JP6583377B2 - Electric drive vehicle structure - Google Patents

Description

  The present invention relates to an electrically driven vehicle structure, and more specifically, left and right front side frames extending in the vehicle front-rear direction are provided on both left and right sides in a motor room disposed at the front of the vehicle, and the vehicle is interposed between the left and right front side frames. A cross member extending in the width direction is bridged, and an inverter that boosts and outputs input electricity and a junction box that houses an electrical distribution circuit including a relay are stacked on top of the cross member. The present invention relates to an electric drive vehicle structure in which a vehicle drive motor is suspended below the cross member and fed by a harness from the junction box.

  Conventionally, a motor room is formed in the front portion of the vehicle, left and right front side frames extending in the vehicle front-rear direction on both left and right sides of the motor room are provided, and an electric motor is disposed between the pair of left and right front side frames, 2. Description of the Related Art An electrically driven vehicle configured to drive left and right wheels using an electric motor as a power source is known.

Examples of such an electrically driven vehicle include those disclosed in Patent Documents 1 and 2.
The one disclosed in Patent Document 1 is provided with left and right front side frames extending in the vehicle front-rear direction on both left and right sides in a motor room, and a cross member extending in the vehicle width direction is mounted on the left and right front side frames. The vehicle driving motor is suspended under the cross member.

  What is disclosed in the patent document is that a left and right front side frame extending in the vehicle front-rear direction on both left and right sides in a motor room is provided, and a power unit in which a motor and a transaxle are integrated is provided, and a motor housing in the power unit An inverter housing is mounted on the top of the inverter, a junction box is mounted on the top of the inverter housing, and each element (power unit, inverter housing, junction box) is connected to the left and right mounting devices without using a cross member. Are supported by the left and right front side frames.

  In general, in an electrically driven vehicle structure, cooling water leaking from a damaged cooling water pipe due to a backward movement of an electric unit such as an inverter housing or a junction box at the time of a vehicle collision causes a damaged three-phase cable or its Although it is required to prevent a short circuit (so-called short circuit) over the connecting portion, the above-mentioned Patent Document 2 does not disclose a point relating to the cooling water piping.

German Patent Application Publication No. 102009040896 JP 2016-22799 A

Therefore, according to the present invention, when the inverter housing or the junction box is retracted at the time of a vehicle collision, the cooling water leaked from the damaged cooling water pipe is prevented from being short-circuited (short-circuited) on the damaged harness or its connecting portion. An object is to provide an electrically driven vehicle structure that can be suppressed.

The electrically driven vehicle structure according to the present invention is provided with left and right front side frames that extend in the vehicle front-rear direction on both left and right sides in a motor room disposed at the front of the vehicle, and extends in the vehicle width direction between the left and right front side frames. A cross member is bridged, and an inverter that boosts and outputs input electricity and a junction box that houses an electric distribution circuit including a relay are stacked on top of the cross member and stacked above and below. An electric drive vehicle structure in which a vehicle drive motor powered by a harness from the junction box is suspended at the lower part of the cross member, and the inverter casing is mounted on the upper surface of the cross member. The junction box casing is placed on the upper surface of the inverter casing, and the inverter casing on the vehicle front side. Entrance of the cooling water is provided on the vehicle rear side of the junction box housing, the connecting portion of the harness is provided, the harness is suspended bent in an arc shape when viewed from the side of the vehicle from the connecting section the It is connected to a vehicle drive motor.

According to the above configuration, the inverter housing provided with the cooling water inlet / outlet is placed under the junction box housing, and the junction box housing provided with the harness connection portion is used as the inverter housing. Since the cooling water entrance / exit is provided on the front side of the vehicle and the harness connection part is provided on the rear side of the vehicle, the inverter housing or the junction box housing may be damaged when the vehicle collides. It can suppress that the cooling water which leaked from the cooled cooling water piping applied to a damaged harness and its connection part, and is short-circuited (short-circuited).

In addition, since the harness described above is bent in an arc shape from the connection portion of the junction box housing located on the upper side of the two housings in a side view of the vehicle and is suspended and connected to the vehicle drive motor, the junction box The distance between the casing and the motor can be increased and the rigid harness can be gently bent and routed.
If, when the upper and lower distance between the junction box housing and the motor is short, housing back of the harness, but the amount of projection rearward from the motor back is large, according to the above configuration, the harness It is possible to reduce the amount of rearward projecting from the rear surface of the housing and the rear surface of the motor.

According to another embodiment of the present invention, the vehicle rear side of the junction box housing, provided the power cable connection portion for connecting the wired power cables toward the power supply unit placed on the vehicle rear to the front of the vehicle It is what was done.
The power supply unit described above may be set to a main battery or a range extender (a power generation engine configured by a rotary engine or the like) disposed under the floor panel at the rear of the vehicle.

According to the said structure, not only a harness connection part but a power cable connection part can escape the flooding of cooling water.

According to this invention, when the inverter housing or the junction box is retracted at the time of a vehicle collision, the cooling water leaked from the damaged cooling water pipe is short-circuited (shorted) over the damaged harness or its connecting portion. There is an effect that can be suppressed.

The perspective view which shows the electric drive vehicle structure of this invention Front view of electric drive vehicle structure Top view of electric drive vehicle structure Rear view of electric drive vehicle structure Longitudinal sectional view of the main part showing the connection structure of the bus bar Tray perspective view Exploded plan view showing mounting structure of electric unit to tray Top view showing the electrical unit attached to the tray

The purpose is to prevent the coolant leaking from the damaged coolant piping from being damaged and short-circuited (short-circuited) over the damaged harness or its connection by retreating the inverter housing or junction box in the event of a vehicle collision. Left and right front side frames extending in the vehicle front-rear direction are provided on the left and right sides in the motor room arranged at the front of the vehicle, and a cross member extending in the vehicle width direction is bridged between the left and right front side frames. An inverter that boosts and outputs input electricity and a junction box that accommodates an electrical distribution circuit including a relay are stacked on top of each other, and the junction box is placed below the cross member. In an electrically driven vehicle structure in which a vehicle drive motor powered by a harness is suspended, The casing of the inverter is mounted on the top surface of the cross member, the casing of the junction box is mounted on the top surface of the casing of the inverter, and an inlet / outlet of cooling water is provided on the vehicle front side of the inverter casing. provided on the vehicle rear side of the junction box housing, the connecting portion of the harness is provided, the harness is suspended bent in an arc shape when viewed from the side of the vehicle from the connecting portion to said vehicle-driving motor Realized by the configuration of being connected.

An embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective view showing the electric drive vehicle structure, FIG. 2 is a front view thereof, FIG. 3 is a plan view of FIG. 1, and FIG. 4 is a rear view of FIG.

1-4, the motor room 1 is arrange | positioned in the vehicle front part. Specifically, a dash lower panel (dash panel) that rises upward from the front end of the floor panel is provided, the front side of this dash lower panel is set to the motor room 1, and the rear side of the dash lower panel is set to the vehicle compartment. .
Left and right front side frames 2, 2 extending in the vehicle front-rear direction on both left and right sides in the motor room 1 are provided.

  As shown in FIGS. 3 and 4, the front side frame 2 has a closed cross section that extends in the front-rear direction of the vehicle by joining and fixing upper and lower joint flanges of the front side frame outer 3 and the front side frame inner 4. 5 (see FIG. 4) is a vehicle body strength member.

  As shown in FIGS. 1 to 4, a set plate 6 for attaching a crash can is provided at the front end portion of the front side frame 2, and the crash can (impact energy) is attached to the set plate 6 via the attachment plate. The bumper reinforcement extending in the vehicle width direction is attached between the front ends of the left and right crash cans.

  As shown in FIGS. 1 and 3, mount brackets 7 and 7 are bolted to the upper surface portion of the front side frame inner 4 in the front side frame 2, and these left and right mount brackets 7 and 7 are connected to the vehicle width direction. By attaching the cross member 8 extending to the left and right, the cross member 8 is bridged between the pair of left and right front side frames 2 and 2.

As shown in FIGS. 1 and 3, on the left side of the vehicle, an inverted L-shaped battery support arm 9 is provided immediately after the mounting bracket 7 described above when viewed from the front of the vehicle. The battery support arm 9 has a substantially vertical portion attached to a vertical surface portion on the inner side in the vehicle width direction of the front side frame inner 4.
On the other hand, a battery support protrusion 7a that extends upward is formed integrally with the mount bracket 7 on the left side of the vehicle. As shown in FIGS. 2 and 3, the battery support protrusion 7a and the battery support arm 9 described above are provided. A battery 11 is disposed on the upper portion of the battery tray 10 via a battery tray 10. A battery clamp 12 is provided between the upper ends of both the vehicle width direction inner and outer pieces in the vehicle longitudinal direction intermediate portion of the battery tray 10 in the vehicle width direction. It is connected to. In this embodiment, a 12V battery using a lead battery is employed as the battery 11 described above, but the present invention is not limited to this.

  FIG. 5 is a longitudinal sectional view of an essential part of the electrically driven vehicle structure. As shown in FIG. 5, the above-mentioned cross member 8 is made of an upper wall 8a, a front wall 8b, a rear wall 8c, and a plurality of reinforcing members. As shown in FIG. 2, the lower part of the center in the vehicle width direction of the front wall 8b and the rear wall 8c is downward in an arc shape with respect to the lower side of both ends in the vehicle width. It is formed to protrude. The upper surface of the upper wall 8a of the cross member 8 is formed in a flat shape. Further, as shown in FIG. 2, recesses 8e and 8e that are open at the bottom are formed at two places on the front wall 8b of the cross member 8 in the middle in the vehicle width direction.

As shown in FIG. 2, the motor unit 15 is suspended below the cross member 8 using left and right support devices 13 and 14 provided at positions corresponding to the recesses 8 e and 8 e of the cross member 8.
As shown in FIG. 2, the motor unit 15 described above includes a three-phase AC motor 16 for driving a vehicle (hereinafter simply referred to as a motor 16) located on the right side of the vehicle and a speed reducer located on the left side of the vehicle. A gear box 17, a closing member 18 for closing the opening provided on the right side of the motor housing 16a, and a closing member 19 for closing the opening provided on the left side of the casing 17a of the gear box 17. It is an integrated unit.

As shown in FIG. 2, the flange portion 16 b provided on the left side of the motor housing 16 a and the flange portion 17 b provided on the right side of the gear box 17 are fastened by bolts 20.
Here, on the left side of the vehicle, the upper portion of the closing member 19 and the lower portion of the support device 13 are fastened and fixed from the outside in the vehicle width direction to the inside in the vehicle width direction using fastening bolts. The upper part of the closing member 18 and the lower part of the support device 14 are fastened and fixed from the front of the vehicle to the rear of the vehicle using fastening bolts. As a result, the motor unit 15 including the motor 16 is suspended below the cross member 8.

  FIG. 6 is a perspective view of the tray, FIG. 7 is an exploded plan view showing the mounting structure of the electric unit to the tray, and FIG. 8 is a plan view showing the electric unit attached to the tray.

  As shown in a front view in FIG. 2, a left tray 21 as a tray is attached to a substantially central upper portion of the cross member 8 in the vehicle width direction, and an inverter 30 is placed on the left tray 21. The junction box 40 is placed, and both the inverter 30 and the junction box 40 constitute an electric unit E1, and the junction box 40 is disposed substantially directly above the motor 16.

  Further, as shown in FIG. 2, a right tray 22 as a tray is attached to the right side of the left tray 21 in the cross member 8 in the vehicle width direction, and a charger 50 is placed on the right tray 22, and the charger The DC-DC converter 60 is placed on the upper part of the electric power unit 50, and the charger 50 and the DC-DC converter 60 constitute an electric unit E2.

The above-described inverter 30 boosts and outputs electricity input from a main battery (not shown) as a power supply unit disposed at the lower part of the floor panel via power cables 71 and 72 described later. It has an inverter circuit that converts electric power into three-phase alternating current.
The junction box 40 described above is a so-called junction box for protecting terminals and terminals used when connecting, branching, and relaying wires, and accommodates an electrical distribution circuit including a relay.

The above-described charger 50 inputs power from an external power source and charges the main battery, and the charger 50 and the main battery are connected by a power cable (not shown). The device 50 has a charging circuit.
The DC-DC converter 60 described above is a converter that converts a high voltage into a low voltage (for example, 12 V) for driving an on-vehicle device.

  As shown in FIGS. 3 and 5, the front and rear lengths of the electric units E1 and E2 described above are larger than the front and rear lengths of the cross member 8, and the housings of the electric units E1 and E2, that is, the inverter housings 31, The front edge of the junction box housing 41 (see FIG. 5), the charger housing 51, and the converter housing 61 (see FIG. 2) of the DC-DC converter 60 is shown in FIGS. As shown, the cross member 8 is positioned in front of the vehicle with respect to the front wall 8b as the front edge portion.

As shown in FIGS. 6 and 7, the left tray 21 is formed continuously with a first bottom portion 21 a that is in contact with and fixed to the top of the cross member 8 and a front portion of the first bottom portion 21 a. A second bottom portion 21b located at a position higher than 21a and left and right third bottom portions 21c, 21c formed continuously from the left and right of the rear portion of the first bottom portion 21a and at the same height as the second bottom portion 21b. The first bottom portion 21a described above is fixed to the upper portion of the cross member 8 using a plurality of bolts 23. The mounting portion 24 of the second bottom portion 21b and the third bottom portions 21c and 21c has a lower portion of the electric unit E1. The inverter 30 is fastened in the vertical direction using bolts 25.
That is, the first bottom portion 21a, the second bottom portion 21b, and the third bottom portion 21c described above are bottom portions that provide a fixed portion of the inverter 30 below the electric unit E1.

  Moreover, as shown in FIGS. 5 to 8, the above-described left tray 21 is in front of the vehicle over the entire region in the vehicle width direction from the front edge portion of the inverter casing 31 and the junction box casing 41 in the vehicle plan view. The front edge 21d is positioned, and the front edge 21d is formed in a wall shape that rises in a substantially vertical direction from a second bottom 21b as a bottom surface.

  As shown in FIGS. 6 to 8, the left tray 21 includes left and right side walls 21e and 21e that rise upward from both left and right outer ends in the vehicle width direction of the first bottom portion 21a and the second bottom portion 21b. A rear wall 21f that rises upward by connecting the three bottom portions 21c and 21c is integrally formed.

  As shown in FIG. 6, the left tray 21 is provided with a plurality of upward convex beads 21g extending in the vehicle front-rear direction and spaced apart in the vehicle width direction at the first bottom portion 21a, and the second bottom portion. 21b is provided with a plurality of downward convex beads 21h extending in the vehicle front-rear direction and spaced apart in the vehicle width direction, a step structure formed by the first bottom portion 21a and the second bottom portion 21b, and a bead extending in the vehicle front-rear direction. 21g and 21h structures are used to improve the rigidity of the bottom surface of the left tray 21.

  As shown in FIGS. 6 and 7, the right tray 22 is formed continuously with a first bottom portion 22 a that is in contact with and fixed to the top of the cross member 8, and a front portion of the first bottom portion 22 a. 2nd bottom part 22b in a position higher than 22a.

  The left and right side walls 22c and 22c rising upward from the left and right end portions of the first bottom portion 22a and the second bottom portion 22b are integrally formed, and horizontally extended from the upper end of the right side wall 22c in the vehicle width direction outward in the vehicle width direction. The pieces 22d and 22e are integrally formed, and a standing wall 22f is erected upward at the rear portion of the first bottom portion 22a and the left side in the vehicle width direction, and is horizontally inclined diagonally rearward from the upper end of the standing wall 22f. A rear wall 22h is integrally formed by bending downward from the rear end of the first bottom portion 22a.

  Further, the right tray 22 includes a vertical wall 22i extending upward from the front end of the second bottom portion 22b, a mounting piece 22j extending horizontally from the upper end of the vertical wall 22i to the front, and a front end of the mounting piece 22j. The front walls 22k and 22k extending upward from are integrally formed.

  The first bottom portion 22a described above is fixed to the upper portion of the cross member 8 using a plurality of bolts 26, and the mounting pieces 22d, 22e, 22g, 22j described above are set to the same height. A charger 50 below the electric unit E2 is fastened in the vertical direction using bolts 28 to the attachment portions 27 formed on the attachment pieces 22d, 22e, 22g, and 22j.

The front wall 22k of the right tray 22 has a wall shape located in front of the vehicle with respect to the front edge of the charger housing 51 and the front edge of the converter housing 61 in the vehicle plan view.
In this embodiment, the left tray 21 and the right tray 22 are configured using a rigid member, for example, an iron plate having a thickness of 2.5 mm, but the present invention is not limited to this.

As shown in FIG. 5, the casing 31 of the inverter 30 and the casing 41 of the junction box 40 that constitute one of the electrical units E1 and E2 are located on the lower side. However, the junction box housing 41 is stacked in the vertical direction so as to be positioned on the upper side.
That is, the inverter housing 31 is placed on the upper surface of the cross member 8 via the left tray 21, and the junction box housing 41 is placed on the upper surface of the inverter housing 31.

  Further, as shown in FIG. 2, the casing 51 of the charger 50 and the casing 61 of the DC-DC converter 60 constituting the other electric unit E2 are located on the lower side, The converter housing 61 is stacked and placed so as to be positioned on the upper side.

  As shown in FIGS. 5 and 8, the inverter casing 31 has a box shape having an upper surface portion 31a, a lower surface portion 31b, and an outer peripheral wall portion 31W including a front wall 31c, a rear wall 31d, and left and right side walls 31e, 31e. In addition to being formed, a partition wall 31 f for forming a space 33 communicating with the rear opening 32 is integrally formed.

  As shown in FIGS. 5 and 8, the inverter housing 31 includes a plurality of mounting seats 31g extending forward from the lower portion of the front wall 31c and a plurality of mounting seats 31h extending rearward from the lower portion of the rear wall 31d. As shown in FIG. 5, these mounting seats 31 g and 31 h are fastened and fixed to the second bottom portion 21 b and the third bottom portion 21 c of the left tray 21 using bolts 25.

  That is, the lower part of the outer peripheral wall 31W of the inverter casing 31 which is one of the inverter casing 31 and the junction box casing 41 is connected to the left tray 21 above the cross member 8 at a plurality of locations around the bolt 25 (first 1 volt) in the vertical direction.

  Further, as shown in FIG. 5, a through hole 31i for inserting the bus bar is formed in the upper surface portion 31a of the inverter housing 31 so as to communicate with the space portion 33 below the bus bar. As shown, the rear opening 32 is detachably covered with a lid member 29 using a bolt 34.

Furthermore, as shown in FIG. 1, the inverter housing 31 is integrally formed with a plurality of mounting seats 31 j that protrude outward from the upper portion of the inverter housing 31.
The inverter casing 31 is formed by aluminum die casting.

  As shown in FIG. 5, the junction box casing 41 is formed by aluminum die casting. The junction box casing 41 includes a box body 42 positioned on the upper side and a bottom plate portion 43 positioned on the lower side. Are fastened and integrated with a plurality of bolts 44.

As shown in FIG. 5, the box body 42 has an upper surface portion 42a and an outer peripheral wall portion 42W including a front wall 42b, a rear wall 42c, and left and right side walls 42d, and an upper opening 45, a lower opening 46, and a rear opening. 47 is provided.
The upper opening 45 described above is detachably covered with a lid member 49 using bolts 48, while the bottom plate portion 43 has a lower surface portion 43c, and the lower surface portion 43c has a through hole on the inverter housing 31 side. A through-hole 43a for inserting a bus bar that coincides with 31i is formed.

As shown in FIGS. 1 and 5, the above-described bottom plate portion 43 is integrally formed with a plurality of mounting seats 43 b projecting outward so as to correspond to the mounting seat 31 j on the inverter housing 31 side. The mounting seat 43b on the junction box housing 41 side is placed on the mounting seat 31j on the housing 31 side, and both the 31j and 43b are fastened with a plurality of bolts 35 in the vertical direction.
That is, the inverter casing 31 positioned on the lower side and the junction box casing 41 positioned on the upper side are fastened in the vertical direction with the bolts 35 (second bolts) at a plurality of locations where the outer peripheral wall portions 31W and 42W are respectively matched. It is a thing.

  As shown in FIG. 5, the bolt 35 that fastens the inverter casing 31 and the junction box casing 41 is thicker than the bolt 25 that fastens the inverter casing 31 to the left tray 21 and has a large shearing force. It is set to become. In this embodiment, an M10 bolt is used as the bolt 35 and an M8 bolt 25 is used, but the present invention is not limited to this.

  As shown in FIG. 5, the electrical distribution circuit in the junction box 40 and the inverter circuit in the inverter housing 31 are connected by a bus bar 36 (bus-bar) made of copper ingot. The bus bar 36 has a bottom plate portion. 43 and the space portion 33 are routed through the upper and lower through holes 43a and 31i for inserting the bus bars, and the outer periphery of the routing portion is covered with an insulating member 37.

  That is, the bus bar 36 that connects the inverter 30 and the electrical distribution circuit of the junction box 40 is disposed inside the outer peripheral wall portions 31W and 42W and penetrates the upper surface portion 31a and the lower surface portion 43c. Is.

  As shown in FIG. 5, in this embodiment, the junction box housing 41 is arranged such that the lower surface portion 43c of the junction box housing 41 matches the upper surface portion 31a of the inverter housing 31. The lower surface portion 43c of the body 41 is provided with the through hole 43a through which the bus bar 36 is inserted. The outer surface of the through hole 43a is the lower surface portion 43c of the junction box housing 41, more specifically, the through hole 43a. An O-ring or the like is provided between the lower surface portion of the projecting portion 43d formed to project downward so as to be flush with the bottom surface of the mounting seat 43b corresponding to the outer periphery and the upper surface portion 31a of the inverter housing 31. A seal member 39 is provided.

  This eliminates the need for a structure that seals all of the outer peripheral edge of the inverter casing 31 and the outer peripheral edge of the junction box casing 41 and prevents water from entering the bus bar 36, and simplifies the structure for preventing water immersion. It is comprised as follows.

  By the way, as shown in FIGS. 7 and 8, the casing 51 of the charger 50 is formed in a box shape having an upper wall, a lower wall 51b, a front wall 51c, a rear wall 51d, and left and right side walls 51e and 51e. A plurality of mounting seats 51f projecting outward from the lower portion of the charger housing 51 are integrally formed, and each of the mounting seats 51f is attached to each mounting piece 22d of the right tray 22 by using a bolt 28. , 22e, 22g, and 22j.

  As shown in FIGS. 1, 2, and 4, a plurality of mounting seats 51g projecting outward from the upper portion of the charger housing 51 are integrally formed, and bolts 52 are attached to the mounting seats 51g. In use, the plate 53 is attached.

  The plate 53 includes a plurality of lower mounting pieces 53a and a plurality of upper mounting pieces 53b. The lower mounting pieces 53a are fixed to the mounting seats 51g of the charger housing 51, and are attached to the upper mounting pieces 53b. The bolts 54 are used to fasten and fix a plurality of mounting seats 61 a that protrude outward from the converter housing 61 of the DC-DC converter 60.

As shown in a rear view in FIG. 4, the back surface portion of the casing 51 of the charger 50 and the back surface portion of the rear wall 22 h of the right tray 22 are connected to each other by a connecting member 55.
Of the inverter 30, the junction box 40, the charger 50, and the DC-DC converter 60 that constitute the electrical units E1 and E2, the inverter 30 and the DC-DC converter 60 are electrical components that require cooling with cooling water.

Therefore, as shown in FIG. 1 to FIG. 3, on the vehicle front side in the vehicle width direction outer side wall 31 e in the inverter casing 31, a water jacket (not shown) inside the inverter casing 31 is A pair of inlets / outlets 38 (cooling water inlet / outlet) for supplying and discharging the cooling water is provided.
Further, on the front side of the upper wall of the converter casing 61 of the DC-DC converter 60 described above, a pair of cooling water is supplied to and discharged from a water jacket (not shown) inside the converter casing 61. Entrances 62 and 63 (cooling water entrances and exits) are provided.

  As shown in FIGS. 3 and 4, the main battery, which is a power supply unit disposed at the rear of the vehicle, on the vehicle rear side of the junction box housing 41 in the junction box 40, more specifically, on the vehicle rear surface side and the vehicle width direction left side. A connection portion 70 (power supply cable connection portion) for power supply power cables 71 and 72 wired from the front (not shown) toward the front of the vehicle is provided.

As shown in FIGS. 3 and 4, the three-phase converted into three-phase alternating current by the inverter 30 on the vehicle rear side of the junction box housing 41 in the junction box 40, specifically, on the vehicle rear surface side and the vehicle width direction right side. A connection portion 76 for three-phase cables 73, 74, 75 for supplying AC power to the motor 16 below the cross member 8 is provided.
The motor 16 is fed from the junction box 40 with three-phase cables 73, 74, 75 as harnesses.

  As shown in FIG. 5, the upper end portion of the three-phase cable 73 is orthogonal to the connection portion 76, and a connection terminal 78 is provided at the tip of the cable body introduced into the junction box housing 41 via the seal member 77. The connecting terminal 78 is connected to the upper horizontal portion of the bus bar 36 using a bolt 79.

  As shown in FIGS. 4 and 5, the three-phase cables 73, 74, 75 are bent in a circular arc shape from the connecting portion 76 in a side view of the vehicle and suspended, and the motor housing 16 a of the motor 16 on the vehicle rear surface side. The connection part 80 is held at right angles to the connection part 80.

In other words, the above-described three-phase cables 73, 74, and 75 are smoothly curved and arranged in a circular arc shape from the upper three-phase cable connecting portion 76 to the connecting portion 80 for the lower motor 16 in a vehicle side view. The angle formed by the three-phase cable connecting portion 76 and the upper ends of the three-phase cables 73, 74, and 75 is set to 90 degrees, and the angle formed by the connecting portion 80 and the lower ends of the three-phase cables 73, 74, and 75 is also set. It is set to 90 degrees.
The connecting portion 80 on the back side of the motor housing 16a and the three-phase cable connecting portion 76 on the back side of the junction box housing 40 are provided at substantially corresponding positions in the vertical direction.

In FIG. 5, only one of three sets of three-phase cables 73, 74, 75 is shown, but the structure of each element 78, 79, 36, 37, 43a, 31i is also shown for the remaining two. 5 is formed, and the structure related to each element 78, 79, 36, 37, 43a, 31i on the upper end side of the pair of power cables 71, 72 is formed in the same manner as in FIG. ing.
1 to 4, 90 is a drive shaft, and in FIG. 3, 91 is a lower mount bracket of the motor unit 15. In the figure, arrow F indicates the front of the vehicle, and arrow R indicates the rear of the vehicle.

  As described above, the electrically driven vehicle structure of the above embodiment is provided with the left and right front side frames 2 and 2 extending in the vehicle front-rear direction on the left and right sides in the motor room 1 disposed in the front of the vehicle. A cross member 8 extending in the vehicle width direction is bridged between the side frames 2 and 2, and an inverter 30 that boosts and outputs input electricity and an electric distribution circuit including a relay are accommodated on the cross member 8. The vehicle driving motor 16 is mounted on the lower side of the cross member 8 and is fed from the junction box 40 with a harness (see three-phase cables 73, 74, 75). In the suspended electric drive vehicle structure, the casing 31 of the inverter 30 is placed on the upper surface of the cross member 8, and the invar A housing 41 of the junction box 40 is placed on the upper surface of the housing 31 of the 30, and a cooling water inlet / outlet port 38 is provided on the vehicle front side of the inverter housing 31. A connecting portion 76 for three-phase cables 73, 74, 75 is provided on the side, and the three-phase cables 73, 74, 75 are bent from the connecting portion 76 in a circular arc shape when viewed from the side of the vehicle and hang down. It is connected to the drive motor 16 (see FIGS. 3 to 5).

  According to this configuration, the inverter housing 31 that requires cooling and is provided with the cooling water inlet / outlet port 38 is placed on the lower side of the junction box housing 41, and the connection portion 76 of the three-phase cables 73, 74, 75 is provided. The provided junction box housing 41 is placed on the upper side of the inverter housing 31, the cooling water inlet / outlet port 38 is provided on the vehicle front side, and the connection portions 76 of the three-phase cables 73, 74, 75 are on the vehicle rear side. Since the inverter casing 31 and the junction box casing 41 are retracted at the time of a vehicle collision, the cooling water leaked from the damaged cooling water pipes is damaged by the damaged three-phase cables 73, 74, 75 and their connecting portions 76. It is possible to suppress a short circuit due to.

Further, the above-described three-phase cables 73, 74, 75 are bent and suspended in an arc shape from the connection portion 76 of the junction box casing 41 located above the casings 31, 41 in a side view of the vehicle. Since it is connected to the vehicle drive motor 16, the three-phase cables 73, 74, and 75 having rigidity are routed gently by extending the vertical separation distance between the junction box housing 41 and the motor 16. be able to.
If the vertical separation distance between the junction box housing and the motor is short, the amount of the three-phase cables 73, 74, 75 projecting rearward from the housing rear surface and the motor 16 rear surface can be shortened. it can.

  As long as the three-phase cables 73, 74, 75 are arranged to reduce the amount of rearward extension, each element 8, 16, 17, 30, 40, 50, 60 is placed in the motor room 1 as far as possible in the rear of the vehicle. The yaw penetrability moment can be reduced.

In one embodiment of the invention, the junction box on a vehicle rear side of the housing 41, the power cables 71 and 72 is routed toward the power supply unit placed on the vehicle rear (see main battery) ahead of the vehicle Is provided with a power cable connecting portion 70 (see FIGS. 3 and 4).

  According to this configuration, not only the three-phase cable connecting portion 76 but also the power cable connecting portion 70 can be prevented from getting wet with the cooling water.

In the correspondence between the configuration of the present invention and the above-described embodiment,
The harness for supplying power to the vehicle drive motor 16 of the present invention corresponds to the three-phase cables 73, 74, 75 of the embodiment.
The present invention is not limited to the configuration of the above-described embodiment.

  As described above, the present invention provides the left and right front side frames extending in the vehicle front-rear direction on the left and right sides in the motor room disposed at the front of the vehicle, and in the vehicle width direction between the left and right front side frames. An extending cross member is spanned, and an inverter that boosts and outputs input electricity and a junction box that houses an electric distribution circuit including a relay are stacked on top of the cross member, This is useful for an electrically driven vehicle structure in which a vehicle driving motor powered by a harness from the junction box is suspended below the cross member.

DESCRIPTION OF SYMBOLS 1 ... Motor room 2 ... Front side frame 8 ... Cross member 16 ... Motor 30 ... Inverter 31 ... Inverter case 38 ... Entrance / exit (cooling water entrance / exit)
40 ... Junction box 41 ... Junction box housing 70 ... Power cable connection 71, 72 ... Power cable 73, 74, 75 ... Three-phase cable (harness)
76 ... Three-phase cable connection

Claims (2)

Provide left and right front side frames that extend in the vehicle front-rear direction on the left and right sides in the motor room arranged in the front of the vehicle,
A cross member extending in the vehicle width direction is bridged between the left and right front side frames,
On the upper part of the cross member, an inverter that boosts and outputs input electricity and a junction box that houses an electric distribution circuit including a relay are stacked in an up and down direction,
An electric drive vehicle structure in which a vehicle drive motor powered by a harness from the junction box is suspended below the cross member,
The casing of the inverter is placed on the upper surface of the cross member,
The junction box casing is placed on the upper surface of the inverter casing,
A cooling water doorway is provided on the vehicle front side of the inverter housing,
On the vehicle rear side of the junction box housing, the harness connecting portion is provided,
The electric drive vehicle structure according to claim 1, wherein the harness is bent in a circular arc shape when viewed from the side of the vehicle and is suspended from the connection portion and connected to the vehicle drive motor. Claims, characterized the rear side of the vehicle of the junction box housing, the power cable connection portion for connecting the wired power cables toward the power supply unit placed on the vehicle rear to the vehicle front is provided The electric drive vehicle structure according to claim 1.

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