阅读说明：本技术 电池组 (Battery pack ) 是由 竹内博 于 2020-09-29 设计创作，主要内容包括：本发明提供电池组。其目的在于将电池组紧凑地构成,同时防止正极部件和负极部件的短路而不增加部件数量。内部单元具有：包括多个电池单元的电池单元群、保持所述电池单元群的保持件和与所述保持件连接的平台。所述平台包括：由正极侧电装品的端子部或正极侧回路部件构成的正极部件和由负极侧电装品的端子部或负极侧回路部件构成的负极部件相邻地配置的绝缘性的主表面；和从所述主表面突出并将所述正极部件和所述负极部件之间隔开的绝缘性的隔开部。(The invention provides a battery pack. The purpose is to compactly configure a battery pack, and prevent short-circuiting of a positive electrode member and a negative electrode member without increasing the number of components. The internal unit has: the battery pack includes a battery cell group including a plurality of battery cells, a holder holding the battery cell group, and a platform connected to the holder. The platform includes: a positive electrode member formed of a terminal portion of the positive electrode-side electrical component or the positive electrode-side circuit member and a negative electrode member formed of a terminal portion of the negative electrode-side electrical component or the negative electrode-side circuit member, which are adjacently disposed; and an insulating partition portion that protrudes from the main surface and partitions the positive electrode member and the negative electrode member.)

1. A battery pack is characterized by comprising a case and an internal unit accommodated in the case,

the internal unit has: a battery cell group including a plurality of battery cells, a holder for holding the battery cell group, a platform connected to the holder, a plurality of electric components mounted on the platform, a plurality of circuit members mounted on the platform, and at least one metal fastener for fixing at least one of the plurality of electric components and the plurality of circuit members,

the plurality of electrical components includes: a positive electrode side electric component electrically connected to the positive electrode side of the battery cell group; and a negative electrode side electric component electrically connected to the negative electrode side of the battery cell group,

the plurality of circuit components includes: a positive electrode side circuit member electrically connected to the positive electrode side of the battery cell group; and a negative electrode side circuit member electrically connected to the negative electrode side of the battery cell group,

the platform includes: an insulating main surface on which a positive electrode member formed of the terminal portion of the positive electrode-side electrical component or the positive electrode-side circuit member and a negative electrode member formed of the terminal portion of the negative electrode-side electrical component or the negative electrode-side circuit member are adjacently disposed; and an insulating partition portion that protrudes from the main surface and partitions the positive electrode member and the negative electrode member.

2. The battery pack according to claim 1,

the platform has: a first plate portion fixed to the holder, a second plate portion provided apart from and in parallel with the first plate portion, and a pillar portion fixing the second plate portion to the first plate portion,

the plurality of electrical components includes: a first electric component mounted on the first plate portion and a second electric component mounted on the second plate portion,

the second electrical component is the positive electrode side electrical component and the negative electrode side electrical component,

the second plate portion includes the main surface and the partition portion.

3. The battery pack according to claim 2,

the battery pack further includes:

a battery-side bus bar having one end portion disposed between the first plate portion and the holder, and electrically connected to the battery cell group;

a current sensor disposed between the first plate portion and the second plate portion and having a detection hole; and

the conductive ring is inserted into the detection hole of the current sensor;

at least one of the fasteners includes a bolt inserted through the conductive ring,

the positive-side circuit member or the negative-side circuit member has an electric component-side bus bar arranged on the main surface of the second plate portion,

the first plate portion and the second plate portion have insertion holes that overlap the detection holes of the current sensor,

the battery-side bus bar and the electric component-side bus bar have insertion holes that overlap the insertion holes of the first plate portion, the insertion holes of the second plate portion, and the detection holes of the current sensors,

the conductive ring is inserted into the detection hole and is inserted into the insertion hole of the first plate portion and the insertion hole of the second plate portion,

the conductive ring abuts against the battery-side bus bar and the electric component-side bus bar in a state where the bolt is inserted through the insertion hole to fasten the battery-side bus bar, the first plate portion, the second plate portion, and the electric component-side bus bar together.

4. The battery pack according to claim 2 or 3,

the second plate portion has an opening formed therein,

the second electrical component includes a relay device disposed in the opening and exposed to the first plate portion side of the main surface.

5. The battery pack according to claim 4,

the relay device has an outer peripheral surface,

the second plate portion has a peripheral end edge defining the opening,

at least a part of the peripheral end edge has a shape along the outer peripheral surface so as to reduce an opening width from the main surface side toward the first plate portion side.

6. The battery pack according to claim 4 or 5,

the second plate portion has a seat portion protruding from the main surface so as to face a bottom surface of the relay device,

the relay device is mounted on the seat.

7. The battery pack according to any one of claims 1 to 6,

the internal unit further has a damper sandwiched between the holder and the housing,

the tip end of the partition portion approaches the housing with a gap formed therebetween.

8. The battery pack according to any one of claims 1 to 7,

the platform has at least one nut insert molded.

Technical Field

The present invention relates to a battery pack.

Background

Patent document 1 discloses a motorcycle which is a hybrid vehicle mounted with a battery. The battery stores electric power supplied to the EV travel motor.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2015-77887.

Disclosure of Invention

Problems to be solved by the invention

Batteries and their associated electrical components are preferably compact in order to sufficiently secure space for other devices. When a compact battery pack is constructed, the positive-side member and the negative-side member may be disposed close to each other. Further, each member is often fixed by a metal fastener, and it is necessary that the detached fastener does not short-circuit the positive-side member and the negative-side member even if the fastener is detached. In order to prevent short-circuiting, it is conceivable to provide an insulating protective member, but in this case, the number of components increases.

It is therefore an object of the present invention to compactly construct a battery pack while preventing short-circuiting of a positive electrode member and a negative electrode member without increasing the number of components.

Means for solving the problems

A battery pack according to an aspect of the present invention includes a case and an internal unit housed in the case, the internal unit including: a battery cell group including a plurality of battery cells, a holder holding the battery cell group, a platform connected to the holder, a plurality of electric components mounted on the platform, a plurality of circuit members mounted on the platform, and at least one metal fastener fixing at least one of the plurality of electric components and the plurality of circuit members, wherein the plurality of electric components include: a positive electrode side electric component electrically connected to the positive electrode side of the battery cell group; and a negative electrode side electric component electrically connected to a negative electrode side of the battery cell group, the plurality of circuit members including: a positive electrode side circuit member electrically connected to the positive electrode side of the battery cell group; and a negative side circuit member electrically connected to a negative side of the battery cell group, the stage including: an insulating main surface on which a positive electrode member formed of the terminal portion of the positive electrode-side electrical component or the positive electrode-side circuit member and a negative electrode member formed of the terminal portion of the negative electrode-side electrical component or the negative electrode-side circuit member are adjacently disposed; and an insulating partition portion that protrudes from the main surface and partitions the positive electrode member and the negative electrode member.

According to the above configuration, even if the metal fastener falls off in a densely arranged structure such as an electric component and a circuit member, the positive electrode member and the negative electrode member can be prevented from being short-circuited by the fastener by the partition portion of the land. Therefore, the battery pack can be constructed compactly while preventing short-circuiting of the positive electrode member and the negative electrode member on the stage without increasing the number of components.

Effects of the invention

According to the present invention, it is possible to compactly construct the battery pack while preventing short-circuiting of the positive electrode member and the negative electrode member without increasing the number of members.

Drawings

Fig. 1 is a side view of a motorcycle according to an embodiment;

fig. 2 is a perspective view of the battery pack mounted on the motorcycle shown in fig. 1, as viewed from the rear and upper side;

fig. 3 is a perspective view of the battery pack shown in fig. 2 as viewed from the rear lower side with the lid removed;

FIG. 4 is a rear view of the battery pack shown in FIG. 3;

fig. 5 is a longitudinal sectional view of the battery pack shown in fig. 3;

FIG. 6 is a perspective view of the platform shown in FIG. 3, as viewed from below the second plate portion and the post portion;

FIG. 7 is a perspective view of the platform shown in FIG. 3, as viewed from above the second plate portion and the post portion;

fig. 8 is a sectional view of a relay device of the battery pack shown in fig. 3 and its vicinity;

description of the symbols:

15 Battery pack

20 casing

21 casing body

22 cover

26 positive side cable

26a terminal portion

27 negative side cable

27a terminal portion

28 vibration damper

30 inner unit

33 group of battery cells

33a battery unit

34 holder

35 platform

36 BMS (first electric installation)

37c terminal portion

37 Relay device (second electric device; positive side electric device)

37b, 37c terminal portions

38 fuse device (second electric device; positive side electric device)

38b and 38c terminal portions

39 Current sensor (cathode side electric installation)

39b inspection hole

40 first Positive electrode Electrical device side bus bar (Positive electrode side Circuit Member)

41 second Positive electrode Electrical component side bus bar (Positive electrode side Circuit Member)

42 third Positive electrode Electrical device side bus bar (Positive electrode side Circuit Member)

43 negative electrode electric fitting side bus bar (negative electrode side circuit component)

44 conductive ring

45 positive electrode battery side bus bar

46 negative battery side bus bar

46a one end portion

51 first plate part

52 second plate part

52a outer surface (main surface)

52b partition part

52c opening

52d seat

52e peripheral end edge

52ea opposite part

52f inner surface

53 pillar part

B1 first bolt (fastener)

B2 second bolt (fastener)

G gap

H1-H4 through hole

N1 first nut

N2 second nut

W opening width.

Detailed Description

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

Fig. 1 is a side view of a motorcycle 1 according to an embodiment. As shown in fig. 1, a motorcycle 1 is a hybrid vehicle as an example of a vehicle. The motorcycle 1 includes: front wheels 2 (driven wheels), rear wheels 3 (driving wheels), a vehicle body frame 4, a front suspension 5 connecting the front wheels 2 to a front portion of the vehicle body frame 4, and a rear suspension (not shown) connecting the rear wheels 3 to a rear portion of the vehicle body frame 4. A steering shaft (not shown) connected to a handlebar 7 is connected to a bracket 6 connected to the front suspension 5. The steering shaft is supported in an angularly displaceable manner on a head pipe 4a that is a part of the vehicle body frame 4.

The vehicle body frame 4 includes: a main frame 4b extending rearward from the head pipe 4a, a seat support frame 4c extending rearward from the upper rear portion of the main frame 4b, and an auxiliary frame 19 extending from the lower portion of the main frame 4b to a middle portion of the seat support frame 4c and supporting the seat support frame 4c from below. A fuel tank 8 is provided behind the handle 7, and a seat 9 on which a driver sits is provided behind the fuel tank 8. The seat 9 is supported by the seat support frame 4 c. An engine E as a driving power source is mounted on the main frame 4b between the front wheels 2 and the rear wheels 3. An electric motor M as a driving power source is disposed in the vicinity of the engine E.

The crankcase 10 extends rearward from a lower portion of the cylinder Eb of the engine E. An electric motor M for driving that generates traveling power to be transmitted to the drive wheels is disposed behind the cylinder Eb of the engine E and above the crankcase 10. The electric motor M is supported by the main frame 4b through the crankcase 10. The inverter (inverter) 12 is integrally provided with the electric motor M, but may be disposed at a position apart from the electric motor M.

A transmission 11 including an input shaft 11a and an output shaft 11b is disposed inside the crankcase 10. The power is transmitted from a crankshaft Ea of the engine E to the input shaft 11a through a gear and a main clutch (not shown). Power is transmitted from the electric motor M to the input shaft 11a of the transmission 11 through a power transmission mechanism not shown. That is, the power of both the engine E and the electric motor M is transmitted to the input shaft 11 a. The motorcycle 1 is not limited to the parallel hybrid system, and may be a series hybrid system. A swing arm 13 that supports the rear wheel 3 and extends in the front-rear direction is supported by the vehicle body frame 4 so as to be angularly displaceable. The rotational power of the output shaft 11b of the transmission 11 is transmitted to the rear wheel 3 through an output transmission member 14 (e.g., a chain, a belt, etc.).

A battery pack 15 supported by the seat support frame 4c is disposed behind the electric motor M. That is, the battery pack 15 is disposed below the seat 9. By disposing the battery pack 15 of the drive train that stores the electric power supplied to the electric motor M below the seat 9, the battery pack 15 as a heavy object can be positioned near the center of gravity of the motorcycle 1. The battery pack 15 stores electric power supplied to the electric motor M. A DCDC converter 16 supported by the seat support frame 4c is disposed behind the battery pack 15. The DCDC converter 16 lowers the voltage of the electric power output from the battery pack 15.

An auxiliary battery 17 supported by the seat support frame 4c is disposed behind the DCDC converter 16. The electric power from the battery pack 15 is stepped down by the DCDC converter 16 and supplied to the auxiliary battery 17. That is, the battery pack 15 outputs high-voltage electric power for driving the electric motor M as a travel driving source, while the auxiliary battery 17 outputs low-voltage electric power to be supplied to electric components (e.g., ECU).

The lower end of the battery pack 15 is located below and forward of the upper end of the rear wheel 3. A part of the battery pack 15 is located on the lower side of the seat support frame 4 c. The battery pack 15, the DCDC converter 16, and the auxiliary battery 17 are covered from below by a rear fender 18 facing the rear wheel 3. The rear fender 18 is supported by the seat support frame 4 c. The front portion of the rear fender 18 covers the rear surface and the bottom surface of the battery pack 15. The battery pack 15 is disposed on the vehicle width direction inner side of the seat support frame 4c and the sub-frame 19. A pair of opposite side surfaces (left and right surfaces) of the battery pack 15 facing each other in the vehicle width direction are exposed to the outside of the motorcycle 1. That is, both side surfaces of the battery pack 15 in the vehicle width direction are exposed when the motorcycle 1 is viewed from the side, and directly hit the traveling wind.

Fig. 2 is a perspective view of the battery pack 15 mounted on the motorcycle 1 of fig. 1 as viewed from the rear and upper side. In the following description, the orientation (posture) of the state in which the battery pack 15 is mounted on the motorcycle 1 defines a direction, but the orientation of the battery pack 15 is not limited to this. As shown in fig. 2, the battery pack 15 includes a substantially rectangular parallelepiped case 20. The housing 20 includes a housing main body 21 and a cover 22. The case main body 21 has a hexahedral shape with an open rear surface, and a battery assembly 31 (see fig. 3) described later is disposed in an internal space of the case main body 21.

The cover 22 closes the inner space of the housing body 21 from the rear, and constitutes a rear wall of the housing 20. The lid 22 has a concave shape, and an electric component assembly 32 (see fig. 3) described later is disposed in an internal space of the lid 22. The lid 22 is provided with a positive electrode-side connector 23 and a negative electrode-side connector 24 electrically connected to an internal unit 30 described later. It is preferable that the housing main body 21 has heat radiating fins on both side walls.

Fig. 3 is a perspective view of the battery pack 15 shown in fig. 2 as viewed from the rear lower side with the cover 22 removed. Fig. 4 is a rear view of the battery pack 15 shown in fig. 3. Fig. 5 is a longitudinal sectional view of the battery pack 15 shown in fig. 3. Fig. 6 is a perspective view of the platform (platform) 35 shown in fig. 3, as seen from below the second plate portion 52 and the support portion 53. Fig. 7 is a perspective view of the second plate portion 52 and the column portion 53 of the platform 35 shown in fig. 3. Fig. 8 is a sectional view of the relay device 37 of the battery pack 15 shown in fig. 3 and its vicinity.

As shown in fig. 3 to 5, the internal unit 30 is accommodated in the case 20 of the battery pack 15 in an accessible manner. The internal unit 30 includes a battery assembly 31 and an electrical component assembly 32. The electrical component assembly 32 is disposed on a side (e.g., rear) of the battery assembly 31. Thereby, an increase in the height dimension of the inner unit 30 can be suppressed.

The battery assembly 31 includes a battery cell group 33 and a holder 34. The battery assembly 31 has a substantially rectangular parallelepiped shape as a whole. The battery cell group 33 includes a plurality of battery cells 33 a. The battery cells 33a have a substantially cylindrical shape, and are arranged to form a group having a substantially rectangular parallelepiped shape and are electrically connected to each other. The holder 34 is made of an insulating resin and holds the battery cell group 33.

The electrical component assembly 32 includes: the battery module includes a stage 35, a BMS36, a relay device 37, a fuse device 38, a current sensor 39, a first positive-electrode electrical-equipment-side bus bar 40, a second positive-electrode electrical-equipment-side bus bar 41, a third positive-electrode electrical-equipment-side bus bar 42, a negative-electrode electrical-equipment-side bus bar 43, a plurality of first bolts B1 (fasteners), a second bolt B2 (fasteners), a conductive coil (collar) 44, a positive-electrode battery-side bus bar 45, and a negative-electrode battery-side bus bar 46.

The stage 35 is a stage on which the electric component is mounted, and is connected to the holder 34. The stage 35 is formed of an insulating resin. The platform 35 is disposed along a side surface (for example, a rear surface) of the battery assembly 31. The platform 35 is mounted with a BMS (Battery Management System) 36, a relay device 37, a fuse device 38, and a current sensor 39 as electrical components. The platform 35 is mounted with a first positive electrode electrical component side bus bar 40, a second positive electrode electrical component side bus bar 41, a third positive electrode electrical component side bus bar 42, and a negative electrode electrical component side bus bar 43 as circuit members.

Specifically, the platform 35 has a two-layer structure including a first plate portion 51, a second plate portion 52, and a plurality of strut portions 53. The first plate portion 51 and the second plate portion 52 are disposed parallel to and spaced apart from each other, and are connected to each other by a plurality of stay portions 53. The first plate portion 51 is fixed to the holder 34. The first plate portion 51 and the second plate portion 52 are parallel to the rear surface of the battery assembly 31.

BMS36 (first electrical component) and a circuit pattern (not shown) connected thereto are mounted on an outer surface (rear surface) of the first plate portion 51. The current sensor 39 (first electrical component) is disposed in a state of being mounted on the first plate portion 51 in a gap between the first plate portion 51 and the second plate portion 52. The relay device 37 (second electrical component; positive-side electrical component) and the fuse device 38 (second electrical component; positive-side electrical component) are mounted on the outer surface (rear surface) of the second plate portion 52.

The relay device 37 includes a housing 37a and a pair of terminal portions 37b and 37 c. A relay (not shown) is housed in the case 37 a. The housing 37a has a substantially cylindrical outer shape having an outer peripheral surface, an upper surface, and a bottom surface. A pair of terminal portions 37b, 37c are provided on the upper surface of the housing 37 a. The fuse device 38 includes a housing 38a and a pair of terminal portions 38b and 38 c. A fuse element (not shown) is accommodated in the housing 38 a. The terminal portions 38b project upward from the housing 38a, and the terminal portions 38c project downward from the housing 38 a. The relay device 37 and the fuse device 38 are arranged in parallel with each other.

First to third positive-electrode electrical-component-side bus bars 40 to 42 (electrical-component-side bus bars; positive-electrode-side circuit members) are disposed on the outer surface (main surface) of the second plate portion 52. The first positive electrode electrical component side bus bar 40 connects one end portion of the positive electrode battery side bus bar 45 to the terminal portion 38c of the fuse device 38. The other end of the positive battery side bus bar 45 is electrically connected to the positive side of the battery cell group 33. The second positive-electrode electric-component-side bus bar 41 connects the terminal portion 38b of the fuse device 38 and the terminal portion 37c of the relay device 37. The third positive-electrode electrical-equipment-side bus bar 42 connects the terminal portion 37b of the relay device 37 to the terminal portion 26a of the positive-electrode-side cable 26.

The positive-side cable 26 extends in the vertical direction along the outer surface of the second plate portion 52 on one side in the lateral direction of the platform 35. The positive-side connector 23 is provided at the upper end of the positive-side cable 26, and the terminal 26a is provided at the lower end of the positive-side cable 26.

On the other side in the left-right direction of the platform 35, the negative-side cable 27 extends in the up-down direction along the outer surface of the second plate portion 52. The negative electrode side connector 24 is provided at the upper end of the negative electrode side cable 27, and the terminal portion 27a is provided at the lower end of the negative electrode side cable 27. The negative-electrode electric component-side bus bar 43 (electric component-side bus bar; negative-electrode-side circuit member) is provided on the outer surface of the second plate portion 52. One end of the negative-electrode electrical component-side bus bar 43 is connected to the terminal portion 27a of the negative-electrode-side cable 27. The other end of the negative-electrode-component-side bus bar 43 is electrically connected to one end of the negative-electrode-battery-side bus bar 46 by a second bolt B2 and a conductive ring 44, which will be described later. The other end of the negative-electrode battery-side bus bar 46 is electrically connected to the negative electrode side of the battery cell group 33.

The relay device 37, the fuse device 38, the first to third positive electrode electrical component side bus bars 40 to 42, the negative electrode electrical component side bus bar 43, and the terminal portions 26a and 27a are fixed to the second plate portion 52 by first metal bolts B1. The terminal portion 27a of the negative-electrode-side cable 27 and the negative-electrode-battery-side bus bar 46 (negative electrode member) are disposed adjacent to and close to the terminal portion 38c of the fuse device 38 and the first positive-electrode-electric-component-side bus bar 40 (positive electrode member).

As shown in fig. 3, 4, 6, and 7, the second plate portion 52 is formed by integrally molding an insulating resin. The second plate portion 52 is insert-molded (insert molding) with a plurality of first nuts N1 at positions corresponding to the first bolts B1. The second plate portion 52 has a partition portion 52b protruding from a predetermined position on the outer surface 52a (main surface) thereof. The partition portion 52b has a plate shape. Since the second plate portion 52 is formed of an insulating resin, the outer surface 52a and the partition portion 52b have insulation properties.

The partition portion 52b extends so as to pass through a gap between the positive electrode member formed by the terminal portion 38c of the fuse device 38 and the first positive electrode electric component side bus bar 40 and the negative electrode member formed by the terminal portion 27a of the negative electrode side cable 27 and the negative electrode battery side bus bar 46. That is, the partition portion 52b partitions the positive electrode member and the negative electrode member. The protruding height of the partition 52b from the outer surface 52a of the second plate 52 is higher than the maximum height of the positive electrode member and the negative electrode member from the outer surface 52a of the second plate 52.

At least the upper side portion of the partition portion 52b extends in the vertical direction. For example, the partition portion 52b extends in the vertical direction over an area greater than 70% (preferably, an area greater than 80%) in a range from the upper end to the lower end of the outer surface 52a of the second plate portion 52. The positive electrode member adjacent to one side in the left-right direction of the separator 52b and the negative electrode member adjacent to the other side in the left-right direction of the separator 52b extend in the vertical direction over a region greater than 70% (preferably greater than 80%) in the range from the upper end to the lower end of the outer surface 52 a. The first nut N1 for fixing the one end portion of the negative-electrode electrical-equipment-side bus bar 43 and the terminal portion 27a of the negative-electrode-side cable 27 from the side by the first bolt B1 is fitted into the partitioned portion 52B toward the side.

An opening 52c is formed in the second plate portion 52 at a position corresponding to the relay device 37. The opening 52c has a substantially quadrangular shape in plan view. The second plate portion 52 has a seat portion 52d protruding from the outer surface 52a below the opening 52 c. The seat portion 52d faces the bottom surface of the case 37a of the relay device 37 from below. The seat portion 52d has a three-dimensional configuration including a rib configuration, and has a thickness greater than that of the partition portion 52 b. A first nut N1 for fixing the housing 37a of the relay device 37 by a first bolt B1 is fitted into the seat 52 d. The relay device 37 is fixed to the seat 52d in a state of being placed on the seat 52d from above.

The internal unit 30 has a damper (damper) 28 sandwiched between a holder 34 and the housing main body 21. The partition portion 52b of the second plate portion 52 and the tip end (projecting end) of the seat portion 52d approach the cover 22 with a gap G formed therebetween. The gap G between the cover 22 and the partition 52B is smaller in size than the minimum thickness of the bolt B1.

As shown in fig. 7 and 8, the second plate portion 52 has a peripheral end edge 52e defining an opening 52 c. The facing portion 52ea of the peripheral edge 52e, which faces the outer peripheral surface of the case 37a of the relay device 37, has a shape along the outer peripheral surface of the case 37 a. Specifically, the facing portion 52ea has a tapered shape (tapered shape) that decreases the opening width W from the outer surface 52a side to the inner surface 52f side (first plate portion 51 side). The relay device 37 is disposed in the opening 52c and exposed to the first plate portion 51 side of the outer surface 52a of the second plate portion 52. Thus, the amount h of projection of the relay device 37 from the outer surface 52a of the second plate portion 52 is smaller than the outer diameter D of the relay device 37.

Returning to fig. 3 to 5, the current sensor 39 disposed between the first plate portion 51 and the second plate portion 52 has a detection hole 39b formed in the housing 39a thereof. The detection hole 39b opens to the first plate 51 and the second plate 52. The current sensor 39 is of a non-contact type (for example, a hall element type, a CT type, or the like), and detects a current by using a magnetic force caused by the current passing through the conductor of the detection hole 39 b.

Insertion holes H1, H2 that overlap the detection hole 39b of the current sensor 39 are formed in the first plate 51 and the second plate 52, respectively. The negative-electrode-electrical-component-side bus bar 43 has an insertion hole H3 that overlaps the insertion hole H2 of the second plate portion 52. The negative-electrode-side bus bar 46 has one end portion 46a disposed between the first plate portion 51 and the holder 34, and an insertion hole H4 that overlaps with the insertion hole H1 of the first plate portion 51 is formed in the one end portion 46 a. A second nut N2 is fitted into the retainer 34, and the hole of the second nut N2 overlaps the insertion hole H4. That is, the holes of the insertion holes H1 to H4 and the second nut N2 overlap the detection hole 39b of the current sensor 39.

The conductive loop 44 is inserted through the detection hole 39b of the current sensor 39 and the insertion holes H1, H2 of the first plate 51 and the second plate 52. The insertion holes H3 and H4 are smaller in diameter than the insertion holes H1 and H2 and the detection hole 39b, and the conductive ring 44 is larger in diameter than the insertion holes H3 and H4 and is interposed between the negative-electrical-component-side bus bar 43 and the negative-battery-side bus bar 46. The conductive ring 44 is a cylindrical body formed of a material having conductivity, such as a metal cylinder.

Second bolts B2 are inserted through the insertion holes H3, H4 and the conductive ring 44, and the second bolts B2 are screwed to nuts N2 of the holder 34. That is, in a state where the negative-electrode-cell-side bus bar 46, the first plate 51, the second plate 52, and the negative-electrode-component-side bus bar 43 are fastened together by the second bolt B2, the conductive coil 44 is brought into contact with and conducted through the negative-electrode-cell-side bus bar 46 and the negative-electrode-component-side bus bar 43.

According to the above configuration, in the electric circuit from the positive-side cable 26 to the negative-side cable 27, the third positive-electrode electrical component-side bus bar 42, the relay device 37, the second positive-electrode electrical component-side bus bar 41, the fuse device 38, the first positive-electrode electrical component-side bus bar 40, the positive-electrode battery-side bus bar 45, the battery cell group 33, the negative-electrode battery-side bus bar 46, the conductive coil 44 (the second bolt B2), and the negative-electrode electrical component-side bus bar 43 are arranged in series in this order.

According to the above-described configuration, even if the first bolt B1 and the second bolt B2 are disengaged in the configuration in which the electrical components such as the relay device 37 and the fuse device 38 and the circuit components such as the bus bars 40 to 43 are densely arranged, the positive electrode member (the terminal portion 38c of the fuse device 38 and the first positive electrode electrical component-side bus bar 40) and the negative electrode member (the terminal portion 27a of the negative electrode-side cable 27 and the negative electrode battery-side bus bar 46) can be prevented from being short-circuited by the disengaged bolts by the separating portions 52B of the platform 35. Thereby, the battery pack 15 can be constructed compactly while preventing short-circuiting of the positive side and the negative side on the stage 35 without increasing the number of components.

Further, since the platform 35 has a two-layer structure in which the first plate portion 51 and the second plate portion 52 that are separated from each other are connected by the stay portion 53, a plurality of electric components (the BMS36, the relay device 37, the fuse device 38, the current sensor 39, and the like) can be compactly arranged, and the battery pack 15 can be downsized.

The current sensor 39 measures the current flowing through the conductive ring 44 (and the second bolt B2) that is in contact with and conductive with the negative battery side bus bar 46 and the negative electric component side bus bar 43, thereby measuring the current flowing between the negative electric component side bus bar 43 and the negative battery side bus bar 46. Therefore, the current sensor 39 can be arranged in a compact structure.

Further, since the relay device 37 is disposed in the opening 52c of the second plate portion 52 and is exposed to the first plate portion 51 more than the outer surface 52a of the second plate portion 52, the amount h of projection of the relay device 37 from the second plate portion 52 can be suppressed to be large, and the battery pack 15 can be downsized.

Further, since the opposing portion 52ea of the peripheral end edge 52e of the second plate portion 52 has a tapered shape in which the opening width is reduced from the outer surface 52a side to the inner surface 52f side (the first plate portion 51 side), the amount of projection h of the relay device 37 from the second plate portion 52 can be suppressed while suppressing an excessive increase in the opening width of the second plate portion 52. Therefore, the thickness of the cover 22 (refer to fig. 5) can be reduced. Further, even if the relay device 37 is fixed and detached, the relay device 37 may be caught by the facing portion 52ea of the peripheral end edge 52e of the second plate portion 52.

Since the relay device 37 is placed on the seat portion 52d facing the bottom surface of the relay device 37, the relay device 37 can be stably supported by the seat portion 52d of the second plate portion 52. Further, since the gap G is formed between the tip ends of the partition portion 52b and the seat portion 52d of the platform 35 and the cover 22, it is possible to prevent the partition portion 52b or the seat portion 52d from interfering with the cover 22 and transmitting an impact to the electric component or the like when the damper 28 absorbs vibration. Further, since the second plate portion 52 has the first nut N1 insert-molded and the retainer 34 has the second nut N2 insert-molded, the assembling work is easy and the vibration resistance is good.

The present invention is not limited to the above embodiments, and the configuration thereof may be changed, added, or deleted. For example, the vehicle is not limited to a motorcycle, and may be another vehicle (a saddle-ride type vehicle such as a three-wheeled motor vehicle that is ridden by a rider). Instead of the hybrid vehicle, the vehicle may be an electric vehicle that travels with the driving force of an electric motor without mounting an internal combustion engine. The battery pack may be used as a power source for other purposes (e.g., stationary installation, etc.) in addition to the electric motor of the vehicle.