JP2021003933A - Protective structure of vehicular electric instrument - Google Patents

Abstract

To provide a protective structure of a vehicular electric instrument that can relax impact applied to the vehicular electric instrument from an on-vehicle member at the time of a collision of the vehicle so as to protect the vehicular electric instrument.SOLUTION: The protective structure of a vehicular electric instrument comprises: a first electric instrument 22 arranged above a front-side member 12 and an auxiliary member 14, behind a radiator 16; and a second electric instrument 23 arranged above the first electric instrument 22 through a bracket 24 to oppose in a vertical direction to the first electric instrument 22. The bracket 24 opposes in a longitudinal direction to the radiator 16 and has a peripheral wall part 36 having a front wall part 37 extending to the radiator 16. The front wall part 37 has a protruding part 37I protruding forward from the front wall part 37 more than lower mounting parts 37A and 37B and upper mounting parts 37E and 37F.SELECTED DRAWING: Figure 3

Description

The present invention relates to a protective structure for electrical equipment for vehicles.

There is known a shock absorbing structure in a motor room that prevents hard parts installed in the motor room from moving backward and interfering with the dash panel (see Patent Document 1).

This shock absorbing structure in the motor room includes a motor for driving the vehicle housed in the motor room at the front of the vehicle, and a radiator installed in front of the motor room with respect to the motor.

An air compressor is attached to the motor as a hard component, and a component mounting frame that supports a power converter (inverter) installed above the motor is connected to a side member.

The shock absorbing structure in the motor room can efficiently transmit this shock to the side members while absorbing the shock by interfering with the parts mounting frame located behind the hard parts in the event of a frontal collision of the vehicle, and to the motor room. It is possible to prevent the installed hard parts from moving backward.

Japanese Unexamined Patent Publication No. 2006-21920

However, in the conventional shock absorbing structure in the motor room, if the radiator moves backward at the time of a frontal collision of the vehicle, it strongly interferes with the power conversion device installed above the motor after the radiator comes into contact with a hard part. There is a risk that the power converter cannot be protected.

The present invention has been made by paying attention to the above circumstances, and is a protective structure for an electric device for a vehicle that can alleviate an impact applied to an electric device for a vehicle from an in-vehicle member at the time of a vehicle collision and can protect the electric device for the vehicle. Is intended to provide.

The present invention includes an in-vehicle member installed in the motor room at the front of the vehicle, a frame member installed in the motor room behind the in-vehicle member and extending in the width direction of the vehicle, and a motor and a drive device connected to the motor. It is a protective structure for electric equipment for vehicles installed in a vehicle having a power train supported by a frame member, and the electric equipment for vehicles is installed on the upper part of the frame member behind the in-vehicle member. It has a first electric device and a second electric device which is installed on the upper part of the first electric device via a bracket and is arranged vertically with the first electric device, and the bracket is in the front-rear direction of the vehicle. A peripheral wall portion having a front wall portion that faces the in-vehicle member and extends in the width direction of the vehicle, a lower mounting portion that is provided at the lower part of the peripheral wall portion and to which the first electric device is mounted, and an upper portion of the peripheral wall portion. The front wall portion has a protruding portion that protrudes forward from the front wall portion toward the vehicle-mounted member, and the protruding portion has a lower mounting portion. It is characterized in that it protrudes forward from the upper mounting portion.

As described above, according to the present invention, it is possible to alleviate the impact applied to the vehicle electric device from the vehicle-mounted member at the time of a vehicle collision, and to protect the vehicle electric device.

FIG. 1 is a plan view of the front part of a vehicle in which an electric vehicle vehicle according to an embodiment of the present invention is installed. FIG. 2 is a left side view of a motor room in which an electric vehicle vehicle according to an embodiment of the present invention is installed. FIG. 3 is a view from the right side of the motor room in which the electric device for the vehicle according to the embodiment of the present invention is installed, and shows the behavior of the radiator at the time of a vehicle front collision. FIG. 4 is a view from above of a motor room in which an electric vehicle vehicle according to an embodiment of the present invention is installed. FIG. 5 is a front view of a motor room in which an electric vehicle vehicle according to an embodiment of the present invention is installed. FIG. 6 is an exploded perspective view of the vehicle electric device and the bracket according to the embodiment of the present invention. FIG. 7 is a perspective view of a bracket of an electric vehicle device according to an embodiment of the present invention. FIG. 8 is a bottom view of a bracket of an electric vehicle device according to an embodiment of the present invention. FIG. 9 is a front view of a bracket of an electric vehicle device according to an embodiment of the present invention. FIG. 10 is a left side view of a bracket of an electric vehicle device according to an embodiment of the present invention. FIG. 11 is a right side view of a bracket of an electric vehicle device according to an embodiment of the present invention.

The protective structure for an electric device for a vehicle according to an embodiment of the present invention is installed in an in-vehicle member installed in a motor room at the front of the vehicle and in the motor room behind the in-vehicle member, and extends in the width direction of the vehicle. A protective structure for electrical equipment for a vehicle installed in a vehicle having a frame member and a motor and a drive device connected to the motor and a power train supported by the frame member. , A first electric device installed on the upper part of the frame member behind the in-vehicle member, and a second electric device installed on the upper part of the first electric device via a bracket and aligned vertically with the first electric device. The bracket is provided with a peripheral wall portion having a front wall portion that faces the in-vehicle member in the front-rear direction of the vehicle and extends in the width direction of the vehicle, and a bracket provided below the peripheral wall portion. It has a lower mounting portion to be mounted and an upper mounting portion provided above the peripheral wall portion to which the second electric device is mounted, and the front wall portion projects forward from the front wall portion toward the in-vehicle member. It has a protruding portion, and the protruding portion protrudes forward from the lower mounting portion and the upper mounting portion.

As a result, the protective structure for the vehicle electric device according to the embodiment of the present invention can alleviate the impact applied to the vehicle electric device from the vehicle-mounted member at the time of a vehicle collision, and can protect the vehicle electric device.

Hereinafter, the protective structure of the electric device for a vehicle according to an embodiment of the present invention will be described with reference to the drawings.
1 to 11 are views showing a protective structure for an electric vehicle device according to an embodiment of the present invention. In FIGS. 1 to 11, the vertical, front, rear, and horizontal directions are such that the width direction of the vehicle is the horizontal direction and the height of the vehicle is the height of the vehicle when the traveling direction of the vehicle equipped with the vehicle electrical equipment is the front and the backward direction is the rear. The vertical direction is the vertical direction.

First, the configuration will be described.
In FIG. 1, the vehicle 1 has a left side member 2L, a right side member 2R, an upper member 2F, a front bumper 3, a dash panel 4, a left side panel 5L, a right side panel 5R, and a hood 6 (see FIGS. 2 and 3). I have.

The left side member 2L and the right side member 2R are separated from each other in the width direction (left-right direction) of the vehicle 1 and extend in the front-rear direction of the vehicle 1. Hereinafter, the width direction of the vehicle 1 is referred to as a vehicle width direction. The upper member 2F extends in the vehicle width direction, and the left end portion and the right end portion are connected to the left side member 2L and the right side member 2R.

The front bumper 3 is installed at the front end of the vehicle 1. The dash panel 4 is installed behind the front bumper 3, and divides the vehicle 1 into a motor room 1A on the front side and a vehicle room 1B behind the motor room 1A.

The left side panel 5L and the right side panel 5R are installed on both the left and right sides of the vehicle 1. The front space of the vehicle 1 surrounded by the front bumper 3, the dash panel 4, the left side panel 5L, the right side panel 5R, and the hood 6 constitutes the motor room 1A. The hood 6 covers the motor room 1A from above and can open and close the motor room 1A.

As shown in FIGS. 2 and 3, an opening (front grill) 3a is formed in the front bumper 3, and when the vehicle 1 is traveling, a traveling wind is blown from the front of the vehicle 1 through the opening 3a into the motor room 1A. Incorporated.

A power train 7 is installed in the motor room 1A. The power train 7 includes a motor 8 and a drive device 9 connected to the left end of the motor 8 in the vehicle width direction.

The motor 8 constitutes a drive source for traveling of the vehicle 1. The drive device 9 is, for example, via an input shaft (not shown), an output shaft, a plurality of gear sets for transmitting power from the input shaft to the output shaft, and a drive shaft (not shown) for transmitting power to the output shaft. It is configured to include a differential device that transmits to drive wheels (not shown).

As shown in FIG. 1, the subframe 11 is connected to the left side side member 2L and the right side side member 2R via the left side support member 10L and the right side support member 10R.

The subframe 11 includes a front member 12, a rear member 13 installed behind the front member 12, and an auxiliary member 14 installed behind the rear member 13.

The front member 12 and the rear member 13 extend in the vehicle width direction, and the auxiliary member 14 is curved rearward from the rear member 13 in a substantially U-shape. The subframe 11 of this embodiment constitutes the frame member of the present invention.

A left side mount member 15L having a mount rubber 15a (see FIG. 2) is connected to the lower surface of the left end portion of the front side member 12 and the rear side member 13 in the vehicle width direction, and the left side mount member 15L is connected to the drive device 9. Has been done.

A right side mount member 15R having a mount rubber 15b (see FIG. 3) is connected to the lower surface of the right end portion of the front side member 12 and the rear side member 13 in the vehicle width direction, and the right side mount member 15R is connected to the motor 8. ing.

A rear mount member 15B having a mount rubber 15c (see FIGS. 2 and 3) is connected to the lower surface of the auxiliary member 14, and the rear mount member 15B is connected to the rear portion of the drive device 9.

That is, the power train 7 is elastically supported by the subframe 11 by the left side mount member 15L, the right side mount member 15R, and the rear side mount member 15B so as to be suspended from the subframe 11.

In FIGS. 1 and 4, the radiator 16 is installed in the motor room 1A, and the subframe 11 and the power train 7 are installed behind the radiator 16 in the motor room 1A.

In FIGS. 2 and 3, the radiator 16 includes an upper tank 16A, a lower tank 16C installed below the upper tank 16A, and a radiator core 16B connecting the upper tank 16A and the lower tank 16C.

The upper tank 16A is supported by the upper member 2F, and the lower tank 16C is supported by a lower member (not shown) installed below the upper member 2F. That is, the radiator 16 is supported so as to be sandwiched from above and below by the upper member 2F and the lower member.

In FIG. 2, the downstream end of the motor outlet pipe 17 is connected to the upper tank 16A, and the upstream end of the motor outlet pipe 17 is connected to the motor 8. The cooling water that has cooled the motor 8 is introduced into the upper tank 16A through the motor outlet pipe 17. Here, upstream and downstream refer to upstream and downstream with respect to the direction in which the cooling water flows.

The radiator core 16B is configured by alternately stacking flat water tubes (not shown). The radiator core 16B cools the cooling water by exchanging heat between the cooling water flowing through the water tube from the upper tank 16A and the outside air, and introduces the cooled cooling water into the lower tank 16C.

The upstream end of the radiator outlet pipe 18 is connected to the lower tank 16C, and the downstream end of the radiator outlet pipe 18 is connected to the electric water pump 19. The cooling water cooled by the radiator core 16B is sucked from the lower tank 16C into the electric water pump 19 through the radiator outlet pipe 18. The radiator 16 of this embodiment constitutes an in-vehicle member of the present invention.

A fan shroud 20 is attached to the rear portion of the radiator 16. As shown in FIG. 5, the fan shroud 20 has a cooling fan 21, a cylindrical portion 20A surrounding the cooling fan 21, and a motor (not shown) that rotationally drives the cooling fan 21.

By rotating the cooling fan 21, the fan shroud 20 draws the traveling wind introduced into the motor room 1A from the front of the vehicle 1 through the opening 3a of the front bumper 3 into the radiator 16.

The air that has been heat-exchanged with the cooling water flowing through the radiator 16 flows backward by the cooling fan 21.

In FIGS. 2 and 3, the subframe 11 is installed behind the fan shroud 20, and both ends in the vehicle width direction are the left side member 2L and the right side member via the left side support member 10L and the right side support member 10R, respectively. It is connected to 2R (see FIG. 1).

As shown in FIG. 3, a first electric device 22 and a second electric device 23 are attached to the upper side of the front member 12 and the rear member 13. The first electric device 22 and the second electric device 23 of the present embodiment constitute the vehicle electric device of the present invention.

The first electric device 22 is composed of a battery module and a DCDC converter, and is installed on the upper surfaces of the front member 12 and the rear member 13.

The second electric device 23 is composed of an inverter. The second electric device 23 is installed above the first electric device 22, and is connected to the first electric device 22 by a bracket 24.

That is, the second electric device 23 is installed on the upper part of the first electric device 22 via the bracket 24, and the first electric device 22 and the second electric device 23 are moved up and down via the bracket 24. Lined up in the direction. In other words, the first electric device 22 and the second electric device 23 face each other in the vertical direction via the bracket 24.

The second electric device 23, which is installed above the first electric device 22, is installed above the radiator 16.

The downstream end of the inverter inlet pipe 26 (see FIG. 2) is connected to the second electric device 23, and the upstream end of the inverter inlet pipe 26 is connected to the electric water pump 19.

The cooling water cooled by the radiator 16 and discharged from the electric water pump 19 is introduced into the second electric device 23 by the inverter inlet pipe 26. As a result, the second electric device 23 is cooled by the cooling water.

The second electric device 23 and the first electric device 22 are connected by a first intermediate pipe (not shown), and the cooling water that cools the second electric device 23 is the first by the first intermediate pipe. It is supplied to the electric device 22. As a result, the first electric device 22 is cooled by the cooling water.

The first electric device 22 and the motor 8 are connected by a second intermediate pipe (not shown), and the cooling water that cools the first electric device 22 is supplied to the motor 8 by the second intermediate pipe. As a result, the motor 8 is cooled by the cooling water.

In FIG. 4, a third electric device 25 is installed on the upper surfaces of the front member 12, the rear member 13, and the auxiliary member 14, and the third electric device 25 is composed of a junction box. The third electric device 25 of this embodiment constitutes the vehicle electric device of the present invention.

In FIG. 2, a terminal 23A is provided on the left side surface 23a of the second electric device 23 in the vehicle width direction. As shown in FIG. 4, the third electric device 25 is adjacent to the first electric device 22 in the vehicle width direction on the left side surface 23a side of the second electric device 23.

As shown in FIG. 2, one end of the cable 31 is connected to the terminal 23A of the second electric device 23, and the other end of the cable 31 is connected to the motor 8. The cable 31 is composed of a U-phase cable, a V-phase cable, and a W-phase cable. The left side surface 23a of the second electric device 23 of the present embodiment in the vehicle width direction constitutes the side surface of the second electric device of the present invention in the vehicle width direction.

A terminal 23B is provided on the left side surface 23a of the second electric device 23, and one end of the cable 32 is connected to the terminal 23B. A terminal 25A is provided on the left side surface 25a of the third electric device 25, and the other end of the cable 32 is connected to the terminal 25A.

A tubular holding portion 33 is attached to the left side surface 25a of the third electric device 25. The cable 32 is inserted into the holding portion 33 and supported by the holding portion 33. The left side surface 25a of the third electric device 25 of the present embodiment constitutes a side surface of the third electric device of the present invention in the vehicle width direction.

In the left side view in the vehicle width direction shown in FIG. 2, the holding portion 33 is installed on the rear side of the terminal 23A. Specifically, the front end 33f of the holding portion 33 is located rearward of the front end 23f of the terminal 23A, and the rear end 33r of the holding portion 33 is located rearward of the rear end 23r of the terminal 23A. doing. The front end 33f of the holding portion 33 may be located behind the rear end 23r of the terminal 23A.

The battery module of the first electric device 22 and the DCDC converter are connected to the third electric device 25 by a cable (not shown).

The DCDC converter of the first electric device 22 transforms the output voltage of the battery module of the first electric device 22, and outputs the transformed voltage from the third electric device 25 to the second electric device 23.

The second electric device 23 rotationally drives the motor 8 by converting the current output from the first electric device 22 from direct current to alternating current and supplying it to the motor 8.

In FIG. 6, the bracket 24 has a bottom wall portion 35 and a peripheral wall portion 36. The peripheral wall portion 36 has a front wall portion 37, a rear wall portion 38, a left side wall portion 39, and a right side wall portion 40.

As shown in FIG. 5, the bottom wall portion 35 faces the first electric device 22 in the vertical direction and has an opening 35a inward (see FIG. 8). The upper surface of the first electrical device 22 is exposed to the running wind through the opening 35a.

As shown in FIG. 6, a bracket 45 is attached to the bottom wall portion 35. The bracket 45 covers the first electric device 22 from above, and prevents the heat of the second electric device 23 from being transferred to the first electric device 22.

In FIG. 7, the front wall portion 37, the rear wall portion 38, the left side wall portion 39, and the right side wall portion 40 extend upward from the outer peripheral edge of the bottom wall portion 35, and the front wall portion 37, the rear wall portion 38, and the left side. An opening 41 is formed on the upper surfaces of the wall portion 39 and the right side wall portion 40.

The lower surface of the second electrical device 23 is exposed to the running wind through the opening 41. As shown in FIG. 5, the front wall portion 37 faces the radiator 16 in the front-rear direction and extends in the vehicle width direction.

As shown in FIGS. 7 and 8, the rear wall portion 38 is located behind the front wall portion 37, faces the front wall portion 37 in the front-rear direction, and extends in the vehicle width direction. The left side wall portion 39 connects the left end portion of the front wall portion 37 in the vehicle width direction and the left end portion of the rear wall portion 38 in the vehicle width direction, and extends in the front-rear direction.

The right side wall portion 40 connects the right end portion of the front wall portion 37 in the vehicle width direction and the right end portion of the rear wall portion 38 in the vehicle width direction, and extends in the front-rear direction. The left side wall portion 39 and the right side wall portion 40 of the present embodiment constitute the side wall portion of the present invention.

Lower mounting portions 37A and 37B are provided on both sides of the lower portion of the front wall portion 37 in the vehicle width direction, and the lower mounting portions 37A and 37B project outward from the front wall portion 37 in the vehicle width direction. .. Through holes 37a and 37b penetrating in the vertical direction are formed in the lower mounting portions 37A and 37B.

Lower mounting portions 37C and 37D are provided on both sides of the lower portion of the rear wall portion 38 in the vehicle width direction, and the lower mounting portions 37C and 37D project outward from the rear wall portion 38 in the vehicle width direction. .. Through holes 37c and 37d penetrating in the vertical direction are formed in the lower mounting portions 37C and 37D.

As shown in FIG. 6, upper mounting portions 22B are provided at the upper four corners of the first electric device 22, respectively, and the upper mounting portion 22B is outward from the first electric device 22 in the vehicle width direction. It protrudes into. A through hole 22b that penetrates in the vertical direction is formed in the upper mounting portion 22B.

When the first electric device 22 is attached to the bracket 24, the upper mounting portion of the first electric device 22 is passed through the through holes 37a, 37b, 37c, 37d of the lower mounting portions 37A, 37B, 37C, 37D of the bracket 24. Bolt 34A is attached to the through hole 22b of 22B.

The bolt 34A may be fastened to a nut (not shown), or a thread groove may be formed on the inner peripheral surface of the through hole 22b and the bolt 34A may be fastened to the thread groove.

Four lower mounting portions 22C are provided in the lower portion of the first electric device 22 (two in FIG. 6). The first electrical device 22 is attached to the front member 12 and the rear member 13 by fastening the lower attachment portion 22C to the front member 12 and the rear member 13 with bolts (not shown).

As shown in FIGS. 7 and 8, upper mounting portions 37E and 37F are provided on both sides of the upper portion of the front wall portion 37 in the vehicle width direction, and the upper mounting portions 37E and 37F are on the front side from the front wall portion 37. It protrudes into. Through holes 37e and 37f penetrating in the vertical direction are formed in the upper mounting portions 37E and 37F.

Upper mounting portions 37G and 37H are provided on both sides of the upper portion of the rear wall portion 38 in the vehicle width direction, and the upper mounting portions 37G and 37H project rearward from the rear wall portion 38. Through holes 37g and 37h penetrating in the vertical direction are formed in the upper mounting portions 37G and 37H.

As shown in FIG. 8, the distance L1 from the wall surface 38w of the rear wall portion 38 to the through holes 37g and 37h is formed longer than the distance L2 from the wall surface 37w of the front wall portion 37 to the through holes 37e and 37f. ..

In FIG. 6, lower mounting portions 23C are provided at the lower four corners of the second electric device 23 (three in the figure), and the lower mounting portions 23C are outward from the second electrical device 23. It protrudes into. A through hole 23c that penetrates in the vertical direction is formed in the lower mounting portion 23C.

When the second electric device 23 is attached to the bracket 24, the through holes 37e of the upper mounting portions 37E, 37F, 37G, 37H of the bracket 24 are passed through the through hole 23c of the lower mounting portion 23C of the second electric device 23. Bolts 34B are attached to 37f, 37g, and 37h.

The bolt 34B may be fastened to a nut (not shown), or a screw groove may be formed on the inner peripheral surfaces of the through holes 37e, 37f, 37g, and 37h, and the bolt 34B may be fastened to the screw groove. The bolt 34B of this embodiment constitutes the fastener of the present invention.

In this way, the second electric device 23 is attached to the first electric device 22 via the bracket 24, and the first electric device 22 and the second electric device 23 are in the vertical direction behind the radiator 16. It is installed side by side in.

The lower mounting portions 37A and 37B of the present embodiment constitute the first lower mounting portion of the present invention, and the upper mounting portions 37E and 37F constitute the first upper mounting portion of the present invention and are mounted on the upper side. The portions 37G and 37H form the second upper mounting portion of the present invention. The through holes 37e and 37f form the first through hole of the present invention, and the through holes 37g and 37h form the second through hole of the present invention.

As shown in FIG. 6, the front wall portion 37, the rear wall portion 38, the left side wall portion 39, and the right side wall portion 40 have an upper outer peripheral edge 22a of the first electric device 22 and a lower outer peripheral edge of the second electric device 23. It is formed along 23b, and a space is formed between the first electric device 22, the second electric device 23, and the peripheral wall portion 36.

In FIGS. 7 to 9, a protruding portion 37I is provided at the left end portion of the front wall portion 37. The protruding portion 37I protrudes forward from the front wall portion 37 (see FIG. 3), and protrudes forward of the lower mounting portions 37A and 37B and the upper mounting portions 37E and 37F, that is, toward the radiator 16.

As shown in FIGS. 7 and 9, the upper mounting portion 37E located on the left side of the front wall portion 37 has a bulging portion 37J that bulges forward from the wall surface 37w of the front wall portion 37 and extends in the vertical direction. A seating surface 37m is provided on the upper surface of the bulging portion 37J, and the lower mounting portion 23C provided on the lower left portion of the second electric device 23 is in contact with the seating surface 37m. That is, the seat surface 37 m constitutes a seat surface for mounting the second electric device 23.

The lower portion of the bulging portion 37J in the extending direction is connected to the protruding portion 37I, and the protruding portion 37I is provided side by side with the seat surface 37 m in the vertical direction. A rib 37L is integrally provided on the bulging portion 37J, and the rib 37L projects forward from the bulging portion 37J and extends in the vertical direction.

The upper mounting portion 37F located on the right side of the front wall portion 37 has a bulging portion 37K that bulges forward from the wall surface 37w of the front wall portion 37 and extends in the vertical direction. A seat surface 37n is provided on the upper surface of the bulging portion 37K, and the lower mounting portion 23C provided on the lower right portion of the second electric device 23 is in contact with the seat surface 37n. That is, the seat surface 37n constitutes a seat surface for mounting the second electric device 23.

In FIG. 4, the protruding portion 37I is installed at the left end portion of the front wall portion 37 on the third electric device 25 side, and the protruding portion 37I and the third electric device 25 face the radiator 16 in the front-rear direction. ing.

As shown in FIG. 2, the third electric device 25 has a high portion 25B on the rear side and a low portion 25C located on the front side of the high portion 25B and having a height lower than that of the high portion 25B.

As shown in FIGS. 4 and 5, the front end 25f of the lower portion 25C, that is, the front end 25f of the third electric device 25 is installed behind the front end 37i of the protrusion 37I and below the protrusion 37I. Has been done.

In FIG. 3, the front end of the subframe 11, that is, the front end 12f of the front member 12, is located in front of the protrusion 37I, the first electric device 22, the second electric device 23, and the third electric device 25. ing.

In the height direction of the vehicle 1, the front member 12 is installed above the central portion O in the height direction of the radiator 16 and below the upper tank 16A.

In FIGS. 7 and 10, a trapezoidal notch 39a is formed in the left wall portion 39, and the notch 39a is notched downward from the upper end of the left wall portion 39.

In FIG. 10, the left side wall portion 39 has a front side wall portion 39A located on the front side and a rear side wall portion 39B located on the rear side of the notch 39a, and has a length in the front-rear direction of the lower end of the front side wall portion 39A. L3 is formed shorter than the length L4 of the lower end of the rear side wall portion 39B in the front-rear direction.

In FIGS. 7 and 11, a trapezoidal notch 40a is formed in the right side wall portion 40, and the notch 40a is cut out downward from the upper end of the right side wall portion 40.

In FIG. 11, the right side wall portion 40 has a front side wall portion 40A located on the front side and a rear side wall portion 40B located on the rear side of the notch 40a, and has a length in the front-rear direction of the lower end of the front side wall portion 40A. L5 is formed shorter than the length L6 of the lower end of the rear side wall portion 40B in the front-rear direction.

In FIG. 7, a trapezoidal notch 38a is formed in the rear wall portion 38, and the notch 38a is notched downward from the upper end of the rear wall portion 38.

In FIG. 8, a fragile portion 37s is formed on the lower surface of the upper mounting portion 37F, and the fragile portion 37s is formed in a groove shape.

A fragile portion 37t is formed on the upper mounting portion 37G. The fragile portion 37t is formed at the base of the upper mounting portion 37G on the rear wall portion 38 side, that is, between the through hole 37g and the rear wall portion 38 in the front-rear direction, and is formed in a groove shape extending in the vehicle width direction. There is.

A fragile portion 37u is formed on the upper mounting portion 37H. The fragile portion 37u is formed at the base of the upper mounting portion 37H on the rear wall portion 38 side, that is, between the through hole 37h and the rear wall portion 38 in the front-rear direction, and is formed in a groove shape extending in the vehicle width direction. There is.

Next, the action will be described.
In FIG. 1, when an impact load F is applied to the vehicle 1 from the front at the time of a front collision of the vehicle 1, the front bumper 3 moves to the rear. Since the radiator 16 is installed in the front portion of the motor room 1A, the front bumper 3 collides with the radiator 16 as the front bumper 3 moves rearward, and the radiator 16 moves rearward.

Since the first electric device 22 and the second electric device 23 are installed in the motor room 1A, the radiator 16 moving rearward may strongly interfere with the first electric device 22 and the second electric device 23. There is.

According to the protective structure of the vehicle electric device of this embodiment, the first electric device 22 installed above the front member 12 and the auxiliary member 14 behind the radiator 16 and the upper part of the first electric device 22. It is installed via a bracket 24 and has a first electrical device 22 and a second electrical device 23 that faces vertically.

The bracket 24 is provided on a peripheral wall portion 36 having a front wall portion 37 that faces the radiator 16 in the front-rear direction and extends in the vehicle width direction, and a lower side provided below the peripheral wall portion 36 to which the first electric device 22 is attached. It has mounting portions 37A, 37B, 37C, 37D, and upper mounting portions 37E, 37F, 37G, 37H provided on the upper portion of the peripheral wall portion 36 to which the second electric device 23 is mounted.

The front wall portion 37 has a protruding portion 37I protruding forward from the front wall portion 37, and the protruding portion 37I protrudes toward the radiator 16 side from the lower mounting portions 37A and 37B and the upper mounting portions 37E and 37F. ..

Further, the front end 12f of the front member 12 is located on the front side of the protruding portion 37I, and the front member 12 is above the central portion O of the radiator 16 in the height direction in the height direction of the vehicle 1 and It is installed below the upper tank 16A.

As a result, when the radiator 16 moves rearward, as shown by the virtual line in FIG. 3, the radiator 16 collides with the front member 12, and the upper part of the radiator 16 collapses rearward with the front member 12 as a fulcrum.

Since the protruding portion 37I protrudes toward the radiator 16 from the lower mounting portions 37A and 37B and the upper mounting portions 37E and 37F, when the radiator 16 falls backward, the radiator 16 becomes the first electric device 22 and the second. Contact the protrusion 37I before colliding with the electric device 23 of the above.

Further, since the first electric device 22 and the second electric device 23 are installed so as to face each other in the vertical direction with the bracket 24 interposed therebetween, when the radiator 16 collides with the protruding portion 37I, the impact load F is applied. It can be distributed from the front wall portion 37 of the bracket 24 to the first electric device 22 and the second electric device 23.

Therefore, it is possible to prevent the radiator 16 from strongly interfering with the first electric device 22 and the second electric device 23, and it is possible to alleviate the impact applied from the radiator 16 to the first electric device 22 and the second electric device 23. .. As a result, the first electric device 22 and the second electric device 23 can be protected from the radiator 16.

Further, according to the protective structure of the electric device for a vehicle of this embodiment, the upper mounting portion 37E and the protruding portion 37I are connected to each other. Since the upper mounting portion 37E is mounted to the second electric device 23 by the bolt 34B, the rigidity of the upper mounting portion 37E is high.

Therefore, by connecting the highly rigid upper mounting portion 37E and the protruding portion 37I, the protruding portion 37I can be reinforced by the upper mounting portion 37E, and the rigidity of the protruding portion 37I can be increased.

Therefore, when the radiator 16 collides with the protrusion 37I, the protrusion 37I can withstand a high contact load, and the impact applied from the radiator 16 to the first electric device 22 and the second electric device 23 is more effective. Can be relaxed. As a result, the first electrical device 22 and the second electrical device 23 can be more effectively protected from the radiator 16.

Further, according to the protective structure of the electric device for vehicles of the present embodiment, the upper mounting portion 37E bulges forward from the wall surface 37w of the front wall portion 37 and extends in the vertical direction, and the lower portion in the extending direction becomes the protruding portion 37I. It has a connected bulging portion 37J and a seat surface 37m provided on the upper surface of the bulging portion 37J and in contact with the second electric device 23. In addition to this, the protruding portion 37I is provided side by side with the seat surface 37 m in the vertical direction.

As a result, the protruding portion 37I can be brought close to the upper mounting portion 37E and formed at a high position of the front wall portion 37, and the impact load F when the upper side of the radiator 16 falls backward can be received at a high position.

Further, since the bulging portion 37J of the upper mounting portion 37E protrudes forward from the wall surface 37w of the front wall portion 37, the rigidity of the upper mounting portion 37E can be further increased. Therefore, the protruding portion 37I can be reinforced by the protruding portion 37J having higher rigidity, and the rigidity of the protruding portion 37I can be increased more effectively.

Further, the rib 37L is integrally provided on the bulging portion 37J, and the rib 37L protrudes forward from the bulging portion 37J and extends in the vertical direction. As a result, the bulging portion 37J can be reinforced by the rib 37L, and the rigidity of the protruding portion 37I can be increased more effectively.

As a result, the first electrical device 22 and the second electrical device 23 can be more effectively protected from the radiator 16.

The number of protruding portions 37I is not limited to one, and a plurality of protruding portions 37I may be provided on the front wall portion 37. Further, the protruding portion 37I may be provided on the upper mounting portion 37F side. When the protruding portion 37I is provided on the upper mounting portion 37F side, the protruding portion 37J may connect the seat surface 37n of the upper mounting portion 37F and the protruding portion 37I.

Further, the protruding portion 37I may be provided on at least one of the lower mounting portion 37A and the lower mounting portion 37B. In this case, the protruding portion 37I may be connected to at least one of the lower mounting portion 37A and the lower mounting portion 37B.

Further, according to the protection structure of the vehicle electric device of the present embodiment, the third electric device 25 is installed on the upper surfaces of the front member 12, the rear member 13, and the auxiliary member 14.

Here, when the front end 25f of the third electric device is installed behind the front end 37i of the protrusion 37I and above the protrusion 37I, when the radiator 16 falls backward, the radiator 16 May collide with the third electrical device 25 before it comes into contact with the protrusion 37I.

According to the protective structure of the vehicle electric device of the present embodiment, the projecting portion 37I is installed at the left end portion of the front wall portion 37 on the third electric device 25 side in the vehicle width direction, and the third electric device. The front end 25f of the above is installed behind the front end 37i of the protrusion 37I and below the protrusion 37I.

As a result, when the radiator 16 is tilted backward, the radiator 16 can be brought into contact with the protrusion 37I before colliding with the third electric device 25.

Therefore, it is possible to prevent the radiator 16 from strongly interfering with the third electric device 25, and it is possible to alleviate the impact applied from the radiator 16 to the third electric device 25. As a result, the third electrical device 25 can be protected from the radiator 16.

Further, according to the protection structure of the vehicle electric device of the present embodiment, the third electric device 25 is adjacent to the radiator 16 with respect to the first electric device 22 and the second electric device 23, and is front and rear. It faces the radiator 16 in the direction.

As a result, in the space behind the radiator 16, the first electric device 22, the second electric device 23, and the third electric device 25 can be arranged in the vehicle width direction and installed in the subframe 11.

Therefore, while preventing the installation space of the first electric device 22, the second electric device 23, and the third electric device 25 from becoming large in the front-rear direction, the protrusion 37I makes the first electric device 22, the first electric device 22, and the third electric device 25. The second electric device 23 and the third electric device 25 can be protected.

Further, according to the protective structure of the vehicle electric device of the present embodiment, the front end 12f of the front member 12 is located on the front side of the protrusion 37I.

As a result, when the radiator 16 moves rearward at the time of a front collision of the vehicle 1, the radiator 16 can collide with the front end 12f of the front member 12 before coming into contact with the protrusion 37I. Therefore, the impact when the radiator 16 comes into contact with the protrusion 37I can be reduced.

Therefore, the impact applied from the radiator 16 to the first electric device 22, the second electric device 23, and the third electric device 25 can be more effectively mitigated, and the first electric device 22, the second electric device 23, and the third electric device 25 can be more effectively relaxed. The third electrical device 25 can be more effectively protected from the radiator 16.

Further, in the height direction of the vehicle 1, the front member 12 is installed above the central portion O in the height direction of the radiator 16 and below the upper tank 16A.

As a result, when the radiator 16 collides with the front member 12, the upper part of the radiator 16 can be guided to fall backward with the front member 12 as a fulcrum. Therefore, the first electric device 22, the second electric device 23, and the third electric device 25 installed above the subframe 11 can be more effectively protected by the protrusion 37I.

Further, according to the protection structure of the vehicle electric device of this embodiment, the second electric device 23 is composed of an inverter and is installed above the radiator 16.

The inverter is a high-voltage component that is constantly operated to transfer power to and from the motor 8, and needs to be actively protected inside the motor room 1A. Therefore, by installing the second electric device 23 composed of the inverter above the radiator 16, the second electric device 23 can be installed far from the radiator 16.

Therefore, it is possible to more effectively prevent the radiator 16 from interfering with the second electric device 23 at the time of a front collision of the vehicle 1, and it is possible to more effectively protect the second electric device 23 from the radiator 16.

Although the embodiments of the present invention have been disclosed, it is clear that some skilled in the art can make changes without departing from the scope of the present invention. All such modifications and equivalents are intended to be included in the following claims.

1 ... vehicle, 1A ... motor room, 7 ... power train, 8 ... motor, 9 ... drive unit, 11 ... subframe, 12 ... front member (frame member) , 12f ... front end (front end of frame member), 13 ... rear member (frame member), 14 ... auxiliary member (frame member), 16 ... radiator (vehicle-mounted member), 22 ... 1st electric device (vehicle electric device), 23 ... 2nd electric device (vehicle electric device), 24 ... bracket, 25 ... 3rd electric device (vehicle electric device), 25f ... front end (front end of third electric device), 35 ... bottom wall part, 36 ... peripheral wall part, 37 ... front wall part, 37A, 37B ... lower mounting part (third) 1 lower mounting part), 37C, 37D ... lower mounting part, 37E, 37F ... upper mounting part (first upper mounting part), 37G, 37H ... upper mounting part, 37I .. .Protruding part, 37i ... front end (front end of protruding part), 37J ... bulging part, 37m ... seat surface, 37w ... wall surface (wall surface of front wall part),

Claims (6)

In-vehicle members installed in the motor room at the front of the vehicle,
A frame member installed in the motor room behind the vehicle-mounted member and extending in the width direction of the vehicle,
A protective structure for electrical equipment for a vehicle installed in a vehicle having a motor and a drive device connected to the motor and a power train supported by the frame member.
The vehicle electric device is installed behind the vehicle-mounted member via a first electric device installed on the upper part of the frame member and on the upper part of the first electric device via a bracket, and the first electric device is installed. It has a device and a second electrical device that is lined up in the vertical direction.
The bracket is provided on a peripheral wall portion having a front wall portion extending in the width direction of the vehicle and facing the vehicle-mounted member in the front-rear direction of the vehicle, and a lower portion of the peripheral wall portion to which the first electric device is attached. It has a lower mounting portion and an upper mounting portion provided above the peripheral wall portion to which the second electric device is mounted.
The front wall portion has a protruding portion that projects forward from the front wall portion toward the vehicle-mounted member.
A protective structure for electrical equipment for a vehicle, wherein the protruding portion projects forward of the lower mounting portion and the upper mounting portion. The lower mounting portion has a first lower mounting portion provided below the front wall portion.
The upper mounting portion has a first upper mounting portion provided on the upper portion of the front wall portion.
The first aspect of the present invention, wherein the front wall portion has a connecting portion for connecting the first lower mounting portion and the protruding portion, or the first upper mounting portion and the protruding portion. Protective structure for electrical equipment for vehicles. The first upper mounting portion bulges forward from the wall surface of the front wall portion and extends in the vertical direction, and the lower portion in the extending direction is connected to the protruding portion and the upper surface of the bulging portion. It has a seating surface that is provided and comes into contact with the second electrical device.
The protective structure for electrical equipment for vehicles according to claim 2, wherein the protruding portion is provided side by side with the seat surface in the vertical direction. A third electric device is installed on the upper part of the frame member.
The third electric device is adjacent to the first electric device and the second electric device in the width direction of the vehicle and faces the in-vehicle member in the front-rear direction of the vehicle.
The protrusion is provided at the widthwise end of the front wall of the vehicle on the third electrical device side.
The vehicle according to any one of claims 1 to 3, wherein the front end of the third electric device is located behind the front end of the protruding portion and below the protruding portion. Protective structure for electrical equipment. The protective structure for an electrical device for a vehicle according to any one of claims 1 to 4, wherein the front end of the frame member is located on the front side of the protruding portion. The protection of the vehicle electric device according to any one of claims 1 to 5, wherein the second electric device is composed of an inverter and is installed above the vehicle-mounted member. Construction.

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