a part of the second storage hole 340 protrudes from the vertical projection area of the first storage hole 339.

  Accordingly, the first storage holes 339 to the third storage holes 341 are arranged in a staggered arrangement in the vertical direction. The first storage holes 339 to the third storage holes 341 are arranged alternately in the horizontal direction and in the vertical direction.

  Due to such arrangement, the first connection surface 337g of the first storage hole 339 and the first side surface 337e of the second storage hole 340 are arranged in the vertical direction. The second connection surface 337h of the second storage hole 340 and the second side surface 337f of the first storage hole 339 are arranged in the vertical direction.

  Further, the second connection surface 337h of the second storage hole 340 and the first side surface 337e of the third storage hole 341 are arranged in the vertical direction. The first connection surface 337g of the third storage hole 341 and the second side surface 337f of the second storage hole 340 are arranged in the vertical direction.

  According to such a configuration, as indicated by an arrow in FIG. 6, the refrigerant flowing through the third vertical flow path that is partially defined by the first connection surface 337g of the first storage hole 339 flows through the second storage hole 340. It collides with the first side surface 337e. Refrigerant flowing through the fourth vertical flow path, a part of which is defined by the second connection surface 337h of the second storage hole 340, collides with the first side surface 337e of the third storage hole 341. Due to this collision, the Y-phase reactor 315 and the Z-phase reactor 316 stored in the second storage hole 340 and the third storage hole 341 located downstream of the X-phase reactor 314 in the flow direction of the refrigerant, the refrigerant, Heat exchange is promoted.

  As described above, the preferred embodiments of the present disclosure have been described. However, the present disclosure is not limited to the above-described embodiments, and can be implemented with various modifications without departing from the gist of the present disclosure. It is.

(First Modification)
In each embodiment, for example, as shown in FIGS. 2 and 3, an example is shown in which X-phase reactors 314 to 316 and X-phase current sensors 325 to Z-phase current sensors 327 are arranged in the horizontal direction. However, as shown in FIGS. 7 and 8, X-phase reactor 314 to Z-phase reactor 316 and X-phase current sensor 325 to Z-phase current sensor 327 face in the height direction, and furthermore, in the horizontal and vertical directions. They may be arranged in an intersecting inclination direction. As long as at least a part of the second flow path 333b is located between the X-phase reactors 314 to 316 and the X-phase current sensor 325 to the Z-phase current sensor 327, the arrangement direction of both is not particularly limited. .

(Second Modification)
In each embodiment, an example has been described in which converter 310 includes three-phase legs of X phase to Y phase, a reactor, a power supply bus bar, a connection bus bar, and a current sensor. However, for example, as shown in FIGS. 9 and 10, converter 310 can also adopt a configuration including one-phase leg, reactor, power supply bus bar, connection bus bar, and current sensor. However, in FIG. 9, the three-phase reactor is connected in series to form one reactor. The number of reactors is not particularly limited. FIGS. 11 and 12 show a mechanical configuration when converter 310 has only one-phase reactor.

(Third Modification)
In each embodiment, for example, as illustrated in FIG. 4, an example in which the bottom surface 337i does not partition a part of the second channel 333b has been described. However, for example, as shown in FIG. 13, the bottom surface 337i may separate a part of the second flow path 333b by separating the bottom surface 337i and the inner surface 332a. In the case of this modification, the distance in the height direction between the bottom surface 337i and the inner surface 332a is equal to or less than the distance in the height direction between the back surface 334b and the inner surface 332a.

(Fourth modification)
In each embodiment, for example, as shown in FIGS. 2 and 3, an example is shown in which the first storage hole 339 to the third storage hole 341 are lined up in the vertical direction. However, the direction in which the first storage hole 339 to the third storage hole 341 are arranged is not particularly limited. For example, as shown in FIGS. 14 to 16, a configuration in which the first storage holes 339 to the third storage holes 341 are arranged side by side in the lateral direction may be adopted. The horizontal direction corresponds to the arrangement direction.

  The second flow path 333b shown in FIG. 14 corresponds to the second flow path 333b shown in FIG. 3 rotated by 90 ° in the circumferential direction around the height direction. The second flow path 333b shown in FIG. 15 corresponds to the second flow path 333b shown in FIG. The second flow path 333b shown in FIG. 16 corresponds to the second flow path 333b shown in FIG. Due to this rotation, the first side surface 337e and the second side surface 337f are arranged side by side. The first connection surface 337g and the second connection surface 337h are arranged in the vertical direction.

(Other modifications)
In the present embodiment, an example has been described in which the power converter 300 is included in the in-vehicle system 100 for an electric vehicle. However, the application of the power converter 300 is not particularly limited to the above example. For example, a configuration in which the power conversion device 300 is included in a hybrid system including a motor and an internal combustion engine may be employed.

  In the present embodiment, the configuration in which the power conversion device 300 is connected to one motor 400 has been described. However, a configuration in which the power conversion device 300 is connected to the two motors 400 can also be adopted. In this case, power conversion device 300 includes two inverters 370.

100 vehicle-mounted system, 200 battery, 300 power converter, 305 first smoothing capacitor, 306 second smoothing capacitor, 310 converter, 314 X-phase reactor, 315 Y-phase reactor, 316 Z-phase reactor 325: X-phase current sensor, 326: Y-phase current sensor, 327: Z-phase current sensor, 330: case, 331 ... housing, 332 ... cover, 333 ... flow path, 333a ... first flow path, 333b ... 2 flow paths, 337c ... inner wall surface, 337d ... outer wall surface, 337e ... 1st side surface, 337f ... 2nd side surface, 337g ... 1st connection surface, 337h ... 2nd connection surface, 337i ... bottom surface, 339 ... 1st storage hole. 340: second storage hole, 341: third storage hole, 370: inverter

Claims (9)

Reactors (314-316)
A case (330) for storing the reactor,
A current sensor (325 to 327) arranged adjacent to the reactor,
Flow paths (333, 333a, 333b) for flowing a liquid refrigerant are formed in the case,
A power converter in which a part of the flow path is located between the reactor and the current sensor. Having a plurality of the reactors,
A plurality of storage holes (339 to 341) for independently storing the plurality of reactors are formed in the case,
A plurality of the storage holes are spaced apart and are arranged in the arrangement direction,
2. The electric power according to claim 1, wherein at least a part of an outer wall surface (337d) on a back side of an inner wall surface (337c) defining a storage space for storing the reactor in the storage hole defines a part of the flow path. 3. Conversion device. The outer wall includes two side surfaces (337e, 337f) arranged in the arrangement direction, two connection surfaces (337g, 337h) connecting the two side surfaces, and two side surfaces and the two connection surfaces. A connecting bottom surface (337i);
If any two of the plurality of storage holes that are adjacent to each other in the arrangement direction are a first storage hole (339) and a second storage hole (340),
One of the two connection surfaces of the first storage hole and two of the side surfaces, and the other of the two connection surfaces of the second storage hole and the two of the side surfaces are each the flow path. The power conversion device according to claim 2, wherein a part of the power conversion device is partitioned.   One of the two connection surfaces of the first storage hole and the first storage hole side of the two side surfaces of the second storage hole are arranged in the alignment direction, and The power converter according to claim 3, wherein the other of the two connection surfaces provided and the second storage hole side of the two side surfaces provided in the first storage hole are aligned in the alignment direction.   5. A part of a portion of the flow path located between the reactor and the current sensor is defined by one of the two connection surfaces provided in the first storage hole. 3. The power converter according to claim 1. The outer wall includes two side surfaces (337e, 337f) arranged in the arrangement direction, two connection surfaces (337g, 337h) connecting the two side surfaces, and two side surfaces and the two connection surfaces. A connecting bottom surface (337i);
If any two of the plurality of storage holes that are adjacent to each other in the arrangement direction are a first storage hole (339) and a second storage hole (340),
The power converter according to claim 2, wherein the two connection surfaces and the two side surfaces of each of the first storage hole and the second storage hole define a part of the flow path. Having capacitors (305, 306) arranged adjacent to the reactor,
The power converter according to any one of claims 1 to 6, wherein a part of the flow path is located between the reactor and the capacitor.   The power converter according to claim 7, wherein the reactor is located between the capacitor and the current sensor.   The power converter according to any one of claims 1 to 8, wherein a material forming the case is a metal.

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