Patent Application
20250058617
This application claims priority to Japanese Patent Application No. 2023-133495 filed Aug. 18, 2023, the disclosure of which is hereby incorporated by reference in its entirety.
The present invention relates to an electric vehicle configured to travel as driven by an electric motor operable with electric power from batteries.
Electrically operated utility vehicles travel as driven by an electric motor operable with electric power from a battery. Such a battery, as disclosed in JP 2018-154191 A (Patent Literature 1), typically lies laterally under a seat. Utility vehicles (that is, electric vehicles) are required to include a battery with a large charging capacity, that is, a large-sized battery, for an extended travelable distance.
Utility vehicles include axles extending in the front-back direction of the body, which makes it difficult to orient a large-sized battery laterally under a seat. Spreading battery cells on the floor may be an option, but will more likely let the battery be damaged, as utility vehicles may travel on rough terrain.
The present invention has an object of providing an electric vehicle including efficiently positioned large-capacity batteries.
In order to attain the above object, an electric vehicle as an embodiment of the present invention includes: a body; an electric motor; a front wheel and a rear wheel each drivable by motive power from the electric motor; and a plurality of batteries each configured to feed electric power to the electric motor, the plurality of batteries including at least two batteries arranged side by side in the left-right direction with the electric motor in between.
Electric vehicles are required to include a battery with a large charging capacity for an extended travelable distance. A battery with a large charging capacity needs to be physically large. The vehicle body is, however, provided with a large number of components such as an electric motor and axles other than a battery. This makes it difficult to mount a large battery in the body.
The above configuration involves a plurality of batteries that are not large to constitute a battery system with an increased charging capacity. The batteries, which are not large, may be positioned efficiently in the body, meaning that a battery system with a large charging capacity may be mounted efficiently in the body.
An electric motor, which supplies motive power in the front-back direction of the body, is usually in or near a laterally central area of the body. Further, an electric motor is relatively large.
The above configuration ensures a space for an electric motor and allows the electric motor to be positioned appropriately. The above configuration also allows batteries to be disposed in an area where the electric motor is absent, meaning that a battery system with a large charging capacity may be mounted efficiently in the body.
The electric vehicle may be further configured such that the at least two batteries are symmetrical to each other with respect to a direction in which the electric vehicle travels.
An electric motor, which supplies motive power in the front-back direction of the body, is usually in or near a laterally central area of the body. Further, an electric motor is relatively large.
The above configuration allows the electric motor to be positioned suitably and allows the batteries to be disposed in the body in a balanced manner, meaning that a battery system with a large charging capacity may be mounted efficiently in the body.
The electric vehicle may be further configured such that the at least two batteries are of an identical model.
Arranging two batteries in the body symmetrically to each other as above allows the weight balance of the body to be suitable.
The electric vehicle may further include: a front axle extending forward from the electric motor and configured to transmit the motive power from the electric motor to the front wheel; and a rear axle extending backward from the electric motor and configured to transmit the motive power from the electric motor to the rear wheel, wherein at least either the front axle or the rear axle is between the at least two batteries.
The above configuration ensures a space for the axles, which extend in the front-back direction of the body, and allows the batteries to be positioned efficiently, meaning that a battery system with a large charging capacity may be mounted efficiently in the body.
The electric vehicle may be further configured such that the at least two batteries are oblique in a plan view relative to a direction in which the electric vehicle travels.
The above configuration allows large (long) batteries to be disposed in an area of the body in which area various other components are absent. This allows efficient use of a large battery system, meaning that a battery system with a large charging capacity may be mounted efficiently in the body.
The electric vehicle may be further configured such that the at least two batteries are oblique such that respective portions further backward relative to the body are closer to each other.
Rear wheels, which are at a back portion of the body, may laterally narrow and limit a space for a battery at a back portion of the body. The above configuration positions the batteries across the electric motor and orients the batteries obliquely such that they are in an area where the electric motor is absent and that their respective portions backward relative to the body, where the available space is small, are close to each other. This allows use of long batteries and also allows two batteries to be positioned efficiently, meaning that a battery system with a large charging capacity may be mounted efficiently in the body.
The electric vehicle may be further configured such that in a front view, the at least two batteries have respective front end portions apart from the electric motor and respective back end portions overlapping with the electric motor.
The above configuration allows two batteries to be positioned efficiently in an area where the electric motor is absent.
The electric vehicle may be further configured such that the electric motor is within an area of the at least two batteries in a side view.
The above configuration allows the batteries to be laterally outward of the electric motor and positioned at the same height as the electric motor. This reduces a space for the batteries and the electric motor in the height direction, and allows the batteries and the electric motor to be mounted efficiently in the body.
The electric vehicle may further include: a driver's seat for an occupant to sit on, wherein the at least two batteries have respective back end portions backward of a back end portion of the driver's seat in a plan view.
The above configuration allows the batteries, which extend backward from under the seat, to be positioned efficiently.
The electric vehicle may be further configured such that the at least two batteries have respective back end portions overlapping with the rear wheel in a side view.
The above configuration allows batteries with a large front-back dimension to be mounted.
The electric vehicle may be further configured such that the at least two batteries each have a rectangular parallelepiped outer shape.
The above configuration allows general-purpose batteries to constitute a battery system.
The description below deals with a utility vehicle as an example of the electric vehicle of the present invention with reference to drawings. The description below refers to
The utility vehicle includes a driver section 4 disposed at a front portion of the body 3 and configured to accommodate an occupant such as a driver. The utility vehicle includes in the driver section 4 a driver's seat 5 for an occupant to sit on, a steering wheel 6 for use to change the direction of the front wheels 1, and a roll-over protective structure (ROPS) 7 that defines a driver space.
The utility vehicle includes a cargo box 8 backward of the driver section 4 and a body frame 9 holding the cargo box 8. The cargo box 8 is swingable up and down about a coupling axis P for the cargo box 8 and the body frame 9. The cargo box 8 is capable of being lifted into a dumping orientation and lowered into a travel orientation.
As illustrated in
The batteries 14 feed electric power to the inverter 13, which then converts it into alternating-current electricity. The inverter 13 supplies the alternating-current electricity to the electric motor 12 to drive the electric motor 12. The utility vehicle includes a rear-wheel differential mechanism 15 (differential gear), a front-wheel differential mechanism 16 (differential gear), a rear axle 17, and a front axle 18. The electric motor 12 transmits motive power through the rear axle 17 and the rear-wheel differential mechanism 15 to the rear wheels 2, The electric motor 12 also transmits motive power through the front axle 18 and the front-wheel differential mechanism 16 to the front wheels 1.
As illustrated in
The lateral frame members 9A lie at the opposite lateral sides of the driver section 4 and extend from a front portion of the driver section 4 through a lower portion thereof to a back portion thereof. The front frame member 9B lies at the front side of the driver section 4 and extends laterally from one lateral frame member 9A to the other. The back frame member 9C lies at the back side of the driver section 4 and extends laterally from one lateral frame member 9A to the other. The back lateral frame members 9D extend from the respective lateral frame members 9A toward the back end of the body 3.
The underguard 21 has a smaller width at a back portion of the body 3 due to the rear wheels 2, which are disposed at a back portion of the body 3. This means a smaller space for components at a back portion of the body 3 than in a central area thereof. The back lateral frame members 9D accordingly extend obliquely in a plan view relative to a front-back direction L such that their respective back ends are close to each other in a plan view.
The intermediate frame member 9E extends laterally in a central area of the driver section 4 in its front-back direction. The front frame member 9B is above the back frame member 9C, which is above the back lateral frame members 9D, which is above the intermediate frame member 9E.
The electric motor 12 is below the driver's seat 5, in a laterally central area of the body 3, and above the underguard 21. The electric motor 12 has a front end within the area of the driver's seat 5 in a plan view.
The front-wheel differential mechanism 16 is between the front wheels 1 and in a laterally central area of the body 3. The rear-wheel differential mechanism 15 is between the front wheels 1, in a laterally central area of the body 3, and above the underguard 21. The inverter 13 is above the rear-wheel differential mechanism 15.
The front and rear axles 18 and 17 are in a laterally central area of the body 3 and above the underguard 21, and extend from the electric motor 12 forward and backward, respectively.
As illustrated in
Including two (or more) batteries 14 allows each battery 14 to be small-sized. This allows the batteries 14 to be positioned efficiently while constituting a battery system with a large charging capacity in total. Further, arranging the batteries 14 laterally to and across the electric motor 12 allows the electric motor 12 to be positioned appropriately and the batteries 14 to be positioned efficiently in an area where the electric motor 12 is absent.
The two batteries 14 (which are sandwiching (arranged on opposite sides of) the electric motor 12) each preferably have a rectangular parallelepiped outer shape. The batteries 14 may each be in the form of a general-purpose battery, which typically has a rectangular parallelepiped shape.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) each extend backward from a position lateral to the electric motor 12. The batteries 14, in other words, each have a back end portion (that is, a back end face 14B) backward of a back end portion of the electric motor 12. Such long batteries 14 each have a large charging capacity.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are arranged laterally across the rear axle 17. The rear axle 17 extends backward from the electric motor 12 (which is in a laterally central area of the body 3) through a laterally central area of the body 3. Arranging the batteries 14 laterally to and across the rear axle 17 allows the rear axle 17 to be positioned appropriately and the batteries 14 to be positioned efficiently in an area where the rear axle 17 is absent.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are symmetrical to each other with respect to the front-back direction L, in which the body 3 travels. This allows the batteries 14 to be laterally well-balanced, and thereby keeps the weight balance of the body 3 appropriately.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) lie obliquely relative to the front-back direction L of the body 3 in a plan view. The batteries 14 are, in other words, positioned obliquely in accordance with where the electric motor 12 is positioned and where the batteries 14 are placeable in the body 3. The batteries 14, for instance, lie obliquely such that their respective front portions are far from each other with the electric motor 12 in-between and that their respective portions further backward relative to the body 3 are closer to each other. The batteries 14 preferably lie obliquely as follows: In a front view, their respective front end portions (that is, the respective front end faces 14F) are laterally apart from the electric motor 12, while their respective back end portions (that is, the respective back end faces 14B) at least overlap with the electric motor 12.
Orienting the batteries 14 obliquely allows the electric motor 12 and other components to be positioned appropriately, regardless of where the electric motor 12 is positioned and where the batteries 14 are placeable. It also eliminates the need for specially shaped batteries, and allows general-purpose batteries 14 with a large front-back dimension and a large charging capacity to be positioned efficiently in an area of the body 3 in which area the electric motor 12 and other components are absent. Orienting the batteries 14 such that their respective portions backward relative to the body 3 are close to each other allows the batteries 14 to be positioned efficiently in an open space available for a component (that is, the batteries 14) in the body 3 in particular such that the batteries 14 extend to an area backward relative to the body 3 in which area the rear wheels 2 and other components are disposed.
Specifically, the electric motor 12 has a front end within the area of the driver's seat 5 in a plan view. The electric motor 12 is also entirely within the area of the two batteries 14 (which are arranged on opposite sides of the electric motor 12) in a side view. In other words, the batteries 14 are disposed such that the electric motor 12 includes a front end portion backward of the respective front end portions of the batteries 14 (that is, the respective front end faces 14F) and a back end portion forward of the respective back end portions of the batteries 14 (that is, the respective back end faces 14B). The batteries 14 are also disposed such that the electric motor 12 includes an upper end portion below the respective upper end portions of the batteries 14 (that is, the respective upper end faces 14U).
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are disposed such that their respective front end portions (that is, the respective front end faces 14F) each at least overlap with the driver's seat 5 in a plan view. The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are disposed such that their respective back end portions (that is, the respective back end faces 14B) are each at least partially backward of the respective back end portions of the driver's seat 5 and the electric motor 12 in a plan view.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are disposed such that their respective back end portions (that is, the respective back end faces 14B) each overlap the area of the rear wheels 2 in a side view.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) have at least respective back end portions below the cargo box 8.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are disposed such that the back frame member 9C is disposed between the front end portions of the batteries 14 (that is, the respective front end faces 14F) and back end portions of the batteries 14 (that is, the respective back end faces 14B) in a plan view. The two batteries 14 (which are arranged on opposite sides of the electric motor 12) have respective upper end faces 14U below the back frame member 9C.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) may lie obliquely in a plan view relative to the front-back direction L at an angle equal to, larger than, or smaller than the angle at which the back lateral frame members 9D lie obliquely relative to the center line.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) may have respective upper end faces 14U above or below the back lateral frame members 9D. If the batteries 14 have respective upper end faces 14U below the back lateral frame members 9D, the batteries 14 may overlap with the respective back lateral frame members 9D in a plan view.
The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are inward of the respective outermost end portions of the lateral frame members 9A in a front view.
(1) The batteries 14, which are arranged on opposite sides of the electric motor 12, are not necessarily symmetrical to each other, and may be oriented in any manner.
The batteries 14, which are arranged on opposite sides of the electric motor 12, lie obliquely relative to the front-back direction L preferably but not necessarily at an equal angle. Further, the batteries 14, which are arranged on opposite sides of the electric motor 12, do not necessarily both lie obliquely: At least one of the batteries 14 may lie not obliquely.
The batteries 14, which are arranged on opposite sides of the electric motor 12, may lie obliquely such that their respective portions further backward relative to the body 3 are closer to or farther from each other.
(2) The utility vehicle not necessarily includes two batteries 14, and may alternatively include three or more batteries 14 to constitute a battery system. In this case, at least two of those batteries 14 are arranged on opposite sides of the electric motor 12.
(3) The two batteries 14 (which are arranged on opposite sides of the electric motor 12) are not necessarily of an identical model, and may alternatively be of different models. The batteries 14 are, however, preferably of an identical model if they are arranged to be symmetrical to each other.
(4) The electric motor 12 may have a front end portion within the area of, forward of, or backward of the driver's seat 5 in a plan view. The electric motor 12 may have any position relative to the driver's seat 5.
(5) The batteries 14, which are arranged on opposite sides of the electric motor 12, may have respective back end portions (that is, the back end faces 14B) backward of a back end portion of the electric motor 12. The batteries 14 may have respective back end portions (that is, the back end faces 14B) not backward of a back end portion of the electric motor 12 if the electric motor 12 is large in the front-back direction or if the batteries 14 ensure a sufficient charging capacity (that is, if the batteries 14 may be short).
(6) The batteries 14, which are arranged on opposite sides of the electric motor 12, may have respective front end portions (that is, the front end faces 14F) lateral to the electric motor 12 and backward of a front end portion of the electric motor 12 in a plan view. The batteries 14 may alternatively have respective front end portions (that is, the front end faces 14F) protruding forward from a front end portion of the electric motor 12. In this case, the front axle 18 is between the batteries 14. Arranging the batteries 14 laterally to and across the front axle 18 allows the front axle 18 to be positioned appropriately and the batteries 14 to be positioned efficiently in an area where the front axle 18 is absent.
(7) The batteries 14 may have respective back end portions (that is, the back end faces 14B) within the area of, forward of, or backward of the rear wheels 2 in a side view.
(8) The batteries 14, which are arranged on opposite sides of the electric motor 12, are not necessarily below the cargo box 8, and may alternatively be forward of the cargo box 8 in a plan view. The batteries 14 may have any position relative to the cargo box 8.
(9) The batteries 14, which are arranged on opposite sides of the electric motor 12, may be below the back frame member 9C (that is, in a space including a space directly below the back frame member 9C), and may alternatively be forward or backward of the back frame member 9C in a plan view.
(10) The batteries 14 may be arranged laterally relative to the body 3 not across the electric motor 12 or lie obliquely relative to the front-back direction L of the body 3 not across the electric motor 12.
(11) The batteries 14, which are arranged on opposite sides of the electric motor 12, may each have a rectangular parallelepiped outer shape or any other outer shape.
(12) The utility vehicle as each of the embodiments above is not necessarily an electric vehicle configured to travel with use of the electric motor 12 alone, and may alternatively be a hybrid electric vehicle configured to travel with use of the electric motor 12 and an engine.
(13) The electric vehicle as each of the embodiments above of the present invention is not necessarily a utility vehicle, and may alternatively be a work vehicle provided with an implement for agricultural or other work and configured to perform various types of work while traveling.
The present invention is applicable to any of various electric vehicles configured to travel with use of an electric motor.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2023-133495 | Aug 2023 | JP | national |
