JP2004087218A - Battery-type power supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a battery-type power supply device capable of uniformly cooling a plurality of rod-shaped battery modules. <P>SOLUTION: The battery-type power supply device 1 is composed of a box 2 having a cooling air lead-in part 16 at one end and a cooling air lead-out part 20 communicating with a suction fan F at the other end, and a battery assembly 3 housed in the box 2. The battery assembly 3 is composed of first to third battery module groups 21<SB>1</SB>-21<SB>3</SB>, and respective battery module groups 21<SB>1</SB>-21<SB>3</SB>are composed of a plurality of rod-shaped battery modules 22. A first air guiding member 36 is arranged at the cooling air lead-in part 16 side of the first battery module group 21<SB>1</SB>. Widths Wa1-Wa8 of a proximity slit 42, all of first slits 38<SB>1</SB>, and remote slit 43, in the direction of crossing the axial line of the rod-shaped battery module, are gradually reduced from the proximity slit 42 toward the remote slit 43. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a battery type power supply device, and more particularly to a power supply device having a battery assembly, which is mounted on a battery car, a hybrid car, a fuel cell vehicle, or the like and used as a power source. Here, the concept of a battery includes those having various power storage functions, such as a large-capacity electric double-layer capacitor, in addition to a primary battery and a secondary battery.
[0002]
[Prior art]
Conventionally, as this type of battery type power supply, there is known a type in which a dedicated cooling air duct and a plurality of cooling members are arranged in a battery assembly to cool a plurality of rod-shaped battery modules constituting the battery assembly. (See, for example, JP-A-10-255859).
[0003]
[Problems to be solved by the invention]
However, in the conventional device, it is difficult to reduce the size because the cooling duct and the like prevent the space between the rod-shaped battery modules from being narrowed, and the increase in manufacturing cost is inevitable due to the large number of components.
[0004]
[Means for Solving the Problems]
SUMMARY OF THE INVENTION It is an object of the present invention to provide a battery-type power supply device capable of reducing the size and manufacturing cost and cooling a plurality of rod-shaped battery modules substantially uniformly.
[0005]
According to the present invention, there is provided a box having a cooling air inlet at one end and a cooling air outlet at the other end, and a battery assembly installed in the box. The battery assembly has first to third battery module groups arranged in parallel with each other along the cooling air flow direction and at an interval. A plurality of rod-shaped battery modules that intersect with the cooling air flow direction in a virtual intersection plane that intersects with the flow direction and are arranged at intervals; The two axis lines of the other rod-shaped battery module are located in an imaginary parallel plane parallel to the flow direction of the cooling air, and the cooling air introduction part is provided with the first battery module group and the first battery module. A cooling air introduction passage, which is located between the first component plates facing a group of the boxes and constitutes a part of the box, and a cooling air introduction opening at one end of the cooling air introduction passage. A cooling wind deriving section, which is provided between the third battery module group and the second battery module group, which faces the third battery module group, and which is located between the second component plates forming a part of the box; A battery-type power supply device having a cooling air outlet located at an end opposite to the cooling air inlet in the outlet path, and is arranged on the cooling air inlet path side of the first battery module group. A first wind guide member, a second wind guide member arranged between the second and third battery module groups, and a third wind guide arranged on the cooling air outlet side of the third battery module group. The first wind guide The material extends in the axial direction of the plurality of rod-shaped battery modules of the first battery module group, and is located between the plurality of air guide plates spaced apart from the rod-shaped battery modules and between the adjacent wind guide plates. And a plurality of slits facing the space between the adjacent rod-shaped battery modules, and the outer diameter of the rod-shaped battery module is d, and the width of the baffle plate corresponding to the outer diameter d is w ₁ And w ₁ ≧ d, the second air guide member has a plurality of slits facing the outer peripheral surface of each rod-shaped battery module of the second and third battery module groups, and the outer diameter d of the rod-shaped battery module and its outer diameter d The width w of the slit corresponding to ₂ And d> w ₂ The third wind guide member has a plurality of slits facing the outer peripheral surface of each rod-shaped battery module of the third battery module group, and corresponds to the outer diameter d of the rod-shaped battery module and its outer diameter d. The width w of the slit ₃ And d> w ₃ And there is a proximity slit between the baffle plate closest to the cooling air inlet and a third component plate adjacent to the baffle plate and forming part of the box. A remote slit between the air guide plate farthest from the air inlet and the fourth component plate which is adjacent to the air guide plate and constitutes a part of the box; A battery-type power supply device is provided in which the width of all the slits of the member in a direction intersecting the axial direction of the rod-shaped battery module gradually decreases from the proximity slit to the remote slit.
[0006]
The configuration in which the cooling air introduction passage, the battery assembly, and the cooling air outlet passage are stacked as described above helps to reduce the size of the battery-type power supply device. However, when the air in the battery assembly is sucked from the cooling air outlet and the cooling air is circulated through the introduction path, the battery assembly, and the outlet path, the air near the outlet in the battery assembly is discharged. Is preferentially sucked out, so that there is a problem that the cooling air is preferentially introduced to a side far from the introduction port in the introduction path.
[0007]
Therefore, the widths of the close slit, the entire slit in the first air guide member, and the width of the remote slit are adjusted as described above, so that approximately equal amounts of cooling air can be introduced from each slit into the battery assembly. It is.
[0008]
Then, in the first battery module group, each rod-shaped battery module is cooled by exposing approximately two-fourths of its outer peripheral surface to cooling air flowing on both sides thereof, and in the second battery module group, each rod-shaped battery module is cooled. The rod-shaped battery module is cooled by exposing approximately three quarters of its outer peripheral surface to cooling air flowing on both sides thereof and flowing into the slit of the second air guide member. The rod-shaped battery module passes through the slit of the second air guide member, flows along the outer peripheral surface of the rod-shaped battery module, and finally exposes the entire outer peripheral surface to cooling air flowing into the slit of the third rectifying plate. Cooled by.
[0009]
Although the cooling capacity of the cooling air decreases during the period from the first battery module group to the third battery module group via the second battery module group, the area of the rod-shaped battery module exposed to the cooling air increases accordingly. , All the rod-shaped battery modules can be cooled almost uniformly.
[0010]
In the battery power supply device, the width of all the third slits of the third air guide member in the direction intersecting with the axial direction of the rod-shaped battery module is set such that the width of the third air slit is the farthest from the cooling air outlet and the cooling air is introduced from the third slit. It may gradually decrease over the third slit closest to the outlet.
[0011]
According to the present invention, the following is also provided as a battery-type power supply capable of obtaining the same effects as described above.
[0012]
That is, according to the present invention, there is provided a box having a cooling air introduction part at one end and a cooling air derivation part at the other end, and a battery assembly installed in the box. , Having first to third battery module groups arranged in parallel with each other along the cooling air flow direction and spaced from each other, and the first to third battery module groups have their axes intersecting with the cooling air flow direction. A plurality of rod-shaped battery modules that are arranged at equal intervals in the virtual intersection plane so as to intersect with the cooling air flow direction. Both axes are located in an imaginary parallel plane parallel to the cooling air flow direction, and the cooling air introduction unit faces the first battery module group and the first battery module group, and A cooling air introduction passage between the first component plates constituting a part of the cooling air supply passage, and a cooling air introduction opening at one end of the cooling air introduction passage. A cooling air outlet path between the third battery module group and the third battery module group and between the second component plates constituting a part of the box; and a cooling air outlet path in the cooling air outlet path. A battery-type power supply device having a cooling air outlet at an end opposite to the mouth, a first air guide member disposed on the cooling air introduction path side of the first battery module group; A second air guide member arranged between the second and third battery module groups; and a third air guide member arranged on the cooling air outlet path side of the third battery module group, The wind guide member is the first battery. A plurality of air guide plates extending in the axial direction of the plurality of rod-shaped battery modules of the joule group and facing the rod-shaped battery modules at an interval; and two adjacent rod-shaped batteries between the adjacent air guide plates. The rod-shaped battery module has a plurality of first slits facing the space between the modules, and the outer diameter of the rod-shaped battery module is d, and the width of the air guide plate corresponding to the outer diameter d is w. ₁ And w ₁ ≧ d, the second wind guide member has a plurality of second slits facing the outer peripheral surface of each rod-shaped battery module of the second and third battery module groups, and has an outer diameter d of the rod-shaped battery module and an outer diameter d. The width w of the slit corresponding to the diameter d ₂ And d> w ₂ The third wind guide member has a plurality of third slits facing the outer peripheral surface of each rod-shaped battery module of the third battery module group, and has an outer diameter d of the rod-shaped battery module and an outer diameter d thereof. The width w of the corresponding slit ₃ And d> w ₃ And there is a proximity slit between the baffle plate closest to the cooling air inlet and a third component plate adjacent to the baffle plate and forming part of the box. There is a remote slit between the air guide plate farthest from the air inlet and the fourth component plate adjacent to the air guide plate and constituting a part of the box, and in all the third slits of the third air guide member. A battery-type power supply device in which a width in a direction intersecting with the axial direction of the rod-shaped battery module gradually decreases from the third slit farthest from the cooling air outlet to the third slit closest to the cooling air outlet. Is provided.
[0013]
Further, according to the present invention, there is provided a box having a cooling air introduction section at one end and a cooling air outlet section at the other end, and a battery assembly installed in the box, and the battery assembly includes: It has first to third battery module groups arranged in parallel with each other along the cooling air flow direction and at intervals, and the first to third battery module groups intersect their axes with the cooling air flow direction. It is composed of a plurality of rod-shaped battery modules arranged at equal intervals in the virtual intersection plane so as to intersect with the cooling air flow direction. The axis is located in an imaginary parallel plane parallel to the flow direction of the cooling air, and the cooling air introduction unit faces the first battery module group and the first battery module group, and A cooling air introduction passage existing between the first component plates constituting a part of the cooling air flow passage, and a cooling air introduction opening existing at one end of the cooling air introduction passage. A cooling air outlet path between the third battery module group and the third battery module group and between the second component plates constituting a part of the box; and a cooling air outlet path in the cooling air outlet path. A battery-type power supply device having a cooling air outlet at an end opposite to the mouth, a first air guide member disposed on the cooling air introduction path side of the first battery module group; A second air guide member arranged between the second and third battery module groups; and a third air guide member arranged on the cooling air outlet path side of the third battery module group, The wind guide member is provided with the first battery module. A plurality of baffle plates extending in the axial direction of the plurality of bar-shaped battery modules of the module group and facing the bar-shaped battery modules at an interval; and two adjacent rod-shaped batteries interposed between the adjacent baffle plates. The rod-shaped battery module has a plurality of first slits facing the space between the modules, and the outer diameter of the rod-shaped battery module is d, and the width of the air guide plate corresponding to the outer diameter d is w. ₁ And w ₁ ≧ d, the second wind guide member has a plurality of second slits facing the outer peripheral surface of each rod-shaped battery module of the second and third battery module groups, and has an outer diameter d of the rod-shaped battery module and an outer diameter d. The width w of the second slit corresponding to the diameter d ₂ And d> w ₂ The third wind guide member has a plurality of third slits facing the outer peripheral surface of each rod-shaped battery module of the third battery module group, and has an outer diameter d of the rod-shaped battery module and an outer diameter d thereof. The corresponding width w of the third slit w ₃ And d> w ₃ And there is a proximity slit between the baffle plate closest to the cooling air inlet and a third component plate adjacent to the baffle plate and forming part of the box. A remote slit between the air guide plate farthest from the air inlet and the fourth component plate adjacent to the air guide plate and constituting a part of the box; A battery-type power supply device is provided that includes an air volume adjustment plate provided between the third and fourth component plates so as to gradually reduce the opening area of the entire first slit of the member from the proximity slit to the remote slit. .
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
1 and 2, a battery-type power supply device 1 according to a first embodiment includes a box 2 having a substantially rectangular parallelepiped shape, and a battery assembly 3 installed in the box 2. The box 2 includes a steel plate base 4 and a metal (or synthetic resin) cover 5. The base 4 includes a support plate 6 on which the battery assembly 3 arranged in a substantially rectangular parallelepiped block shape is placed, and a shielding plate which rises from one side edge of the support plate 6 and faces one side surface of the battery assembly 3. 7 The support plate 6 has two ridges 8 arranged at an interval. Each ridge 8 is formed at a right angle to the shielding plate 7 and has a flat top surface 9. The height of each ridge 8 is the lowest on the shield plate 7 side, and gradually increases as the distance from the shield plate 7 increases.
[0015]
As shown in FIG. 3, the base 4 is installed such that the top surface 9 of each ridge 8 is horizontal. The remaining three side surfaces of the battery assembly 3 except for the side surface facing the shield plate 7 are covered by the side plate 10 facing the shield plate 7 and the opposite side plates 11 of the cover 5. The side is covered by a ceiling plate 12 of the cover 5. One side of the cover 5 is open, but the opening is closed by a shielding plate 7 except for the upper part.
[0016]
As will be described later, in the box 2, the cooling air is circulated from one end, that is, the upper cooling air introduction side to the other end, that is, the lower cooling air outlet side. The cooling air flow direction A is from top to bottom.
[0017]
As shown in FIG. 4, three battery assemblies 3 are arranged in parallel with each other along the cooling air flow direction A and at intervals, that is, the first to third battery module groups 21. ₁ ~ 21 ₃ Having. Each battery module group 21 ₁ ~ 21 ₃ Is a virtual intersection plane P intersecting the axis with the cooling air flow direction A. ₁ And a plurality of rod-shaped battery modules 22 which intersect with the cooling air flow direction A and are arranged at intervals. In the embodiment, the number of the rod-shaped battery modules 22 is ₁ , 21 ₂ , The third battery module group 21 ₃ There are six. Both axes of one rod-shaped battery module 22 and the other rod-shaped battery 22 adjacent to each other in the cooling air flow direction A are a virtual parallel plane P parallel to the cooling air flow direction A. ₂ Located within. Third battery module group 21 ₃ The reason why the number of the rod-shaped battery modules 22 is reduced by one from that of the others is that the number of the rod-shaped battery modules 22 is an even number because the rod-shaped battery modules 22 are paired for connection.
[0018]
As shown in FIG. 5, each of the rod-shaped battery modules 22 includes a plurality of, in this embodiment, six batteries (secondary batteries) 23 so that both adjacent batteries 23 are connected in series via a connection ring 24. It is a concatenation. In each of the rod-shaped battery modules 22, a positive electrode 25 having a hexagonal shape is protruded from one end surface, and a negative electrode 26 having a rectangular shape is protruded from the other end surface.
[0019]
As shown in FIGS. 3 and 6, the first battery module group 21 ₁ The seven rod-shaped battery modules 22 are supported by two square rod-shaped grommets 27 made of synthetic resin which are arranged at predetermined intervals at two locations in the axial direction. Each grommet 27 includes an upper first half 28 and a lower second half 29. On the mating surfaces 30, 31 of the two halves 28, 29, there are formed seven semicircular concave portions 32, 33 which fit into the outer peripheral surface of the connection ring 24 of each rod-shaped battery module 22. Second battery module group 21 ₂ Between the first battery module group 21 and the two grommet 27 ₁ Is the same as Third battery module group 21 ₃ The six rod-shaped battery modules 22 are held by the grommets 27 in the same manner as described above, and the rod-shaped battery modules 22 do not exist in the circular holding holes formed by the concave portions 32 and 33 adjacent to the shielding plate 7.
[0020]
As shown in FIGS. 3 and 7, the cooling air introduction unit 16 is connected to the first battery module group 21. ₁ And its first battery module group 21 ₁ And a wedge-shaped cooling air introduction passage 15 existing between the ceiling plates 12 as a first component plate constituting a part of the box 2, and one end of the cooling air introduction passage 15, that is, the most of the introduction passage 15. And a cooling air inlet 14 located in a wide area. In the embodiment, the inlet 14 is formed in a flatter rectangular tube shape with an extended portion of the ceiling plate 12, a protruding portion of the side plates 11, and an upper edge plate 13 bent outward from an upper edge of the shielding plate 7. ing.
[0021]
A series of bent edges 17 are formed on both sides of the support plate 6, the shielding plate 7 and the upper edge plate 13 so as to bend upward in the support plate 6, respectively. The inner surfaces of the opposite side plates 11 of the cover 5 are in close contact with each other, and the lower edges of the side plates 10 facing the shielding plate 7 are in contact with the top surfaces 9 of the double ridges 8, respectively.
[0022]
The cooling air deriving unit 20 is connected to the third battery module group 21. ₃ And its third battery module group 21 ₃ And a wedge-shaped cooling air outlet 19 existing between the support plates 6 as a second component plate, which faces the box 2, and the cooling air inlet 14 in the cooling air outlet 19. It has an opposite end, that is, a cooling air outlet 18 located at the widest part of the outlet passage 19. In the embodiment, the lead-out path 19 is divided into three by the double ridges 8, and the lead-out port 18 is located below the lower edge of the side plate 10 and is connected to the suction fan F via a common duct D. .
[0023]
As shown in FIG. 8, between the top surfaces 9 of the double ridges 8 on the base 4, a small main body 34 a of a synthetic resin third wind guide member 34 whose planar shape is smaller than the support plate 6 is one of them. The third battery module group 21 is placed on the pendulum-shaped main body 34a. ₃ The two grommets 27 that hold the ridges are placed so that their one sides abut against the shielding plate 7 and are located directly above the ridges 8. Between the two grommets 27, a main body 35 a of a synthetic resin second air guide member 35 having a configuration in which the third air guide member 34 is turned upside down is passed with one side edge thereof abutting on the shielding plate 7. At the same time, a plurality of spacers 34b, 35b protruding from the child-shaped main bodies 34a, 35a of the two cages are mutually abutted. The second battery module group 21 is placed on the child body 35a of the second air guide member 35. ₂ The two grommets 27 holding one side of the grommet 27 contact one side of the grommet 27 with the shielding plate 7 and ₃ Are mounted so as to be located immediately above both grommets 27. On both grommets 27, the first battery module group 21 ₁ The two grommets 27 are mounted on the grommet 27 with one side thereof abutting against the shielding plate 7. Between the two grommets 27, a child-shaped first air guide member 36 of a synthetic resin cage having a form different from that of the second and third air guide members 35 and 34, with one side edge thereof abutting on the shielding plate 7, is provided. Has been passed. The length of each grommet 27 and the first to third baffle members 36 to 34 in the direction intersecting with the cooling air flow direction A are equal.
[0024]
As described above, the first air guide member 36 is connected to the first battery module group 21 closest to the cooling air introduction path 15. ₁ Of the second and third battery module groups 21 are disposed on the side of the cooling air introduction passage 15. ₂ , 21 ₃ The third air guide member 34 is disposed between the third battery module groups 21. ₃ Is disposed on the side of the cooling air outlet path 19.
[0025]
The first air guide member 36 is connected to the first battery module group 21. ₁ In the embodiment, the plurality of the rod-shaped battery modules 22 extend in the axial direction, face the outer peripheral surface of the rod-shaped battery modules 22 at an interval, and are disposed in the cooling air introduction passage 15. A plurality of strip-shaped air guide plates 37 and a plurality of, in the present embodiment, six first slits 38 which are located between the adjacent wind guide plates 37 and face the space between the adjacent rod-shaped battery modules 22. ₁ And
[0026]
First battery module group 21 ₁ , The outside diameter of the rod-shaped battery module 22 is d, and the width of the air guide plate 37 corresponding to the outside diameter d is w. ₁ And w ₁ ≧ d is set. Here, the outer diameter d of the rod-shaped battery module 22 is the outer diameter of the bottomed cylindrical body 23a on the negative electrode side of the battery 23, as shown in FIGS. This is the same hereafter.
[0027]
In the first air guide member 36, a portion facing both grommets 27 is a shallow channel material 40 that opens downward. ₁ And each channel material 40 ₁ Is fitted to each grommet 27. The air guide plate 37 is divided into four parts in the axial direction of the rod-shaped battery module 22, and the first divided piece has one end thereof connected to one channel member 40. ₁ The second divided piece is joined at one end to one channel material 40. ₁ Channel material 40 on the other side and adjacent to it ₂ And the third divided piece is a channel material 40 ₂ The other side and the other channel material 40 ₁ Each of the fourth divided pieces is joined to one channel side of the other channel material 40. ₁ On the other side.
[0028]
The small main body 35a of the second air guide member 35 is located between the adjacent strip-shaped flat plates 35c, and is located between the second and third battery module groups 21. ₂ , 21 ₃ A plurality of second slits 38 that face the outer peripheral surface of each of the rod-shaped battery modules 22, in the embodiment, extend in the axial direction of each of the rod-shaped battery modules 22, and are divided in the middle. ₂ And a second slit 38 corresponding to the outer diameter d of the rod-shaped battery module 22 and the outer diameter d. ₂ Width w ₂ And d> w ₂ In a relationship.
[0029]
The third main body 34a of the third air guide member 34 is located between the adjacent strip-shaped flat plates 34c, and ₃ A plurality of third slits 38 that face the outer peripheral surface of each of the rod-shaped battery modules 22, in the embodiment, extend in the axial direction of each of the rod-shaped battery modules 22, and are divided on the way. ₃ Having. However, one third slit 38 closest to the cooling air inlet 14 is provided. ₃ Is not used. The outer diameter d of the rod-shaped battery module 22 and the third slit 38 corresponding to the outer diameter d ₃ Width w ₃ Is d> w ₃ In a relationship.
[0030]
As shown in FIGS. 3 and 7, in the first air guide member 36, the air guide plate 37 located closest to the inlet 14 and the air guide plate 37 are adjacent to the air guide plate 37 and constitute a part of the box 2. There is a proximity slit 42 between the shielding plates 7 as the third component plates. Further, there is a remote slit 43 between the wind guide plate 37 located farthest from the inlet 14 and the side plate 10 as the fourth component plate adjacent to the wind guide plate 37 and constituting a part of the box 2. All the first slits 38 of the near slit 42 and the remote slit 43 and the first wind guide member 36 ₁ Of the rod-shaped battery module in the direction intersecting the axial direction of the rod-shaped battery module gradually decreases from the proximity slit 42 to the remote slit 43. That is, the width of the proximity slit 42 is defined as Wa1, the width of the remote slit 43 is defined as Wa8, and the first slits 38 of the first air guide member 36 arranged from the proximity slit 42 side to the remote slit 43 side. ₁ Assuming that the aforementioned width is Wa2 to Wa7, Wa1> Wa ₂ >Wa3>Wa4>Wa5>Wa6>Wa7> Wa8.
[0031]
As shown in FIGS. 2 and 3, the mounting portion 45 at one end of the two steel frame members 44 is provided on the top surface 9 of the two ridges 8 at the end opposite to the shielding plate 7. Are fixed to each other by bolts 46a and nuts 46b. As shown in FIG. 9, a vertical portion 47 rising from each mounting portion 45 has a channel shape, and a side portion of each grommet 27 is fitted into the channel 48. As shown in FIG. 10, the horizontal portion 49 bent from each vertical portion 47 also has a channel shape, and its channel 50 is the channel member 40 of the first air guide member 36. ₁ The horizontal part 49 and the channel material 40 ₁ And a plurality of leaf springs 51 are arranged between them. The first to third air guide members 36 to 34 and the three grommets 27 are pressed against the support plate 6 by the elastic force of the leaf springs 51. The mounting portion 52 connected to the end of each horizontal portion 49 is mounted on the upper edge plate 13 connected to the shielding plate 7 and fixed thereto by bolts 54 and nuts 55.
[0032]
In the horizontal portion 49 of each frame member 44, a support member 57 having a nut 56 on the upper surface is provided on the upper surface of the end on the side of the introduction port 14, and the ceiling plate 12 of the cover 5 is placed on the nut 56. A bolt 58 penetrating through the ceiling plate 12 is screwed into the nut 56. Thus, the cover 5 is attached to each frame member 44. Although not shown in the drawing, the means for attaching the cover 5 is also provided outside.
[0033]
As shown in FIGS. 2, 5, and 6, the first battery module group 21 ₁ And the second battery module group 21 adjacent thereto. ₂ The rod-shaped battery modules 22 are connected to each other by a synthetic resin clip 59 at the position of the connection ring 24 located at the center in the axial direction. Also, as shown in FIGS. ₃ Each of the rod-shaped battery modules 22 has a semicircular concave portion 60 provided on the spacers 35b, 34b of the second and third air guide members 35, 34 at the position of the connection ring 24 located at the center in the axial direction. , 61. As a result, the first to third battery module groups 21 ₁ ~ 21 ₃ The vibration of each of the rod-shaped battery modules 22 is suppressed.
[0034]
In FIG. 7, when the suction fan F is operated to cool the battery assembly 3, the cooling air a flows through the inlet 14, the inlet 15, the inside of the battery assembly 3, the outlet 19, and the outlet 18 in this order. . In this case, the proximity slit 42 and all the first slits 38 of the first wind guide member 36 ₁ .. And Wa7> Wa8 by setting the width relationship of the remote slits 43 to Wa1> Wa2... Wa7> Wa8. ₁ , 43, a substantially equal amount of cooling air a is introduced into the battery assembly 3. Then, the cooling air a is applied to the slits 42 and 38. ₁ , 43, the first and second battery module groups 21 ₁ , 21 ₂ When the air flows on both sides of each of the rod-shaped battery modules 22, a stagnation s of the cooling air having a low cooling capacity is formed between the air guide plate 37 and approximately one quarter of the outer peripheral surface of the rod-shaped battery module 22 opposed thereto. Further, the cooling capacity is provided between approximately one quarter of the lower part of the outer peripheral surface of the rod-shaped battery module 22 of the first battery module group 21 and approximately one-fourth upper part of the outer peripheral surface of the rod-shaped battery module 22 adjacent thereto. The cooling air stagnation s is formed. Thus, in the first battery module group 21, each rod-shaped battery module 22 is cooled by exposing roughly two-fourths of the outer peripheral surface thereof to the cooling air a flowing on both sides thereof.
[0035]
Second battery module 21 ₂ In the above, each of the rod-shaped battery modules 22 flows on both sides thereof and ₂ The cooling air is cooled by exposing approximately three quarters of the outer peripheral surface thereof to the cooling air a flowing into the air.
[0036]
Third battery module group 21 ₃ , Each rod-shaped battery module 22 is connected to the second slit 38 of the second air guide member 35. ₂ And flows along the outer peripheral surface of the rod-shaped battery module 22, and finally the third slit 38 of the third air guide member 34. ₃ Is cooled by exposing the entire outer peripheral surface thereof to a cooling wind a flowing into the air.
[0037]
The cooling capacity of the cooling air “a” is the ₁ To the second battery module group 21 ₂ Through the third battery module group 21 ₃ However, since the area of the rod-shaped battery module 22 exposed to the cooling air a increases accordingly, all the rod-shaped battery modules 22 can be cooled substantially uniformly.
[0038]
FIG. 11 shows a second embodiment. In this embodiment, the slits 42 and 38 on the first air guide member 36 side are used. ₁ , 43, and all the third slits 38 of the third baffle member 34 ₃ The width in the direction intersecting the axial direction of the rod-shaped battery module at the third slit 38 farthest from the cooling air outlet 18 ₃ From the third slit 38 closest to the cooling air outlet 18 ₃ It is gradually reduced toward. That is, the third slit 38 farthest from the cooling air outlet 18. ₃ Is defined as Wb1, and the third slit 38 ₃ Next third slit 38 ₃ From the third slit 38 closest to the cooling air outlet 18 ₃ Those third slits 38 leading to ₃ Is Wb2 to Wb7, Wb1>Wb2>Wb3>Wb4>Wb5>Wb6> Wb7. The other configuration is the same as that of the first embodiment.
[0039]
With the above configuration, the slits 42 and 38 are formed in the battery assembly 3 on the first wind guide member 36 side. ₁ , 43 from the battery assembly 3 on the third air guide member 34 side. ₃ , A substantially equal amount of cooling air a is derived, and all the rod-shaped battery modules 22 can be efficiently and almost uniformly cooled.
[0040]
FIG. 12 shows a third embodiment. In this embodiment, the slits 42 and 38 on the first air guide member 36 side are used. ₁ , 43 are such that Wa1 ≒ Wa2 ≒ Wa3 ≒ Wa4 ≒ Wa5 ≒ Wa6 ≒ Wa7 ≒ Wa8, while the entire third slit 38 of the third baffle member 34 ₃ Of the rod-shaped battery module in the direction intersecting with the axial direction of the rod-shaped battery module, the width of the third slit ₃ From the third slit 38 closest to the cooling air outlet 18 ₃ It gradually decreases toward. That is, the third slit 38 farthest from the cooling air outlet 18. ₃ Is defined as Wb1, and the third slit 38 ₃ Next third slit 38 ₃ From the third slit 38 closest to the cooling air outlet 18 ₃ Those slits 38 that lead to ₃ If the above widths are Wb2 to Wb7, Wb1>Wb2>Wa3>Wa4>Wa5>Wa6> Wa7. The other configuration is the same as that of the first embodiment.
[0041]
With the above configuration, the third slits 38 from the inside of the battery assembly 3 on the side of the third air guide member 34. ₃ Of the cooling air “a” through the first slits 38 in the battery assembly 3 on the first air guide member 36 side. ₁ , A substantially equal amount of cooling air can be introduced to efficiently cool all the rod-shaped battery modules 22 almost uniformly.
[0042]
FIG. 13 shows a fourth embodiment. In this embodiment, the proximity slit 42 and each first slit 38 of the first air guide member 36 are provided. ₁ The relationship between the widths of the remote slit 43 and the remote slit 43 is Wa1, Wa2, Wa3, Wa4, Wa5, Wa6, Wa7, and Wa8. ₁ In order to gradually decrease the opening area from the proximity slit 42 to the remote slit 43, an air volume adjusting plate 62 is provided between the third and fourth component plates, that is, the shielding plate 7 and the side plate 10. In the embodiment, the channel-shaped air volume adjusting plate 62 having a gradually increasing width in the axial direction of the rod-shaped battery module from the proximity slit 42 to the remote slit 43 makes the channel downward, and the central channel material in the first air guide member 36. 40 ₂ Instead of a part of the first air guide member 36. The other configuration is the same as that of the first embodiment.
[0043]
With the above-described configuration, the proximity slit 42 and each first slit 38 of the first air guide member 36 are provided. ₁ In addition, by introducing a substantially equal amount of cooling air a into the battery assembly 3 from the remote slit 43, all the rod-shaped battery modules 22 can be cooled substantially uniformly.
[0044]
【The invention's effect】
According to the first to fourth aspects of the present invention, each of the rod-shaped battery modules can be cooled substantially uniformly by the above-described configuration, and the first to third air guide members and the first to third air guide members can be cooled. Due to the stacked arrangement with the three-rod battery module group, it is possible to reduce the size by narrowing the space between the two adjacent rod-shaped battery modules, and to reduce the manufacturing cost because the number of parts is small. A battery-type power supply device can be provided.
[Brief description of the drawings]
FIG. 1 is a perspective view of a first embodiment of a battery type power supply device.
FIG. 2 is a perspective view showing a relationship between a battery assembly and a base and the like.
FIG. 3 is a sectional view taken along line 3-3 of FIGS.
FIG. 4 is a perspective view illustrating an arrangement of rod-shaped battery modules.
FIG. 5 is a perspective view of a rod-shaped battery module.
FIG. 6 is a main part perspective view showing a relationship between a rod-shaped battery module and a grommet.
FIG. 7 is an explanatory diagram showing a relationship between first to third air guide members and a rod-shaped battery module, and a flow of cooling air.
FIG. 8 is a perspective view showing a relationship between first to third air guide members and grommets.
FIG. 9 is an enlarged view of a main part of FIG. 3;
FIG. 10 is a sectional view taken along line 10-10 of FIG. 9;
FIG. 11 is a sectional view of a second embodiment of the battery-type power supply device, and corresponds to FIG.
FIG. 12 is a sectional view of a third embodiment of the battery-type power supply device, and corresponds to FIG.
FIG. 13 is a sectional view of a fourth embodiment of the battery-type power supply device, and corresponds to FIG.
[Explanation of symbols]
1. Battery power supply unit
2 …………… Box
3 …………… Battery assembly
6 Support plate (second component plate)
7. Shielding plate (third component plate)
10 Side plate (fourth component plate)
12 ... ceiling board (first component board)
14 ... Cooling air inlet
15 Cooling air introduction path
16 Cooling air inlet
18 Cooling air outlet
19 ... Cooling air outlet
20 cooling air outlet
21 ₁ ~ 21 ₃ .... First to third battery module groups
22 ............. Battery-shaped battery module
34 Third air guide member
35 ........ 2nd air guide member
36 First air guide member
37 ……… Wind guide plate
38 ₁ ~ 38 ₃ .... First to third slits
42 ...... Proximity slit
43 Remote slit
62 Airflow adjustment plate
A: Direction of cooling air flow
P ₁ ………… Virtual intersection plane
P ₂ …………… Virtual parallel plane
Wa1 to Wa8 ... width
Wb1 to Wb7 ... width
a …………… Cooling air
d …………… Outer diameter
w ₁ ~ W ₃ ……width

Claims (4)

A box (2) having a cooling air inlet (16) at one end and a cooling air outlet (20) at the other end, and a battery assembly (3) installed in the box (2). The battery assembly (3) includes first to third battery module groups (21 _{1 to} 21 ₃ ) arranged in parallel with each other along the cooling air flow direction (A) and at intervals. , The first to third battery module groups (21 _{1 to} 21 ₃ ) intersect with the cooling air flow direction (A) in a virtual intersection plane (P ₁ ) whose axis intersects with the cooling air flow direction (A). And a plurality of rod-shaped battery modules (22) arranged side by side at intervals and one rod-shaped battery module (22) and the other rod-shaped battery module (22) adjacent to each other in the cooling air flow direction (A). Are both the cooling air flow direction (A) Located in a parallel virtual parallel plane (P ₂ ), the cooling air introduction unit (16) faces the first battery module group (21 ₁ ) and the first battery module group (21 ₁ ), and A cooling air introduction passage (15) existing between the first component plates (12) constituting a part of the box (2) and a cooling air introduction opening (1) provided at one end of the cooling air introduction passage (15). 14), the cooling air outlet section (20) is opposed to the third battery module group (21 ₃ ) and the third battery module group (21 ₃ ), and one of the boxes (2). Outlet for cooling air existing between the second component plates (6) constituting the section, and an end of the outlet for cooling air (19) opposite to the inlet for cooling air (14). Battery-type power supply having a cooling air outlet (18) A first wind guide member (36) disposed on the cooling air introduction path (15) side of the first battery module group (21 ₁ ); and the second and third battery module groups. (21 ₂ , 21 ₃ ) and a third air guide member (35) arranged on the cooling air outlet path (19) side of the third battery module group (21 ₃ ). And a wind member (34), wherein the first wind guide member (36) extends in the axial direction of the plurality of rod-shaped battery modules (22) of the first battery module group (21 ₁ ). 22) and a plurality of air guide plates (37) opposed to each other at intervals and facing a space between two adjacent rod-shaped battery modules (22) between adjacent air guide plates (37). the has a first slit (38 ₁₎ The outer diameter of Jo battery module (22) is d, a w ₁ ≧ d when the width is set to w ₁ of the air guide plate corresponding to the outer diameter d (37), the second air duct member (35 ) Has a plurality of second slits (38 ₂ ) facing the outer peripheral surface of each rod-shaped battery module (22) of the second and third battery module groups (21 ₂ , 21 ₃ ), and the rod-shaped battery module (22). wherein the width _{w 2} of the second slit (38 ₂₎ are in relation of d> _{w 2,} the third air duct member (34) is the third battery module corresponding to the outer diameter d and the outer diameter d of Each of the plurality of rod-shaped battery modules (22) of the group (21 ₃ ) has a plurality of third slits (38 ₃ ) facing the outer peripheral surface thereof, and has an outer diameter d corresponding to the outer diameter d of the rod-shaped battery modules (22). Third slit (38 ₃₎ the width w ₃ of is in the d> w ₃ relationships, the box together with adjacent the said air guide plate closest to the cooling air inlet for (14) (37) and baffle plates (37) There is a proximity slit (42) between the third component plates (7) constituting a part of (2), and the air guide plate (37) farthest from the cooling air inlet (14) and its air guide. There is a remote slit (43) between the fourth component plate (10) adjacent to the plate (37) and forming part of the box (2), the close slit (42) and the remote slit (43) and the remote slit (43). The width (Wa1 to Wa8) of the entire first slit (38 ₁ ) of the _first wind guide member (36) in the direction intersecting with the axial direction of the rod-shaped battery module is changed from the proximity slit (42) to the remote slit (43). Gradually decreasing toward Battery-type power supply unit, wherein the door. A width (Wb1 to Wb7) of a direction intersecting with the axial direction of the rod-shaped battery module in all the third slits (383) of the _third wind guide member (34) is farthest from the cooling air outlet (18). the third slit (38 ₃₎ gradually decreases said toward the nearest said third slits in the cooling outlet (18) (38 ₃₎ from the battery-type power supply apparatus according to claim 1. A box (2) having a cooling air inlet (16) at one end and a cooling air outlet (20) at the other end, and a battery assembly (3) installed in the box (2). The battery assembly (3) includes first to third battery module groups (21 _{1 to} 21 ₃ ) arranged in parallel with each other along the cooling air flow direction (A) and at intervals. , The first to third battery module groups (21 _{1 to} 21 ₃ ) intersect with the cooling air flow direction (A) in a virtual intersection plane (P ₁ ) whose axis intersects with the cooling air flow direction (A). And a plurality of rod-shaped battery modules (22) arranged at equal intervals, and both of one rod-shaped battery module (22) and the other rod-shaped battery module (22) adjacent to each other in the cooling air flow direction (A). The axis is parallel to the cooling air flow direction (A). The cooling air introduction part (16) is located in a virtual parallel plane (P ₂ ), facing the first battery module group (21 ₁ ) and the first battery module group (21 ₁ ), and A cooling air introduction path (15) existing between the first component plates (12) constituting a part of (2) and a cooling air introduction port (14) existing at one end of the cooling air introduction path (15). The cooling air outlet (20) faces the third battery module group (21 ₃ ) and the third battery module group (21 ₃ ), and forms a part of the box (2). A cooling air outlet path (19) existing between the constituent second component plates (6) and an end of the cooling air outlet path (19) opposite to the cooling air inlet (14). A battery-type power supply having a cooling air outlet (18); A first air guide member (36) arranged on the cooling air introduction path (15) side of the first battery module group (21 ₁ ); and a second and third battery module group (21 _2). , 21 ₃ ), and a third air guide member (35) arranged on the cooling air outlet path (19) side of the third battery module group (21 ₃ ). 34), wherein the first wind guide member (36) extends in the axial direction of the plurality of rod-shaped battery modules (22) of the first battery module group (21 ₁ ), and A plurality of air guide plates (37) facing each other at intervals and a plurality of first air guides located between the adjacent wind guide plates (37) and facing the space between the adjacent rod-shaped battery modules (22). the bar back and having a slit (38 ₁₎ The outer diameter of the re module (22) is d, a w ₁ ≧ d when the width is set to w ₁ of the air guide plate corresponding to the outer diameter d (37), the second air duct member (35) Has a plurality of second slits (38 ₂ ) facing the outer peripheral surface of each rod-shaped battery module (22) of the second and third battery module groups (21 ₂ , 21 ₃ ), and the outer diameter d and the width _{w 2} of the slit (42) corresponding to the outer diameter d is in the relation of d> _{w 2,} the third air duct member (34) is the third battery module group (21 ₃ ), A plurality of third slits (38 ₃ ) facing the outer peripheral surface of each rod-shaped battery module (22), and the outer diameter d of the rod-shaped battery module (22) and the slit (43) corresponding to the outer diameter d. d and width _{w 3} of> Located on the _third relationship, third constituting a part of the box (2) with adjacent the said air guide plate closest to the cooling air inlet for (14) (37) and baffle plates (37) There is a proximity slit (42) between the component plates (7), and the box (37) furthest from the cooling air inlet (14) and the box (37) adjacent to the plate (37). fourth configuration plate constituting a part of 2) (10) remote slit (43) is between said rod-like battery module axial direction in all the third slits (38 ₃₎ of the third air duct member (34) The width (Wb1 to Wb7) in the direction intersecting with the third slit (38 ₃ ) furthest from the cooling air outlet (18) to the third slit closest to the cooling air outlet (18) (38 ₃₎ that it is gradually reduced Battery-type power supply unit according to claim. A box (2) having a cooling air inlet (16) at one end and a cooling air outlet (20) at the other end, and a battery assembly (3) installed in the box (2). The battery assembly (3) includes first to third battery module groups (21 _{1 to} 21 ₃ ) arranged in parallel with each other along the cooling air flow direction (A) and at intervals. , The first to third battery module groups (21 _{1 to} 21 ₃ ) intersect with the cooling air flow direction (A) in a virtual intersection plane (P ₁ ) whose axis intersects with the cooling air flow direction (A). And a plurality of rod-shaped battery modules (22) arranged at equal intervals, and both of one rod-shaped battery module (22) and the other rod-shaped battery module (22) adjacent to each other in the cooling air flow direction (A). The axis is parallel to the cooling air flow direction (A). The cooling air introduction part (16) is located in a virtual parallel plane (P ₂ ), facing the first battery module group (21 ₁ ) and the first battery module group (21 ₁ ), and A cooling air introduction path (15) existing between the first component plates (12) constituting a part of (2) and a cooling air introduction port (14) existing at one end of the cooling air introduction path (15). The cooling air outlet (20) faces the third battery module group (21 ₃ ) and the third battery module group (21 ₃ ), and forms a part of the box (2). A cooling air outlet path (19) existing between the constituent second component plates (6) and an end of the cooling air outlet path (19) opposite to the cooling air inlet (14). A battery-type power supply having a cooling air outlet (18); A first air guide member (36) arranged on the cooling air introduction path (15) side of the first battery module group (21 ₁ ); and a second and third battery module group (21 _2). , 21 ₃ ), and a third air guide member (35) arranged on the cooling air outlet path (19) side of the third battery module group (21 ₃ ). 34), wherein the first wind guide member (36) extends in the axial direction of the plurality of rod-shaped battery modules (22) of the first battery module group (21 ₁ ), and A plurality of air guide plates (37) facing each other at intervals and a plurality of first air guides located between the adjacent wind guide plates (37) and facing the space between the adjacent rod-shaped battery modules (22). the bar back and having a slit (38 ₁₎ The outer diameter of the re module (22) is d, a w ₁ ≧ d when the width is set to w ₁ of the air guide plate corresponding to the outer diameter d (37), the second air duct member (35) Has a plurality of second slits (38 ₂ ) facing the outer peripheral surface of each rod-shaped battery module (22) of the second and third battery module groups (21 ₂ , 21 ₃ ), and the outer diameter d and the width _{w 2} of the second slit (38 ₂₎ corresponding to the outer diameter d is in the d> of _{w 2} relationship, the third air duct member (34) is the third battery module group (21 ₃ ) each of the rod-shaped battery modules (22) has a plurality of third slits (38 ₃ ) opposed to the outer peripheral surface thereof, and has the outer diameter d of the rod-shaped battery module (22) and the _third diameter corresponding to the outer diameter d. 3 slit (38 ₃₎ It has a relationship of w ₃ and the d> w _3, wherein the air guide plate closest to the cooling air inlet for (14) (37) and said box together adjacent to the air guide plate (37) (2) There is a proximity slit (42) between the third component plates (7) constituting a part thereof, and the air guide plate (37) farthest from the cooling air inlet (14) and the air guide plate (37). There is a remote slit (43) between the fourth component plates (10) adjacent to and together forming part of the box (2), the close slits (42) and the remote slits (43) and the first air guide. In order to gradually reduce the opening area of the first slit (38 ₁ ) of the member (36) from the proximity slit (42) to the remote slit (43), between the third and fourth component plates (7, 10). Equipped with the provided air volume adjusting plate (62) Battery-type power supply unit, characterized in that there.

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