JP4285405B2 - Hybrid car - Google Patents

Description

  The present invention relates to a structure for mounting a battery in a hybrid-type vehicle, and relates to a hybrid vehicle that is reduced in cost and including a harness portion.

  As a conventional hybrid vehicle, for example, the one described in Patent Document 1 is known.

  As shown in FIG. 10, in the trunk room 101 at the rear of the automobile 100, a high-voltage battery 102 that generates a high-voltage current and a high-voltage DC current of the high-voltage battery 102 are converted into a low-voltage DC current. And a DC-DC converter 103 that steps down the voltage and supplies it to on-vehicle electrical equipment. A drive motor 105 for driving the automobile and an inverter 106 for converting direct current into alternating current are arranged in the engine room 104 at the front of the vehicle body. The inverter 106 is disposed in front of the vehicle body from the front wheel axle. The inverter 106 uses the high voltage direct current generated by the high voltage battery 102 to rotate the permanent magnet type AC synchronous drive motor 105 when the vehicle 100 is driven by the drive motor 105 instead of the engine 107. It is converted into an alternating current and supplied to the drive motor 105. The high voltage battery 102 and the inverter 106 are connected by a power supply harness 108 made of a conductive wire, and the power supply harness 108 extends from the front part of the vehicle body to the rear part of the vehicle body.

109 is a transmission, and 110 to 112 are water-cooled hoses. The DC-DC converter 103 and the inverter 106 employ a method of cooling with water-cooled hoses 110 to 112 for miniaturization. The water cooling hose 110 connects between the drive motor 105 and the high voltage battery 102 and the DC-DC converter 103, the water cooling hose 111 connects between the drive motor 105 and the inverter 106, and the water cooling hose 112 connects to the high voltage battery. It connects between the 102 and the DC-DC converter 103 and the driving motor 105, and by circulating coolant between them.

However, in the case of the hybrid vehicle described above, the high-voltage battery 102, which is generally air-cooled, and the inverter 106 and the DC-DC converter 103, which are generally water-cooled, are arranged in a mixed manner. The reason is that the water-cooled hoses 110 and 112 for supplying the refrigerant and the power supply harness 108 are long, the weight of the refrigerant and the supply hose is increased, and the manufacturing cost is increased. It becomes.

  The present invention has been made paying attention to such problems, and aims to improve the cooling efficiency of the battery, the inverter and the converter, reduce the weight of the power supply harness and the cooling system, and reduce the cost.

In order to solve the above-described problems, a hybrid vehicle of the present invention includes a driving AC type driving motor, an inverter that supplies driving AC current to the driving motor, and the inverter driving the driving motor. A hybrid vehicle comprising a high-voltage battery for supplying high-voltage direct current and a converter for converting the high-voltage direct-current generated by the high-voltage battery into low-voltage direct current and supplying electric power to an on-vehicle electric device. The converter is configured as a first unit, the high-voltage battery is configured as a second unit, the first unit and the second unit are mounted close to each other, and the inverter and the converter are mounted on the first unit. And a liquid cooling system that cools the high voltage battery to the second unit. An air cooling system to be rejected, and the air cross-sectional area of the air cooling path of the second unit is set so as to increase from upstream to downstream, and the battery elements constituting the high-voltage battery are stacked. The battery elements are stacked stepwise so that the height increases from upstream to downstream of the flow path .

  In the hybrid vehicle according to the present invention, the inverter and the converter are integrated into one unit to be the first unit, the high voltage battery is disposed as the second unit, and the cooling method for the first unit and the second unit is provided. Since they are different, the cooling efficiency of each unit is improved, the power supply harness can be shortened, and the size reduction of the high voltage battery, the inverter, the converter, etc. can be promoted by reducing the weight and the resistance value.

Hereinafter, a hybrid vehicle according to an embodiment of the present invention will be described with reference to the drawings. Figure 1 is a planar arrangement of a hybrid vehicle schematically illustrated, Figure 2 shows an inverter unit 8 of the lower floor arrangement of a high-voltage battery 9. 3 shows a longitudinal sectional configuration of the inverter unit 8 in the longitudinal direction of the vehicle body, and FIG. 4 shows a longitudinal sectional configuration of the high voltage battery 9 in the longitudinal direction of the vehicle body. 5 shows a longitudinal sectional configuration of the inverter unit 8 and the high voltage battery 9 in the vehicle width direction, and FIG. 6 shows panels 34 and 35 on which the inverter unit 8 and the high voltage battery 9 are mounted and their peripheral structures. The left-right direction in FIG. 1 is the vehicle body front-rear direction, and the vertical direction is the vehicle width direction. 1 indicates the forward direction of the hybrid vehicle 1, and R indicates the backward direction of the hybrid vehicle 1.

  As shown in FIG. 1, the engine 2 of the hybrid vehicle 1 is disposed in an engine room 4 at the front of the vehicle, and a drive motor 3 composed of a permanent magnet AC synchronous motor is connected to the rear end of the engine 2. Has been. A transmission 5 is connected to the rear end of the drive motor 3. The driving force of the engine 2 or the driving motor 3 or the driving force of the engine 2 and the driving motor 3 is selectively input to the transmission 5 at the time of starting, accelerating or traveling. The driving force of the transmission 5 is transmitted to the rear differential gear 7 via the propeller shaft 6 to drive the rear wheels.

  As shown in FIGS. 1, 2, and 5, an inverter unit 8 corresponding to the first unit in the claims and a high voltage corresponding to the second unit in the claims are provided near the center of the floor of the hybrid vehicle 1. A battery 9 is mounted in parallel in close proximity. The inverter unit 8 that supplies power to the drive motor 3 and the high-voltage battery 9 are different in cooling method, and are separately disposed between the front and rear axles.

  As shown in FIGS. 1, 2, and 5, the inverter unit 8 and the high-voltage battery 9 are provided between a front wheel axle and a rear wheel axle, and a propeller shaft 6 that extends in the vehicle body length direction at the center of the vehicle body. It is arranged on the left and right. That is, the inverter unit 8 and the high-voltage battery 9 are arranged at positions close to each other in the vehicle width direction around the propeller shaft 6. A second cross member 31 extending in the vehicle width direction is joined to the lower part of the driver's seat (see FIG. 5), and the inverter unit 8 and the high voltage battery 9 are mounted near the lower part of the second cross member 31.

  The inverter unit 8 and the high voltage battery 9 are connected by a power supply harness 27. The power supply harness 27 is housed in a cylindrical reinforcing member 29 (see FIG. 2) extending in the vehicle width direction. As shown in FIG. 5, the reinforcing member 29 passes through the floor front center 28 in the vehicle width direction, passes below the propeller shaft 6, and is disposed at the same position as the second cross member 31 in the vehicle longitudinal direction. The propeller shaft 6 is housed in a floor front center 28 that extends in the longitudinal direction of the vehicle body. The inverter unit 8 and the drive motor 3 are connected by a power cable 32 (see FIG. 1) and wired below the front floor panel 30.

  As illustrated in FIGS. 1 and 2, the inverter unit 8 includes an inverter 10 and a DC-DC converter 11. The inverter 10 and the DC-DC converter 11 are cooled with a liquid refrigerant. The inverter unit 8 is disposed between the front and rear axles and on either the left or right side of the propeller shaft 6 and is provided at a position from the lower floor of the front seat occupant to the portion in front of the fuel tank.

FIG. 2 shows a cooling path of the inverter unit 8. A water cooling system 12 including a radiator and a pump is disposed in front of the inverter unit 8. The inverter 10 and the DC-DC converter 11 of the inverter unit 8 are cooled by a liquid cooling system (an aqueous solution such as water and antifreeze liquid) circulated from the water cooling system 12 and the drive motor 3 is connected to the inverter unit 8. Similarly, water is cooled as a liquid refrigerant. The liquid refrigerant sent from the water cooling system 12 to the inverter unit 8 through the water cooling hose 13 cools the inverter unit 8 and then exits from the inverter unit 8 and enters the drive motor 3 via the water cooling hose 14 to cool the drive motor 3. Later, it circulates back to the water cooling system 12 via the water cooling hose 15. The water cooling system 12 is cooled by a refrigerant of an air conditioner sent through pipes 16a and 16b described later.

  FIG. 3 shows a longitudinal sectional structure of the inverter unit 8 in the longitudinal direction of the vehicle body. A cover 44 is provided on the top of the inverter unit 8. The cover 44 has a convex shape on the upper side and a flange 46 on the lower edge. The cover 44 is attached on the reinforcing members 36, 37, 40, 41 of FIG. The cover 44 covers the upper part of the inverter unit 8 and protects the inverter unit 8 from water, dust and the like.

4 to 6 show the configuration of the mounting part of the inverter unit 8 and the high-voltage battery 9. The inverter unit 8 is mounted on an upper surface of the panel 34 of the lower floor 33a that is one step lower than the front floor panel 30 and surrounded by the reinforcing members 36, 37, 40, and 41. Similarly, the high-voltage battery 9 is mounted on the upper surface of the panel 35 of the lower floor 33b that is one step lower than the front floor panel 30 and surrounded by the reinforcing members 23, 25, 35, and 38 shown in FIG. The reinforcing members 36, 37, 40, 41 and the reinforcing members 23, 25, 35, 38 each have a hollow cross-sectional structure.

  FIG. 4 shows a longitudinal sectional structure of the high-voltage battery 9 in the longitudinal direction of the vehicle body. FIG. 4 shows an arrangement state of the battery module 19 of the high voltage battery 9. As shown in FIG. 5, the high voltage battery 9 is installed between the front and rear axles and at a position opposite to the installation location of the inverter unit 8 around the propeller shaft 6. A cover 45 is provided on the high voltage battery 9. The cover 45 has a convex shape on the upper side and a flange 47 on the lower edge. The cover 45 is attached on the reinforcing members 23, 25, 38, 39 via flanges 47, respectively. The cover 45 covers the upper portion of the high voltage battery 9 and protects the high voltage battery 9 from water, dust and the like.

  As shown in FIG. 4, the battery unit 20 that constitutes the high-voltage battery 9 serving as the second unit is composed of an assembly of battery modules 19. The battery modules 19 are mounted in four rows. For example, from the front side of the vehicle, the front row is 2 steps, the next row is 4 steps, the last row is 4 steps, and the step located downstream from the step located upstream of the air flow path is higher. They are stacked almost in a staircase pattern. A flow path (shaded portion) is formed between the battery modules 19 and the cover 45 to be loaded, and the cross-sectional area of the flow path 56 increases as the cooling air flows to the rear of the vehicle, and the cooling air flows with less resistance. It is like that.

The high voltage battery 9 includes a battery unit 20, a junction box 21, and a controller 22, and is cooled by an air cooling method. The battery unit 20 is configured by connecting a plurality of battery modules 19 in series, and the battery module 19 is formed by electrically connecting a plurality of cells in series. The junction box 21 is a connection part that connects the battery unit 20 and the inverter unit 8 with a power supply harness 27. The controller 22 controls the output of the battery unit 20.

  The high voltage battery 9 is cooled by the cooling air of the air conditioner of the hybrid vehicle 1, and the cooling air supplied from the air conditioner passes through the cooling duct 24 connected to the reinforcing member 23 having the air holes 23a (see FIG. 6). The high voltage battery 9 is cooled. The cooling air that has passed through the high voltage battery 9 passes through a cooling duct 26 connected to a reinforcing member 25 having an air hole 25a (see FIG. 6) and is discharged from a drafter (not shown).

The inside of the cooling duct 24 is hollow for ventilation. One end of the cooling duct 24 is connected to the cooling chamber of the air conditioner, and the other end of the cooling duct 24 communicates with the air hole 23 a of the reinforcing member 23. The air cooled by the air conditioner passes through the unit of the high voltage battery 9 through the cooling duct 24 and cools the high voltage battery 9 and then is discharged from the cooling duct 26 to the outside of the vehicle. If the high voltage battery 9 is cooled and then returned to the cooling pipe of the air conditioner without being discharged from the cooling duct 26 to the outside of the vehicle, the cooling heat is reduced by returning the cooling duct 24 to the storage room of the high voltage battery 9. It is efficient because it is not lost.

  FIG. 5 shows a state in which the inverter unit 8 and the high voltage battery 9 are respectively installed on the left and right sides of the propeller shaft 6.

  FIG. 6 shows a configuration in which the inverter unit 8 and the high voltage battery 9 are attached. The inverter unit 8 and the high voltage battery 9 can be replaced by removing the panel 34 and the reinforcing members 36, 37, 40, 41, and the panel 35 and the reinforcing members 23, 25, 38, 39 from the front floor panel. It is said that. The panel 34 and the reinforcing members 36, 37, 40, and 41 are assembled by welding, and the panel 35 and the reinforcing members 23, 25, 38, and 39 are assembled by welding.

  The lower floor 33a is formed in a box shape, and is provided at a plate-like panel 34 serving as a bottom plate, reinforcing members 36 and 37 fixed to left and right ends of the panel 34, and front and rear ends of the panel 34. And reinforcing members 40 and 41. The reinforcing members 36 and 37 are directed in the longitudinal direction of the vehicle body, and the reinforcing members 40 and 41 are directed in the vehicle width direction.

The reinforcing member 40 is formed with a hole 33b through which the water-cooled hose 14 passes, a hole 33c through which the water-cooled hose 15 passes, and a hole 33d through which the pipe 16a for air conditioner refrigerant passes. The periphery of the holes 33b, 33c, and 33d is covered with a cylindrical inner wall, and is separated from the inside of the cylindrical body of the reinforcing member 33a. The air-conditioner refrigerant pipe 16a is for passing a refrigerant for cooling the water cooling system 12. The refrigerant is sent from the air conditioner (not shown) through the pipe 16a to the water cooling system 12, and the refrigerant cools the water cooling system 12. After that, it is sent again to the air conditioner side through the pipe 16b passed through the hole 37a, recooled and circulated. The pipe 16 b communicates with the water cooling system 12 through the hole 37 a of the reinforcing member 37.

  The reinforcing member 37 has a hole 37b through which the cylindrical reinforcing member 29 is passed. The reinforcing member 38 has a hole 38 a through which the reinforcing member 29 is passed and a hole 38 b through which the power feeding harness 27 is passed. The power feeding harness 27 passes through the inside of the reinforcing member 38 from the hole 38 b, then passes through the inside of the reinforcing member 29, and passes through the hole 37 b of the reinforcing member 37 to the inverter unit 8.

  The lower floor 33b shown in FIG. 6 is formed in a box shape and has a plate-like panel 35 serving as a bottom plate, reinforcing members 38 and 39 fixed to left and right ends of the panel 35, and front and rear ends of the panel 35. Reinforcing members 23 and 25 are provided. The reinforcing members 38 and 39 are directed in the longitudinal direction of the vehicle body, and the reinforcing members 23 and 25 are directed in the vehicle width direction.

  The reinforcing member 23 is formed with an air hole 23a for introducing cooling air. The periphery of the air hole 23 a is covered with a cylindrical inner wall and is separated from the inside of the cylindrical body of the reinforcing member 23. The reinforcing member 25 is formed with an air hole 25a for discharging cooling air. The periphery of the air hole 25a is covered with a cylindrical inner wall and is separated from the inside of the cylindrical body of the reinforcing member 25.

  As shown in FIG. 5, the lower floor 33 a extends in the vehicle width direction on the lower side of the front floor panel 30 and the extension front side member 48 and the tunnel member 54 extending in the vehicle body full length direction on the lower side of the front floor panel 30. It attaches to the extending cross members 50 and 51 (refer FIG. 3). The lower floor 33b includes an extension front side member 49 and a tunnel member 55 (see FIG. 5) extending in the vehicle body length direction below the front floor panel 30, and a cross member extending in the vehicle width direction below the front floor panel 30. 52, 53.

  FIG. 7 shows an example of a hybrid vehicle 78 of the second embodiment. In the hybrid vehicle 78, the engine 2 is disposed in the engine room 4 at the front of the vehicle, and a drive motor 57 is disposed at the rear end of the engine 2. The drive motor 57 drives the front wheels via the propeller shaft 58. The driving force of the engine 2 is transmitted via a propeller shaft 58 to a driving device 62 in which a driving motor 60 and a rear differential gear 61 are integrated, and the rear wheels are driven. The inverter unit 8 and the high voltage battery 9 are separated in the vehicle width direction so as to be positioned on the left and right sides with the propeller shaft 58 interposed therebetween, and are disposed close to each other between the front wheel axle and the rear wheel axle.

  In the electrical wiring path, the high voltage battery 9 and the inverter unit 8 are connected by a power supply harness 62, and the inverter unit 8 and the drive motor 60 are connected by a power supply harness 64.

In the cooling path, the refrigerant discharged from the water cooling system 12 enters the inverter unit 8 via the water cooling hose 70, enters the drive motor 60 via the water cooling hose 69, and drives the motor 57 via the water cooling hose 67. And finally circulated through the water cooling hose 68 in the order of the water cooling system 12.

  FIG. 8 shows a hybrid vehicle according to the third embodiment. In this hybrid vehicle, in another hybrid vehicle 77, the engine 2 and the drive motor 66 are arranged next to the engine 2 in the engine room 4 at the front of the vehicle, and the engine 2 and the drive motor 66 are driven by the front wheels. The inverter unit 8 and the high voltage battery 9 for supplying power to the drive motor 66 are mounted separately. The inverter unit 8 and the high-voltage battery 9 are disposed close to each other between the front wheel axle and the rear wheel axle. The inverter unit 8 and the high-voltage battery 9 each have a longitudinal direction. The inverter unit 8 and the high-voltage battery 9 are mounted so that each longitudinal direction is in the vehicle width direction and the inverter unit 8 is in front of the high-voltage battery 9 in the vehicle body longitudinal direction. The In the electrical wiring path, the high voltage battery 9 and the inverter unit 8 are connected by a power supply harness 71, and the inverter unit 8 and the drive motor 66 are connected by a power supply harness 72.

In the cooling path, the refrigerant discharged from the water cooling system 12 enters the inverter unit 8 via the water cooling hose 74, enters the drive motor 66 via the water cooling hose 75, and passes through the water cooling hose 73 to the water cooling system 12. It is circulated in the order.

FIG. 9 shows a hybrid vehicle according to the fourth embodiment. In this embodiment, the insides of the reinforcing members 75 and 76 that are arranged in the longitudinal direction of the vehicle body and that constitute the lower floor 33a on which the inverter unit 8 is mounted are divided into four parts. The reinforcing members 75 and 76 are reinforcing members that extend in the vehicle width direction and connect the unit of the inverter unit 8 and the high-voltage battery 9, and are divided into four parts, and a power feeding harness is provided in any of the partitioned passages. 27 is stored. Other configurations are the same as those in FIG. Accordingly, there is no need to fix the power supply harness 27 with a fixing tool or the like, and there is no concern that the electric wire is exposed, so that productivity and safety can be improved and production cost can be reduced.

It is a perspective view which shows the planar arrangement structure of the inverter and high voltage battery in the hybrid vehicle of embodiment of this invention. It is the top view to which the planar arrangement configuration of the inverter and high voltage battery in FIG. 1 was expanded. It is a figure which shows the longitudinal cross-section structure of the AA line of the inverter unit in the hybrid vehicle of FIG. It is a figure which shows the longitudinal cross-sectional structure of the BB line of the high voltage battery in the hybrid vehicle of FIG. It is a perspective view which shows the longitudinal cross-sectional structure of CC line of the inverter unit of FIG. 2, and a high voltage battery. It is a perspective view which shows the combination state of the inverter unit concerning an embodiment, and the mounting member of a high voltage battery. FIG. 7 is a plan view of the hybrid vehicle according to the second embodiment. FIG. 8 is a plan view of a hybrid vehicle according to the third embodiment. FIG. 9 is a cross-sectional view of a hybrid vehicle according to the fourth embodiment. FIG. 10 is a plan view showing an arrangement state of an engine, a drive motor, an inverter, and a converter of a conventional hybrid vehicle.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hybrid vehicle 2 Engine 3 AC synchronous drive motor 4 Engine room 5 Transmission 8 Inverter unit 9 High voltage battery 10 Inverter for DC / AC conversion 11 DC-DC converter 12 Water cooling system 13, 14, 15 Water cooling hose 16a, 16b Air conditioner refrigerant Piping 19 Battery module 20 Battery unit 21 Junction box 22 Controller 23 Reinforcing member 23a Air hole 24 Cooling duct 25 Reinforcing member 25a Air hole 26 Cooling duct 27 Feeding cable 29 Reinforcing member 31 Cross member 56 Cooling air flow path

Claims (11)

AC driving motor for traveling, an inverter for supplying driving AC current to the driving motor, a high voltage battery for supplying high voltage DC current to the inverter to drive the driving motor, and the high voltage In a hybrid vehicle equipped with a converter that converts a high-voltage direct current generated by a battery into a low-voltage direct current and supplies power to an on-vehicle electrical device,
The inverter and the converter are configured as a first unit, the high-voltage battery is configured as a second unit, and the first unit and the second unit are mounted close to each other,
A liquid cooling system for commonly cooling the inverter and the converter is provided in the first unit, and an air cooling system for cooling the high-voltage battery is provided in the second unit;
The air unit cross-sectional area in the air cooling path of the second unit is set to increase from upstream to downstream, and the stacking height of the battery elements constituting the high-voltage battery is from upstream to downstream of the flow path. A hybrid vehicle in which the battery elements are stacked in a stepped manner so as to become higher toward the vehicle. The hybrid vehicle of claim 1,
A hybrid vehicle characterized in that the first unit and the second unit are disposed between front and rear axles . The hybrid vehicle according to any one of claims 1 and 2,
A hybrid vehicle using a refrigerant cooled by an air conditioner for the liquid cooling . In the hybrid vehicle according to any one of claims 1 to 3,
A hybrid vehicle using air conditioner cold air for the air cooling . In the hybrid vehicle according to any one of claims 1 to 4,
A hybrid vehicle characterized in that the first unit and the second unit are housed in an area below a boarding surface of a floor . In the hybrid vehicle according to any one of claims 1 to 5,
A hybrid vehicle characterized in that the first unit and the second unit are coupled by a reinforcing member extending in the vehicle width direction, and the reinforcing member is disposed in the vicinity of a second cross member . In the hybrid vehicle according to any one of claims 1 to 6,
A hollow reinforcing member disposed in the vehicle front-rear direction and the vehicle width direction and surrounding the outer periphery of each of the first unit and the second unit, and the bottom of each of the first unit and the second unit are shielded. A hybrid vehicle comprising a panel . In the hybrid vehicle according to any one of claims 1 to 7 ,
The inside of the reinforcing member that extends in the longitudinal direction of the vehicle and is arranged beside the first unit and the second unit is partitioned into a plurality of parts, and the first unit and the second unit are connected to any of the partitioned passages. A hybrid vehicle characterized in that a power supply harness is stored . In the hybrid vehicle according to any one of claims 1 to 8,
A hybrid vehicle characterized in that upper and lower portions of the first unit and the second unit are sealed with a cover . In the hybrid vehicle according to any one of claims 1 to 9,
A hybrid vehicle characterized in that the first unit and the second unit are arranged side by side in the vehicle longitudinal direction between axles . AC driving motor for traveling, an inverter for supplying driving AC current to the driving motor, a high voltage battery for supplying high voltage DC current to the inverter to drive the driving motor, and the high voltage In a hybrid vehicle equipped with a converter that converts a high-voltage direct current generated by a battery into a low-voltage direct current and supplies power to an on-vehicle electrical device,
The inverter and the converter are configured as a first unit, and the high voltage battery is configured as a second unit,
The first unit and the second unit are mounted close to each other, the first unit and the second unit are cooled by different methods, and the first unit and the second unit are arranged in the vehicle width direction. Connected by a reinforcing member extending to
A hybrid vehicle characterized in that a power supply harness for connecting the first unit and the second unit is housed in the reinforcing member .

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