JP2013102000A - Power storage device and power storage device assembly - Google Patents

Abstract

An object of the present invention is to reduce the number of mechanisms for releasing gas generated by an electrochemical reaction to the outside of a power storage device.
A power storage device includes a first storage cell and a second storage cell, and a first storage chamber that stores the first storage cell and a second storage chamber that stores the second storage cell. A conductor housing 3 in which the first electrode body of the first storage cell 2A and the first electrode body of the second storage cell 2B are electrically connected, and a space surrounded by the housing 3, A partition member 8 that partitions the storage chamber 6 and the second storage chamber 7, a communication portion 9 that communicates the first storage chamber 6 and the second storage chamber 7, and the first storage chamber 6 attached to the housing 3. And a pressure regulating valve 40 for adjusting the pressure in the second storage chamber 7.
[Selection] Figure 7

Description

  The present invention relates to a power storage device and a power storage device assembly that can be charged and discharged.

  As a storage element capable of charging and discharging electricity, an electric double layer capacitor, a secondary battery, and the like are known. As an electric double layer capacitor, what was described in patent document 1 is known, for example. Moreover, about a secondary battery, what was described in patent document 2, for example is known. In addition, in an electric storage element such as an electric double layer capacitor and a secondary battery, a gas such as oxygen, hydrogen, or carbon dioxide gas is generated by an electrochemical reaction. As a mechanism for avoiding an increase in the internal pressure of the energy storage device caused by gas generated by an electrochemical reaction, for example, Patent Literature 3 describes a gas permeable valve that discharges internal gas to the outside.

JP-A-2-285622 JP 2001-093508 A Japanese Patent Laid-Open No. 11-40468

  When using a storage element such as an electric double layer capacitor or a secondary battery as an energy source for vehicles or industrial machines, in order to secure the required voltage, connect a plurality of storage elements in series and use it as a collection of storage elements. There is. Since one safety mechanism described in Patent Document 3 is required for one power storage element, when using it as an aggregate of power storage elements in which a plurality of power storage elements are combined, The number of air permeable valves is required. An object of the present invention is to reduce the number of mechanisms for releasing gas generated by an electrochemical reaction to the outside of a power storage device.

  The present invention includes a first electricity storage cell and a second electricity storage cell that have a first electrode body and a second electrode body, and that can be charged and discharged, and a first storage chamber that houses the first electricity storage cell and the second electricity storage cell. A conductor housing having a second storage chamber for storing a cell and electrically connecting the first polar body of the first power storage cell and the first polar body of the second power storage cell; A first terminal electrically connected to the second polar body of one storage cell and drawn out of the casing; and an external connection of the second terminal of the second storage cell to the outside of the casing Communication between the first terminal and the second storage chamber, the second member drawn to the partition, a partition member that partitions the space enclosed by the housing into the first storage chamber and the second storage chamber, and the first storage chamber and the second storage chamber And a pressure adjusting mechanism that is attached to the housing and adjusts the pressure of the first storage chamber and the second storage chamber. That is a power storage device.

  In this invention, it is preferable that the said pressure regulation mechanism is arrange | positioned in the position of the said communication part.

  In the present invention, it is preferable that the pressure adjusting mechanism has a gas inlet opening in the first storage chamber or the second storage chamber.

  In this invention, it is preferable that the said communication part is provided in the said partition member.

  In this invention, it is preferable that the said communication part is provided in the said housing | casing.

  The present invention is a power storage device assembly in which a plurality of power storage devices according to any one of claims 1 to 5 are connected in series and arranged in a casing.

  The present invention can reduce the number of mechanisms for releasing the gas generated by the electrochemical reaction to the outside of the power storage device.

FIG. 1 is a front view illustrating the power storage device according to the first embodiment. FIG. 2 is a side view showing the power storage device according to the first embodiment. FIG. 3 is a plan view illustrating the power storage device according to the first embodiment. FIG. 4 is a perspective view of the first polar body, the second polar body, and the separator. 5 is a cross-sectional view taken along the line AA in FIG. 6 is a cross-sectional view taken along the line BB in FIG. 7 is a cross-sectional view taken along the line CC of FIG. FIG. 8 is an enlarged view showing the mounting structure of the pressure regulating valve. FIG. 9A is an enlarged view showing a modified example of the mounting structure of the pressure regulating valve. FIG. 9-2 is an enlarged view showing a modification of the pressure regulating valve mounting structure. FIG. 10 is a cross-sectional view showing the structure of the pressure regulating valve. FIG. 11 is a DD arrow view of FIG. FIG. 12 is a cross-sectional view showing a modification of the pressure regulating valve. FIG. 13 is a view showing a modification of the pressure regulating valve. FIG. 14 is an electric circuit diagram of a power storage device in which single power storage cells are connected in series. FIG. 15 is an electric circuit diagram of the power storage device according to the first embodiment. FIG. 16 is a diagram illustrating the method for manufacturing the power storage device according to the first embodiment. FIG. 17 is a diagram illustrating a method for manufacturing the power storage device according to the first embodiment. FIG. 18 is a diagram illustrating a method for manufacturing the power storage device according to the first embodiment. FIG. 19 is a diagram illustrating the method for manufacturing the power storage device according to the first embodiment. FIG. 20 is a diagram illustrating the method for manufacturing the power storage device according to the first embodiment. FIG. 21 is a diagram illustrating the method for manufacturing the power storage device according to the first embodiment. FIG. 22 is a plan view showing a power storage device assembly including a plurality of power storage devices according to the present embodiment. FIG. 23 is a diagram illustrating the power storage device according to the second embodiment. 24 is a cross-sectional view taken along line EE in FIG. FIG. 25 is a side view showing the hybrid excavator. FIG. 26 is a view taken along the line FF in FIG.

  DESCRIPTION OF EMBODIMENTS Embodiments (embodiments) for carrying out the present invention will be described in detail with reference to the drawings. The present invention is not limited by the contents described in the following embodiments. The constituent elements described below include those that can be easily assumed by those skilled in the art and those that are substantially the same. Furthermore, the constituent elements described below can be appropriately combined. In addition, various omissions, substitutions, or changes of components can be made without departing from the scope of the present invention.

(Embodiment 1)
<Overall structure of power storage device>
FIG. 1 is a front view illustrating the power storage device according to the first embodiment. FIG. 2 is a side view showing the power storage device according to the first embodiment. FIG. 3 is a plan view illustrating the power storage device according to the first embodiment.
FIG. 4 is a perspective view of the first polar body, the second polar body, and the separator. 5 is a cross-sectional view taken along the line AA in FIG. 6 is a cross-sectional view taken along the line BB in FIG. 7 is a cross-sectional view taken along the line CC of FIG. FIG. 8 is an enlarged view showing the mounting structure of the pressure regulating valve. FIGS. 9-1 and FIGS. 9-2 are enlarged views showing modified examples of the pressure regulating valve mounting structure. FIGS.

  In the present embodiment, the power storage device 1 is an EDLC (Electric Double Layer Capacitor). However, the power storage device 1 is not limited to EDLC, and may be a secondary battery such as a lithium ion capacitor, an electrolytic capacitor, or a lithium ion battery.

  The power storage device 1 includes a first power storage cell 2 </ b> A and a second power storage cell 2 </ b> B, a housing 3, a first terminal 4, and a second terminal 5. Both the first storage cell 2A and the second storage cell 2B have the same structure. The first electricity storage cell 2A and the second electricity storage cell 2B include a first electrode body 21 (see FIG. 4) provided with an active material layer on the surface and a second electrode body provided with an active material layer on the surface. 22 (see FIG. 4). Both the first polar body 21 and the second polar body 22 are conductors. In the present embodiment, the first polar body 21 and the second polar body 22 are both conductive foils or sheets. The 1st polar body 21 and the 2nd polar body 22 can be manufactured with aluminum or an aluminum alloy, for example. A separator 23 is sandwiched between the first polar body 21 and the second polar body 22. The active material of the first polar body 21 and the active material of the second polar body 22 are opposed to the separator 23.

  The 1st polar body 21 and the 2nd polar body 22 are immersed in electrolyte with the separator 23 and the active material provided in each surface. The active material layers provided on the surface of the first polar body 21 and the surface of the second polar body 22 form a first polarizable electrode 24A and a second polarizable electrode 24B, respectively. The first polarizable electrode 24A and the second polarizable electrode 24B are, for example, those obtained by mixing activated carbon with a binder or the like (a conductive auxiliary agent may be further added). It can form by apply | coating to the surface of this.

  In the present embodiment, both the first polar body 21 and the second polar body 22 form an electric double layer capacitor. That is, the first polar body 21, the second polar body 22, and the separator 23 constitute an EDLC. The first energy storage cell 2A and the second energy storage cell 2B have at least one combination of the first electrode body 21, the second electrode body 22, and the separator 23. In the present embodiment, there are a plurality of the combinations. doing. As described above, each of the first power storage cell 2A and the second power storage cell 2B is an EDLC and is a chargeable / dischargeable power storage element.

  When the power storage device 1 is an EDLC, the first polar body 21 and the second polar body 22 have no polarity. In the present embodiment, the first polar body 21 electrically connects the first power storage cell 2A and the second power storage cell 2B, and the second polar body 22 is electrically connected to the connection target of the power storage device 1. The two are distinguished as being connected to each other.

  A combination of the first polar body 21, the separator 23, and the second polar body 22 forms one power storage unit. The voltage between the first polar body 21 and the second polar body 22 in one power storage unit corresponds to the inter-terminal voltage of the first power storage cell 2A. The first power storage cell 2A (the same applies to the second power storage cell 2B) may include one power storage unit, or a plurality of the power storage units stacked via the separator 23 and connected in parallel. In the former case, for example, the first polar body 21 of one power storage unit is electrically connected by a conductor. In the latter case, the first electrode bodies 21 of the plurality of power storage units are electrically connected to each other and electrically connected to the first electrode body 21, and the second electrode bodies 22 of the plurality of power storage units are connected to each other. It is electrically connected and electrically connected to the second polar body 22.

<Case structure>
The housing 3 includes a first storage chamber 6 that stores the first storage cell 2A, and a second storage chamber 7 that stores the second storage cell 2B. The housing 3 is made of a conductor, and the first electrode body 21 of the first electricity storage cell 2A and the first electrode body 21 of the second electricity storage cell 2B are electrically connected. The housing 3 is a structure for partitioning the first power storage cell 2A and the second power storage cell 2B from the outside. The housing 3 includes a side circumferential member 3S, a lid 3T, and a bottom 3B. For this reason, the side peripheral member 3S, the lid 3T, and the bottom 3B are conductors. In the present embodiment, the housing 3 is, for example, an aluminum alloy, but the material of the housing 3 is not limited to this. Further, the side circumferential member 3S, the lid 3T, and the bottom 3B may be all conductors, and the materials may be different as necessary. For example, the side circumferential member 3S and the bottom 3B may be made of an aluminum alloy, and the lid 3T may be made of a copper alloy. By doing in this way, the material suitable for each member which the housing | casing 3 has can be selected.

  The side circumferential member 3S is a cylindrical member. The side circumferential member 3S has a partition member 8 in a space surrounded by side portions. The partition member 8 partitions the space inside the side circumferential member 3S into two spaces. In the present embodiment, the side circumferential member 3S and the partition member 8 are integrally formed using the same material. However, even if both are manufactured as separate members and joined together by joining means such as welding. Good. Since the partition member 8 also has a function as a rib of the side peripheral member 3S of the housing 3, the strength of the side peripheral member 3S can be improved. It is preferable that the partition member 8 is fixed to the side peripheral member 3S because the function as the rib is further increased.

  The lid 3T and the bottom 3B are respectively provided at both ends of the side circumferential member 3S that is a cylindrical member. The lid 3T and the bottom 3B correspond to a pair of end side members. In the present embodiment, the bottom 3B as one end side member is formed integrally with the side circumferential member 3S. For this reason, as shown in FIG. 5, the side peripheral member 3S and the bottom 3B become a bottomed container in which the end of the side peripheral member 3S opposite to the bottom 3B is opened. As described above, the housing 3 is a structure in which the side circumferential member 3S, the bottom 3B, and the partition member 8 are integrally formed. Such a structure can be manufactured, for example, by a processing method that is a kind of cold forging called impact molding. The method for manufacturing the structure is not limited to impact molding. By integrally forming the bottom 3B and the side circumferential member 3S, the joining between the bottom 3B and the side circumferential member 3S can be omitted, and thus the power storage device 1 can achieve the effects of simplifying the manufacturing process and reducing the number of components. . Further, by integrally molding the bottom 3B and the side peripheral member 3S by impact molding, the risk of leakage of the electrolyte (electrolytic solution) sealed in the housing 3 can be reduced.

  As shown in FIG. 5, the first opening 6H of the first storage chamber 6 and the second opening 7H of the second storage chamber 7 are opened at the end of the side circumferential member 3S opposite to the bottom 3B. Yes. A lid 3T as the other end side member is attached to the first opening 6H and the second opening 7H. More specifically, the lid 3T includes the end (opening side end) 3St, the first opening 6H, and the second opening 7H side of the side peripheral member 3S on the first opening 6H and the second opening 7H side. Is attached to the end portion (opening-side partition member end portion) 8St of the partition member 8. And the lid | cover 3T is joined and fixed by joining means, such as welding, with the side periphery member 3S.

  The first storage chamber 6 and the second storage chamber 7 included in the housing 3 are divided into spaces surrounded by the housing 3, that is, a space surrounded by the lid 3T, the side circumferential member 3S, and the bottom 3B. It is a space divided into individual pieces. That is, the first storage chamber 6 and the second storage chamber 7 are spaces surrounded by the side circumferential member 3S, the lid 3T, the bottom 3B, and the partition member 8. As shown in FIG. 5, in the present embodiment, the opening-side partition member end 8St of the partition member 8 is in contact with the lid 3T, but they may be separated from each other. By partitioning the first storage chamber 6 and the second storage chamber 7 by the partition member 8, interference between the first power storage cell 2A and the second power storage cell 2B disposed in the housing 3 can be reliably suppressed. . In this embodiment, since the partition member 8 is integrally formed with the side peripheral member 3S, the partition member 8 is a conductor. However, the partition member 8 may not be a conductor.

  The housing 3 is electrically connected to the second polar body 22 of the first power storage cell 2A and is drawn out of the housing 3, and the second polar body 22 of the second power storage cell 2B is electrically connected to the second power body 2B. And a second terminal 5 that is connected to the outside of the housing 3. The first terminal 4 and the second terminal 5 are both conductors, and in this embodiment are aluminum or an aluminum alloy. The material of the first terminal 4 and the second terminal 5 is not limited to aluminum or aluminum alloy. The first terminal 4 penetrates the lid 3T from the first storage chamber 6 and is drawn out of the lid 3T. The second terminal 5 penetrates the lid 3T from the second storage chamber 7 and is drawn out of the lid 3T. A first seal member 4S is interposed between the first terminal 4 and the lid 3T, and a second seal member 5S is interposed between the second terminal 5 and the lid 3T. The first seal member 4S and the second seal member 5S are members for ensuring electrical insulation between the first terminal 4 and the second terminal 5 and the lid 3T that is a conductor. Further, the first seal member 4S and the second seal member 5S seal the first storage chamber 6 and the second storage chamber 7 by sealing the gap between the first terminal 4 and the second terminal 5 and the lid 3T. . With such a structure, leakage of electrolyte from the first storage chamber 6 and the second storage chamber 7 is suppressed. For this reason, the first seal member 4S and the second seal member 5S are made of rubber, resin, or the like that has high electrical insulation and sealing performance.

  In the present embodiment, the first polar body 21 of the first storage cell 2A and the first polar body 21 of the second storage cell 2B are electrically connected to the lid 3T included in the housing 3. Next, this connection structure will be described. As shown in FIG. 5, a first protrusion 10 and a second protrusion 11 are provided on the side of the first storage chamber 6 and the second storage chamber 7 of the lid 3T. The first protrusion 10 and the second protrusion 11 are both integrally formed with the lid 3T, but electrical continuity between the first protrusion 10 and the second protrusion 11 and the cover 3T is ensured. For example, both may be separate members.

  The first protrusion 10 is provided at a position facing the first storage chamber 6 of the lid 3T, and protrudes from the surface of the lid 3T toward the first storage chamber 6. The 2nd protrusion part 11 is provided in the position facing the 2nd storage chamber 7 of the lid | cover 3T, and protrudes toward the 2nd storage chamber 7 from the surface of the lid | cover 3T. As shown in FIG. 5, the 1st connection conductor 25 is electrically connected to the 1st polar body 21 of 2 A of 1st electrical storage cells, and the 1st polar body 21 of the 2nd electrical storage cell 2B, respectively. The first connection conductor 25 is, for example, a sheet in which a good electrical conductor such as copper or aluminum is formed.

  The first connection conductor 25 connected to the first polar body 21 of the first storage cell 2 </ b> A stored in the first storage chamber 6 is electrically connected to the first protrusion 10. Further, the first connection conductor 25 connected to the first electrode body 21 of the second storage cell 2 </ b> B stored in the second storage chamber 7 is electrically connected to the second protrusion 11. Since the 1st projection part 10 and the 2nd projection part 11 are electrically connected through lid 3T, the 1st polar body 21 of the 1st electrical storage cell 2A and the 1st polar body of the 2nd electrical storage cell 2B The first connection conductor 25, the first protrusion 10, the lid 3 </ b> T, the second protrusion 11, and the first connection conductor 25 are electrically connected. With such a structure, the first power storage cell 2A and the second power storage cell 2B are connected in series via the lid 3T included in the housing 3.

  The first terminal 4 is electrically connected to the second polar body 22 of the first power storage cell 2A, and the second terminal 5 is electrically connected to the second polar body 22 of the second power storage cell 2B. Next, this connection structure will be described. As shown in FIG. 6, the first terminal 4 has a first conductor connection portion 4C on the first storage chamber 6 side, and the second terminal 5 has a second conductor connection portion on the second storage chamber 7 side. 5C. Each of the first conductor connection portion 4C and the second conductor connection portion 5C has a flat plate shape, and the first terminal 4 and the second terminal are more than the portion where the first terminal 4 and the second terminal 5 are pulled out from the lid 3T. The area when viewed from the direction in which 5 is pulled out is widened.

  As shown in FIG. 6, a second connection conductor 26 is electrically connected to the second polar body 22 of the first power storage cell 2A and the second polar body 22 of the second power storage cell 2B. For example, the second connection conductor 26 is a sheet in which a good electrical conductor such as copper or aluminum is formed. The second connection conductor 26 connected to the second polar body 22 of the first storage cell 2A stored in the first storage chamber 6 is electrically connected to the first conductor connection portion 4C of the first terminal 4. . The second connection conductor 26 connected to the second polar body 22 of the second storage cell 2 </ b> B stored in the second storage chamber 7 is electrically connected to the second conductor connection portion 5 </ b> C of the second terminal 5. Is done. With such a structure, in the power storage device 1, the first power storage cell 2 </ b> A and the second power storage cell 2 </ b> B connected in series exchange power through the first terminal 4 and the second terminal 5.

<Pressure control mechanism>
As shown in FIGS. 1 and 7, the lid 3T has a pressure regulating valve 40 as a pressure regulating mechanism. In the power storage device 1, activated carbon is used for the first polarizable electrode 24 </ b> A and the second polarizable electrode 24 </ b> B, but residual moisture and functional groups of the activated carbon are electrolyzed by repeated charge / discharge to generate gas. That is, gas is generated in the power storage device 1 by an electrochemical reaction. This gas increases the pressure in the first storage chamber 6 and the second storage chamber 7. For this reason, the pressure regulating valve 40 included in the lid 3T releases the gas generated in the first storage chamber 6 and the second storage chamber 7 to the outside of the housing 3, and the first storage chamber 6 and the second storage chamber 7 are discharged. Suppresses internal pressure rise.

  As shown in FIGS. 7 to 9-2, the pressure regulating valve 40 is attached to the housing 3, more specifically, a lid 3 </ b> T that is a part of the housing 3. In the present embodiment, the pressure regulating valve 40 is attached to the through hole 16 penetrating the lid 3T. The through-hole 16 is open at the position of the partition member 8 that partitions both the first polarizable electrode 24A and the second polarizable electrode 24B. In the present embodiment, as shown in FIG. 8, the partition member 8 has a communication portion 9 at the end on the lid 3T side. The communication unit 9 communicates the first storage chamber 6 and the second storage chamber 7. In the example illustrated in FIG. 8A, the communication member 9 is provided in the partition member 8, but the location where the communication member 9 is provided is not limited thereto. For example, as shown in FIG. 9A, a recess that communicates the partition member 8 across the partition member 8 may be provided on the first storage chamber 6 and the second storage chamber 7 side of the lid 3T, and this may be used as the communication portion 9a.

  By providing the communication portions 9 and 9a, the pressure in the first storage chamber 6 and the pressure in the second storage chamber 7 become the same. Further, the communication portions 9 and 9 a freely move the gas between the first storage chamber 6 and the second storage chamber 7. For this reason, if the gas inlet 40I of the pressure regulating valve 40 is connected to at least one of the first storage chamber 6 and the second storage chamber 7, both gases can be released to the outside of the housing 3. That is, the pressure regulating valve 40 does not need to be provided in each of the two first storage chambers 6 and the second storage chamber 7, and the first storage chamber 6 and the second storage chamber 7 are configured by the single pressure regulation valve 40. Both pressures can be adjusted (reduced pressure). As a result, it is possible to obtain effects such as a reduction in manufacturing cost of the power storage device 1, an improvement in productivity due to a reduction in the step of attaching the pressure regulating valve 40, and an improvement in reliability by reducing the number of parts.

  The position at which the adjustment valve 40 is provided on the lid 3T is not particularly limited. However, when the partition member 8 has the communication portion 9, the pressure adjustment valve 40 is disposed at the position of the communication portion 9, and the gas of the pressure adjustment valve 40 is obtained. It is preferable that the inlet 40I is positioned at the communication portion 9. In this way, if there is a portion where the pressure regulating valve 40 protrudes toward the first storage chamber 6 and the second storage chamber 7, this portion can be extended to the communication portion 9, so Interference with the pressure valve 40 can be avoided. Moreover, by providing the communication part 9 in the partition member 8, a part of the pressure regulating valve 40 can be projected to the communication part 9 without particularly processing the lid 3T. Furthermore, when the partition member 8 has the communication part 9, since it is not necessary to process the lid 3T, there is no need to secure a processing allowance for the lid 3T, so that the thickness of the lid 3T can be reduced. . In addition, since the communication portion 9 is provided between the first storage chamber 6 and the second storage chamber 7, if the pressure regulating valve 40 is disposed in the communication portion 9 to release gas, the first storage chamber 6. And the second storage chamber 7 can release gas in a well-balanced manner.

  When the lid 3T has the communication portion 9a, the portion where the pressure regulating valve 40 protrudes toward the first storage chamber 6 and the second storage chamber 7 is stored in the communication portion 9a, and the first storage chamber 6 and the first 2 It is preferable not to protrude from the storage chamber 7 side. In this case, the pressure regulating valve 40 is disposed in the communication portion 9a. In this way, interference between the pressure regulating valve 40 and the partition member 8 can be avoided. Further, when the lid 3T has the communication portion 9a, it is not necessary to process the partition member 8.

  As shown in FIG. 9-2, the pressure regulating valve 40 may be disposed on the first storage chamber 6 side or the second storage chamber 7 side. In this example, the pressure regulating valve 40 is disposed on the first storage chamber 6 side, and the gas inlet 40I of the pressure regulating valve 40 opens into the first storage chamber 6. Even if it does in this way, interference with the partition member 8 and the pressure regulation valve 40 can be avoided. In this example, the position of the communication part 9 and the position of the gas inlet 40I of the pressure regulating valve 40 are different.

  Since the communication parts 9 and 9a should just connect the 1st storage chamber 6 and the 2nd storage chamber 7, the position is not limited. However, from the viewpoint of allowing the first storage chamber 6 and the second storage chamber 7 to communicate with each other and allowing gas to freely move between the two storage chambers 6 and 7, the communication portions 9 and 9 a are made of electrolyte (electrolyte) in the housing 3. It is preferable that the first storage chamber 6 and the second storage chamber 7 communicate with each other above the liquid level. In the present embodiment, by providing the communication portion 9 at the end of the lid 3T of the partition member 8 or by providing the communication portion 9a on the lid 3T, the influence of the electrolyte (electrolyte) is eliminated as much as possible. The storage chamber 6 and the second storage chamber 7 are reliably communicated with each other.

  The position of the pressure regulating valve 40 is not particularly limited, but the gas inlet 40I of the pressure regulating valve 40 is open in a space in the first storage chamber 6 or the second storage chamber 7 where there is no electrolyte (electrolyte). Is preferred. In this way, it is possible to reduce the possibility that the electrolyte (electrolytic solution) adheres to the gas inlet 40I and obstructs the passage of the gas, and the gas in the first storage chamber 6 and the second storage chamber 7 is securely enclosed. It can be discharged outside the body 3. Next, the structure of the pressure regulating valve 40 will be described.

  FIG. 10 is a cross-sectional view showing the structure of the pressure regulating valve. FIG. 11 is a DD arrow view of FIG. The pressure regulating valve 40 includes an annular base body 41 attached to the through hole 16 of the lid 3T, an annular connecting member 42 attached to the base body 41, a disc-like lid body 43 attached to the connecting member 42, and an elastic member 45. And a disc-like valve body 46 and a seal member 47.

  The base body 41 has a gas inlet 40I on the communication part 9 side of the partition member 8. As shown in FIGS. 10 and 11, the base body 41 has an overhanging portion 41 </ b> F that projects toward the center of the gas inlet 40 </ b> I. Furthermore, as shown in FIG. 11, the base body 41 has a valve body arrangement hole 41 </ b> H on the lid body 43 side. The valve body 46 is arrange | positioned in the valve body arrangement | positioning hole 41H. The diameter of the gas inlet 40I is smaller than the diameter of the valve element disposing hole 41H by the overhanging portion 41F protruding toward the center of the gas inlet 40I. For this reason, the valve body 46 arrange | positioned at the valve body arrangement | positioning hole 41H does not fall out from the gas inlet 40I.

  A seal member 47 is disposed between the valve body 46 and the overhang portion 41F. The seal member 47 is an annular and flexible member. The seal member 47 is made of, for example, rubber or resin. An elastic member 45 is disposed between the lid body 43 and the valve body 46. The elastic member 45 provides the valve body 46 with a force toward the overhanging portion 41F. In the present embodiment, the elastic member 45 is a coil spring, but it is sufficient that the elastic member 45 has a function of applying a force toward the protruding portion 41F to the valve body 46. By changing the spring constant of the elastic member 45, the valve opening pressure of the pressure regulating valve 40 can be adjusted.

  As shown in FIG. 11, the valve element disposition hole 41 </ b> H included in the base body 41 has a plurality of protrusions 41 </ b> T directed radially inward on the inner peripheral surface. The plurality of protrusions 41T regulates the radial movement of the valve body 46 arranged in the valve body arrangement hole 41H, and has a predetermined distance between the valve body 46 and the inner peripheral surface of the valve body arrangement hole 41H. Provide a gap. This gap allows the gas flowing in from the gas inlet 40I to pass through.

  The lid 43 has a gas outlet 44. The gas outlet 44 discharges the gas flowing into the pressure regulating valve 40 from the gas inlet 40I. The lid body 43 is attached to the base body 41 via the connecting member 42. In the present embodiment, the base body 41, the connecting member 42, and the lid body 43 are all made of resin, but materials other than resin may be used. Further, the connecting member 42 may be integrated with the lid body 43 or the base body 41. The base body 41, the connecting member 42, and the lid body 43 are integrated by, for example, being bonded by an adhesive, or by ultrasonic bonding or laser welding.

  A male screw is provided in a portion of the base body 41 attached to the through hole 16 of the lid 3T, and a female screw corresponding to the male screw is provided in the through hole 16. Then, the pressure regulating valve 40 may be attached to the lid 3T by screwing the base body 41 into the through hole 16. Further, the base body 41 may be bonded to the through hole 16 with an adhesive. Furthermore, the base body 41 may be provided in the through hole 16 by injection molding or the like. Further, as shown by a dotted line in FIG. 10, the partition member 8 side of the overhang portion 41 </ b> F of the base body 41 may be projected outward in the radial direction of the through hole 16 of the lid 3 </ b> T. In this way, since the overhanging portion 41F that protrudes outward in the radial direction of the through-hole 16 is engaged with the lid 3T, the possibility that the base body 41 falls off the lid 3T can be reduced.

  In the pressure regulating valve 40, since the elastic member 45 presses the valve body 46 against the overhanging portion 41F of the base body 41, a first sealing member 47 interposed between the valve body 46 and the overhanging portion 41F is shown in FIG. The storage chamber 6 and the second storage chamber 7 are sealed from the outside. When the pressure in the first storage chamber 6 and the second storage chamber 7 rises and the force pushing the valve body 46 toward the lid body 43 exceeds the pressing force of the elastic member 45, the sealing by the seal member 47 is released. Thus, the gas in the first storage chamber 6 and the second storage chamber 7 passes between the valve body 46 and the overhanging portion 41F. The gas is discharged from the gas outlet 44 of the lid 43 after passing through the gap between the valve body 46 and the inner peripheral surface of the valve body arrangement hole 41H. As a result, when the pressure in the first storage chamber 6 and the second storage chamber 7 decreases and the force pushing the valve body 46 toward the lid body 43 is less than the pressing force of the elastic member 45, the valve body 46 is tensioned. The seal member 47 is sandwiched between the protruding portion 41F. As a result, the first storage chamber 6 and the second storage chamber 7 are sealed from the outside. In this way, the pressure regulating valve 40 suppresses an increase in pressure inside the first storage chamber 6 and the second storage chamber 7.

  FIG. 12 is a cross-sectional view showing a modification of the pressure regulating valve. The pressure regulating valve 40a of the present modification has a structure substantially similar to that of the pressure regulating valve 40 described above, but the structure of the valve body 46a and the seal member 47a, the position and number of the gas outlets 44a, and the like are different. Further, the pressure regulating valve 40a of the present modification is different in that it does not have the connecting member 42 that the pressure regulating valve 40 has. The operating principle of the pressure regulating valve 40a is the same as that of the pressure regulating valve 40 described above.

  The seal member 47a is a disk-shaped member, and the material is the same as that of the seal member 47 of the pressure regulating valve 40 described above. The seal member 47 is disposed so as to block the entire gas inlet 40I. Since the diameter of the seal member 47a is larger than the diameter of the gas inlet 40I, the dropout of the seal member 47a from the gas inlet 40I is avoided. The seal member 47a is fitted in a recess provided on the gas inlet 40I side of the valve body 46a. The valve element 46a is arranged in the valve element arrangement hole 41H with a predetermined distance from the inner peripheral surface thereof. The point that the valve body 46a receives a pressing force from the elastic member 45a toward the gas inlet 40I is the same as that of the pressure regulating valve 40.

  In the base body 41 a, the outer side of the lid 3 </ b> T (the side opposite to the gas inlet 40 </ b> I) projects toward the radially outer side of the through hole 16. A lid 43a is attached to the side surface of the protruding portion. For example, the two may be bonded with an adhesive, or a male screw may be provided on the side surface of the protruding portion, and a female screw corresponding to the male screw may be provided on the inner peripheral portion of the lid 43a to fasten both. The gas outlet 44a is open to the side periphery of the lid 43a. Such a pressure regulating valve 40a can also suppress an increase in pressure inside the first storage chamber 6 and the second storage chamber 7 shown in FIG.

  FIG. 13 is a view showing a modification of the pressure regulating valve. The pressure regulating valve 40b of this modification is a reed valve type. In the pressure regulating valve 40b, a first valve body 49a made of an elastic material and a second valve body 49b made of an elastic material are combined at a mating surface 49c. The first valve body 49a and the second valve body 49b are fitted into the through hole 16 of the lid 3T from the communication portion 9 side, that is, from the first storage chamber 6 and second storage chamber 7 side shown in FIG. . The first valve body 49a and the second valve body 49b are larger than the diameter of the through hole 16 on the first storage chamber 6 and the second storage chamber 7 side, so that the first storage chamber 6 and the second storage chamber from the lid 3T. The possibility of falling off to the opposite side of the chamber 7 can be reduced. The first valve body 49a and the second valve body 49b are pressed against the mating surface 49c, thereby preventing gas from passing through the mating surface 49c.

  When the gas pressure in the first storage chamber 6 and the second storage chamber 7 increases, the passage of the gas through the mating surface 49c is prevented only by pressing the first valve body 49a and the second valve body 49b. Can not be. If it will be in such a state, the gas in the 1st storage chamber 6 and the 2nd storage chamber 7 will pass through the mating surface 49c, and will be discharge | released outside. Such a pressure regulating valve 40b can also suppress an increase in pressure inside the first storage chamber 6 and the second storage chamber 7 shown in FIG. Moreover, the pressure regulating valve 40b has an advantage that the structure is simple.

  In the present embodiment, the example in which the valve device, more specifically, the pressure regulating valves 40, 40a, 40b is used as the pressure regulating mechanism has been described. However, the pressure adjusting mechanism is not limited to the valve device. For example, a gas-permeable film or the like may be used as the pressure adjusting mechanism. Next, the power storage device 1 of the present embodiment will be described in comparison with a single power storage cell.

<Comparison between a single power storage cell and the power storage device of this embodiment>
FIG. 14 is an electric circuit diagram of a power storage device in which single power storage cells are connected in series. The power storage cells 220A and 220B included in the power storage device 201 illustrated in FIG. 14 each have an inter-terminal voltage E, and the inter-terminal voltage of the power storage device 201 (a voltage between two terminals 205) is 2 × E. In the storage cells 220A and 220B, the first lead portion 221E and the second lead portion 222E are drawn from the housing 203 and are electrically connected to terminals 204 and 205 as external connection terminals, respectively. The storage cells 220A and 220B have two insulators 204S and 205S, respectively, in order to ensure insulation between the housing 203 and the first and second lead portions 221E and 222E. Therefore, the power storage device 201 including the two power storage cells 220A and 220B has a total of four insulators. In addition, the power storage device 201 electrically connects the terminal 204 of the power storage cell 220A and the terminal 204 of the power storage cell 220B using the power storage cell connection bar 223 in order to connect the two power storage cells 220A and 220B in series. To do.

  FIG. 15 is an electric circuit diagram of the power storage device according to the first embodiment. The first power storage cell 2 </ b> A and the second power storage cell 2 </ b> B included in the power storage device 1 illustrated in FIG. 15 each have a terminal voltage of E, and the terminal voltage of the power storage device 1 (the first terminal 4 and the second terminal 5 The voltage between) is 2 × E. As shown in FIG. 15, the power storage device 1 connects the first power storage cell 2A and the second power storage cell 2B in series via the first lead portion 21E and the housing 3, and via the second lead portion 22E. Connect to external connection terminals (first terminal 4 and second terminal 5). The potential of the housing 3 is half (E) of the voltage between the terminals of the power storage device 1. Thus, the potential of the housing 3 becomes an intermediate potential of the power storage device 1.

  The power storage device 1 has a structure in which a current flows through the housing 3. With such a structure, the power storage device 1 has two power storage cells 2A and 2B, but only two external connection terminals, the first terminal 4 and the second terminal 5, are required. The number of insulators for ensuring insulation between the housing 3 and the first terminal 4 and the second terminal 5 as external connection terminals is sufficient, that is, the first seal member 4S and the second seal member 5S. In addition, the power storage device 201 illustrated in FIG. 14 requires the inter-storage cell connection bar 223, but the power storage device 1 electrically connects the first power storage cell 2 </ b> A and the second power storage cell 2 </ b> B via the housing 3. Therefore, the inter-storage cell connection bar 223 is unnecessary. For this reason, the power storage device 1 can reduce the number of parts.

  In the power storage device 1, the first polar body 21 of the first power storage cell 2 </ b> A and the first polar body 21 of the second power storage cell 2 </ b> B are connected to the housing 3 without an external connection terminal. For this reason, the power storage device 1 can reduce the number of external connection terminals when two power storage cells 2A and 2B are connected in series. As a result, the power storage device 1 has a simple structure, so that the manufacturing cost is reduced and the reliability is improved. Moreover, since the housing | casing 3 is made from a conductor, it is excellent in electrical conductivity and heat conductivity. In this embodiment, since the housing | casing 3 is an aluminum alloy, electrical conductivity and heat conductivity are favorable. In the power storage device 1, the first power storage cell 2 </ b> A and the second power storage cell 2 </ b> B generate heat, but the first electrode body 21 is connected to the housing 3 having good thermal conductivity. For this reason, the heat generated in the first power storage cell 2 </ b> A and the second power storage cell 2 </ b> B is transmitted from the first polar body 21 to the housing 3 and is radiated from the surface of the housing 3. For this reason, the electrical storage apparatus 1 has the advantage that heat dissipation performance is high. Note that unevenness or fins may be provided on the surface of the housing 3. In this case, since the surface area of the housing 3 is increased, the heat dissipation performance of the power storage device 1 is further improved.

  The power storage device 1 stores an electrolyte (electrolytic solution) in the first storage chamber 6 and the second storage chamber 7 in addition to the first storage cell 2A and the second storage cell 2B. For this reason, the power storage device 1 provides the first seal member 4S and the second seal member 5S between the lid 3T of the housing 3 and the first terminal 4 and the second terminal 5 to seal the inside of the housing 3. doing. Since the first terminal 4 and the second terminal 5 and the housing 3 are all conductors, they need to be insulated. It is difficult to achieve both the sealing of the housing 3 and the insulation between the housing 3 and the first terminal 4 and the second terminal 5 and to improve the reliability. The power storage device 201 (see FIG. 14) described above has two power storage cells 220A and 220B connected in series, and a total of four insulators are used for the sealing and the insulation. On the other hand, the power storage device 1 has two first power storage cells 2A and a second power storage cell 2B connected in series. For the sealing and the insulation, the first seal member 4S and the second seal are used. Two of the members 5S may be used. As described above, since the power storage device 1 can reduce the number of members used for the sealing and the insulation, the reliability can be improved correspondingly, and the work used for the sealing and the insulation can be reduced, and the cost can be reduced. it can.

  In the power storage device 1 shown in FIG. 15, the first power storage cell 2 </ b> A and the second power storage cell 2 </ b> B are electrically connected by the housing 3. And since the electrical storage apparatus 1 has the communication part 9 which connects the 1st storage chamber 6 and the 2nd storage chamber 7 which accommodated the 1st electrical storage cell 2A and the 2nd electrical storage cell 2B, it generate | occur | produces by an electrochemical reaction The mechanism that discharges the gas thus discharged to the outside of the power storage device, that is, the pressure regulating valve 40 is sufficient. On the other hand, the power storage device 201 shown in FIG. 14 requires a pressure regulating valve 240 for each of the two power storage cells 220A and 220B. As described above, both the power storage device 1 and the power storage device 201 have the same terminal voltage of 2 × E. As described above, the power storage device 1 can halve the number of the pressure regulating valves 40 compared to the power storage device 201 having the same inter-terminal voltage by connecting the single power storage cells 220A and 220B in series. .

<Method for manufacturing power storage device>
16 to 21 are diagrams illustrating the method for manufacturing the power storage device according to the first embodiment. In manufacturing the power storage device 1, a structure 3 </ b> D, a first power storage cell 2 </ b> A, and a second power storage cell 2 </ b> B in which the side circumferential member 3 </ b> S and the bottom 3 </ b> B are integrally formed are prepared. The structure 3D is a part of the housing 3 shown in FIG. The first connection conductor 25 is electrically connected to the first lead portion 21E of the first power storage cell 2A and the second power storage cell 2B, and the second connection conductor 26 is electrically connected to the second lead portion 22E. . The first lead portion 21E is a conductor drawn from the first pole body 21 in order to connect the first pole body 21 shown in FIG. 4 to a terminal. The second lead portion 22E is a conductor drawn from the second pole body 22 in order to connect the second pole body 22 shown in FIG. 4 to a terminal. The first lead portion 21E and the first connection conductor 25 are electrically connected by a joining means such as welding or ultrasonic joining. The second lead portion 22E and the second connection conductor 26 are similarly connected.

  Next, the first storage cell 2A is stored in the first storage chamber 6 of the structure 3D, and the second storage cell 2B is stored in the second storage chamber 7. At this time, the first lead portion 21E and the second lead portion 22E included in the first power storage cell 2A and the second power storage cell 2B are placed on the opening side of the first storage chamber 6 and the second storage portion 7 included in the structure 3D. Turn. Next, as shown in FIG. 17, the first connection conductor 25 of the first storage cell 2A is electrically connected to the first protrusion 10 provided on the lid 3T, and the first connection of the second storage cell 2B. The conductor 25 is electrically connected to the second protrusion 11 provided on the lid 3T. Further, as shown in FIG. 18, the second storage conductor 26 of the first storage cell 2A is electrically connected to the first conductor connection portion 4C of the first terminal 4 provided on the lid 3T, so that the second storage cell The 2B second connection conductor 26 is electrically connected to the second conductor connection portion 5C of the second terminal 5 provided on the lid 3T. For these connections, for example, a joining means such as welding or ultrasonic joining is used.

  Then, as shown in FIG. 18, the lid 3T is moved closer to the side circumferential member 3S (the direction indicated by the arrow C in FIG. 19), and the lid 3T is placed on the end of the side circumferential member 3S on the opening side. . Next, as shown in FIG. 19, the boundary portion between the lid 3T and the side circumferential member 3S is joined using a joining means such as welding or ultrasonic joining, and both are fixed. Thereafter, the electrolyte ES is injected from the through hole 16 of the lid 3T into the inside of the housing 3, more specifically, the first storage chamber 6 and the second storage chamber 7 shown in FIG. If electrolyte ES is inject | poured, as shown in FIG. 21, the pressure regulation valve 40 will be attached to the lid | cover 3T, and the electrical storage apparatus 1 will be completed. Since this power storage device manufacturing method uses the structure 3D manufactured by impact molding, the step of joining the bottom 3B and the side peripheral member 3S can be omitted, and the number of components can be reduced. Next, connecting a plurality of power storage devices 1 in series will be described.

<Power storage device assembly>
FIG. 22 is a plan view showing a power storage device assembly including a plurality of power storage devices according to the present embodiment. By connecting a plurality of power storage devices 1 in series, a voltage required for a power supply target of the power storage device 1 can be created. The power storage device assembly 110 illustrated in FIG. 22 includes a plurality (eight in this example) of power storage devices 1 connected in series. The number of power storage devices 1 is not limited. When a plurality of power storage devices 1 are connected in series, the first terminal 4 and the second terminal 5 of the adjacent power storage devices 1 are electrically connected. The first terminal 4 and the second terminal 5 that are not connected to the first terminal 4 or the second terminal 5 of any power storage device 1 are terminals of the power storage device assembly 110.

  The plurality of power storage devices 1 are disposed inside the assembly housing 111 and are attached to a power storage device mounting body having a cooling medium passage inside and sealed from the outside. In addition, the power storage device assembly 110 includes a balance circuit board 28 having a balance circuit for adjusting the balance of electrical characteristics among the plurality of power storage devices 1. As described above, when a large number of power storage devices 1 are connected in series, maintenance and inspection are facilitated by dividing the plurality of power storage devices 1 into a plurality of units.

  In the power storage device assembly 110, a plurality of power storage devices 1 are stored in the assembly housing 111. For this reason, it is possible to reduce the possibility that foreign matter, moisture, or the like enters the power storage device 1 through the pressure regulating valve 40 of the power storage device 1. For this reason, the power storage device assembly 110 in which the plurality of power storage devices 1 are stored in the assembly housing 111 is a power source used in an environment in which foreign matter or moisture easily enters from the pressure regulating valve 40, for example, a power source for a construction machine or the like. Is preferred.

(Embodiment 2)
FIG. 23 is a diagram illustrating the power storage device according to the second embodiment. 24 is a cross-sectional view taken along line EE in FIG. The power storage device 1b electrically connects the first lead portion 21E of the first power storage cell 2Aa and the first lead portion 21E of the second power storage cell 2Ba to the partition member 8b, and the housing 3b and the partition member 8b One power storage cell 2Aa and the second power storage cell 2Ba are covered. Other configurations are the same as those of the power storage device 1 according to the first embodiment.

  Since the structures of the first power storage cell 2Aa and the second power storage cell 2Ba included in the power storage device 1b are as described in the second embodiment, the description thereof is omitted. The partition member 8b is a single plate-like member. In the present embodiment, the partition member 8b has a rectangular shape (including a square) in a plan view (a shape when viewed from a direction orthogonal to the plate surface), but is not limited thereto. The partition member 8b is manufactured by press-molding a sheet metal, for example.

  The partition member 8b is a conductor, and in this embodiment is an aluminum alloy. The material of the partition member 8b is not limited to this. In the partition member 8b, the first terminal 4b and the second terminal 5b are disposed on one end 8bt1 side, and the first lead portion 21E of the first storage cell 2Aa and the second storage cell 2Ba are disposed on the other end 8bt2 side. The first lead portion 21E is electrically connected.

  An insulator 13A and an insulator 13B are provided between the partition member 8b and the first energy storage cell 2Aa and the second energy storage cell 2Ba. The insulators 13A and 13B ensure electrical insulation between the first power storage cell 2Aa and the second power storage cell 2Ba and the partition member 8b. The housing 3b is provided on the first power storage cell 2Aa side and the second power storage cell 2Ba side with the partition member 8b as the center. The housing 3b is a sheet-like member having a rectangular shape (including a square) in plan view. The housing 3b has a structure in which an outer layer 12A such as a metal foil and an insulating layer 12B such as a resin are laminated, but is not limited thereto. The two housings 3b are arranged on the outer periphery of the partition member 8b with the insulating layer 12B facing the first storage cell 2Aa and the second storage cell 2Ba and wrapped between the partition member 8b. Sealing is performed, and the sealing portion 15 is formed in this portion. For the sealing of the two casings 3b, for example, a joining means such as ultrasonic fusion can be used.

  Part of the surface of the first terminal 4b and part of the surface of the second terminal 5b are covered with the first seal member 4Sb and the second seal member 5Sb, respectively. The first seal member 4Sb and the first seal member 5Sb are sandwiched between the housing 3b and the partition member 8b. The first seal member 4Sb and the first seal member 5Sb insulate the first terminal 4b and the second terminal 5b from the partition member 8b, and two spaces surrounded by the housing 3b and the partition member 8b, that is, The first storage chamber 6b and the second storage chamber 7 are sealed. The first storage cell 6A is stored in the first storage chamber 6b, and the second storage cell 2Ba is stored in the second storage chamber 7.

  As shown in FIG. 23, the partition member 8 b has a communication portion 9. In this embodiment, the communication part 9 has penetrated the plate-shaped partition member 8b in the thickness direction. With such a structure, the communication portion 9 communicates the first storage chamber 6b and the second storage chamber 7b shown in FIG. In this embodiment, the communication part 9 is arrange | positioned above the electrical storage apparatus 1b, specifically, the 1st terminal 4b side.

  In the power storage device 1b, a pressure regulating valve 40 is provided in the housing 3b. In the present embodiment, the gas inlet 40I is provided in the housing 3b on the first storage chamber 6b side and opens into the first storage chamber 6b. The pressure regulating valve 40 is disposed above the power storage device 1b, specifically, on the first terminal 4b side. With such a structure, the communication portion 9 equalizes the pressure in the first storage chamber 6b and the pressure in the second storage chamber 7b, and allows gas to move between them. And since the pressure regulation valve 40 discharge | releases gas to the exterior of the housing | casing 3b, when the pressure of the 1st storage chamber 6b and the 2nd storage chamber 7b rises, the 1st storage chamber 6b and the 2nd storage chamber 7b The pressure rise is suppressed. Furthermore, the communication part 9 may have only one pressure regulating valve 40 for the two first storage chambers 6b and the second storage chamber 7b. As a result, effects such as reduction in manufacturing cost of the power storage device 1, improvement in productivity, and improvement in reliability due to simplification of the structure can be obtained.

(Embodiment 3)
<Application example to construction machinery>
In the present embodiment, a hybrid construction machine will be described as an example of a machine having a power storage device assembly 110 having a plurality of power storage devices 1 according to the above-described embodiments. As the hybrid construction machine, a hybrid hydraulic excavator is taken as an example, but the application target of the power storage device 1 and the power storage device assembly 110 is not limited to this.

  FIG. 25 is a side view showing the hybrid excavator. FIG. 26 is a view taken along the line FF in FIG. The hybrid excavator 100 drives a generator motor by an internal combustion engine to generate electric power, and the electric motor is driven by the electric power to turn the upper swing body, or the auxiliary machinery of the hybrid excavator 100 is driven. This is a so-called hybrid construction machine.

  The hybrid excavator 100 includes a lower traveling body 102 having a pair of left and right crawler belts 102C, an upper swing body 103, a boom 104a, an arm 104b and a bucket 104c, and a work machine 104 attached to the upper swing body 103, A swing circle 105 that connects the traveling body 102 and the upper swing body 103 is included. The pair of left and right crawler belts 102C are driven by a right traveling hydraulic motor and a left traveling hydraulic motor to cause the hybrid excavator 100 to travel. The right traveling hydraulic motor and the left traveling hydraulic motor are driven by being supplied with hydraulic oil fed from the hydraulic pump 107 shown in FIG.

  The upper swing body 103 is rotated by an electric motor 105M (see FIG. 26) that functions as a swing motor. An outer race 105O of a swing circle 105 is fixed to the upper swing body 103, and an inner race 105I of the swing circle 105 is fixed to the lower traveling body 102. With such a structure, the swing circle 105 connects the upper swing body 103 and the lower traveling body 102. The input / output shaft of the electric motor 105M is connected to the swing pinion 105P through a swing machinery having a speed reduction mechanism. The swing pinion 105P meshes with internal teeth attached to the inner race 105I of the swing circle 105. The driving force of the electric motor 105M is transmitted to the swing pinion 105P via the swing machinery, and turns the upper swing body 103. In this embodiment, the electric motor 105M is installed vertically, that is, when the hybrid excavator 100 is installed on a horizontal plane, the input / output shaft of the electric motor 105M is directed in the direction in which gravity acts. The boom 104a, the arm 104b, and the bucket 104c are driven by hydraulic cylinders for the boom 104a, the arm 104b, and the bucket 104c, respectively, via the control valve by hydraulic oil pumped from the hydraulic pump 107 shown in FIG. Perform work such as excavation.

  The upper swing body 103 is a structure having a substantially rectangular shape in plan view. The cockpit 103a of the upper swing body 103 is disposed on the left side in front of the upper swing body 103 when the direction in which the operator's line of sight is mainly directed during the operation of the hybrid excavator 100 is assumed to be forward. The counterweight 103 b is disposed behind the upper swing body 103. In addition to the cockpit 103a and the counterweight 103b, the upper swing body 103 includes an internal combustion engine 106 as a power generation source of the hybrid excavator 100, a generator motor 109 according to the present embodiment, a hydraulic pump 107, an inverter 108, And a power storage device assembly 110 in which a plurality of the power storage devices 1 described above are connected in series.

  The internal combustion engine 106 is a diesel engine, for example, but the type of the internal combustion engine 106 is not limited. The internal combustion engine 106, the generator motor 109, the hydraulic pump 107, the inverter 108, and the power storage device assembly 110 are disposed in front of the counterweight 103b, that is, on the cockpit 103a side. A generator motor 109 is disposed between the internal combustion engine 106 and the hydraulic pump 107. The output shaft 106S of the internal combustion engine 106 is connected to the input / output shaft of the generator motor 109, and the input / output shaft of the generator motor 109 is connected to the input shaft 107S of the hydraulic pump 107. With such a structure, the internal combustion engine 106 drives the generator motor 109 to generate electric power and drives the hydraulic pump 107. That is, the hydraulic pump 107 is driven via the generator motor 109. The generator motor 109 may be indirectly connected to the output shaft of the engine via a PTO (Power Take Off).

  The high voltage wiring CAa is electrically connected to the input / output terminal of the inverter 108 and the power input / output terminal of the generator motor 109. A high voltage wiring CAb is electrically connected to the output terminal of the inverter 108 and the input terminal of the electric motor 105M. The inverter 108 stores the electric power generated by the generator motor 109 in the power storage device assembly 110, or supplies the electric power to the electric motor 105M to drive it. Further, the inverter 108 stores, in the power storage device assembly 110, electric power obtained by the electric motor 105M converting the kinetic energy of the upper swing body 103 into electrical energy when the swing brake is operated on the upper swing body 103. . The electric power stored in the power storage device assembly 110 is supplied to the electric motor 105M by the inverter 108 when the upper swing body 103 turns next time. The generator motor 109 can operate as a motor by receiving power supply from the power storage device assembly 110 and can assist the internal combustion engine 106 as necessary.

  As described above, the above-described power storage device assembly 110 is applied to the hybrid excavator 100 which is a kind of construction machine. Note that the application target of the power storage device assembly 110 is not limited to the hybrid excavator 100. For example, the power storage device assembly 110 may be applied to other hybrid construction machines such as a wheel loader.

  Construction machines such as the hybrid excavator 100 are normally used on rough terrain, and the working machine 104 and the upper swing body 103 are subjected to rapid acceleration / deceleration or a large load is applied. Thus, construction machines are often used under severe conditions. For this reason, the power storage device assembly 110 mounted on the construction machine is also subjected to rapid acceleration / deceleration, vibration or impact, or a large current is passed to the electric motor 105M in order to accelerate the upper turning zone 103 rapidly. So it is used in harsh conditions.

  The number of connection bars in the power storage device assembly 110 that electrically connects the first terminal 4 and the second terminal 5 of the adjacent power storage device 1 as compared to the case where the power storage elements of a single power storage cell are connected in series. In addition, it is possible to reduce the number of connection points between the second terminal 5 and the first terminal 4 and the connection bar. In addition, the power storage device assembly 110 is provided between the first terminal 4 and the second terminal 5 (external terminal) and the lid 3T (housing) as compared to the case where the power storage elements of a single power storage cell are connected in series. Since the number of the first seal members 4S and the second seal members 5S (sealing locations) provided can be reduced, the reliability can be improved. As described above, the power storage device assembly 110 can reduce the number of the connection portions and the sealing portions that are easily affected by vibration or impact, and thus can maintain high reliability. In particular, when the power storage device assembly 110 is used as a power supply source for driving an electric motor or the like, a high voltage is required, and as a result, the number of power storage devices 1 in series increases, so that the connection location and the sealing location are also To increase. Since the power storage device assembly 110 can reduce the number of the connection locations and the sealing locations, the power storage device assembly 110 is suitable for applications in which many power storage devices 1 are connected in series, such as a hybrid construction machine.

  Since the construction machine is usually used on rough terrain or the like, it is necessary to protect the power storage device assembly 110 from mud or foreign matter. For this reason, as shown in FIG. 22, the power storage device assembly 110 houses and seals the plurality of power storage devices 1 inside the assembly housing 111. The power storage device 1 included in the power storage device assembly 110 can efficiently transfer the heat generated in the first power storage cell 2A and the second power storage cell 2B to the housing 3 through the connected first electrode body 21. . Therefore, the power storage device assembly 110 efficiently transfers the heat of the first power storage cell 2A and the second power storage cell 2B to the power storage device attachment 34 via the housing 3 even when the power storage device 1 is sealed. Accordingly, it is possible to suppress an excessive temperature rise of the power storage device 1.

  Furthermore, the power storage device assembly 110 is sealed after the plurality of power storage devices 1 are housed inside the assembly housing 111. For this reason, it can suppress that a foreign material or a water | moisture content penetrate | invades in the assembly housing | casing 111. FIG. As a result, the power storage device assembly 110 can reduce the risk of foreign matter or moisture entering the power storage device 1 from the pressure regulating valve 40 of the power storage device 1, thereby ensuring high reliability. Thus, the power storage device assembly 110 is suitable for a construction machine.

1, 1b, 201 Power storage device 2A, 2Aa First power storage cell 2B, 2Ba Second power storage cell 3, 3b Case 3B Bottom 3D Structure 3S Side peripheral member 3T Lid 4, 4b First terminal 4C First conductor connection portion 5 5b 2nd terminal 5C 2nd conductor connection part 6, 6b 1st storage chamber 6H 1st opening part 7, 7b 2nd storage chamber 7H 2nd opening part 8, 8b Partition member 9, 9a Communication part 10 1st protrusion part 11 2nd protrusion part 15 Sealing part 16 Through-hole 21 1st polar body 21E 1st extraction part 22 2nd polar body 22E 2nd extraction part 23 Separator 24A 1st polarizable electrode 24B 2nd polarizable electrode 25 1st connection Conductor 26 Second connection conductor 40, 40a, 240 Pressure regulating valve 40I Gas inlet 41, 41a Base body 41H Valve body arrangement hole 41F Overhang portion 41T Projection portion 42 Connecting member 43, 43a Lid 44, 44a Gas outlet 45, 45a Elastic portion 46,46a valve 47,47a seal member 49a first valve body 49b second valve body 49c mating surface 100 hybrid hydraulic shovel 110 power storage device assembly 111 assembly housing

Claims (6)

A first storage cell and a second storage cell having a first polar body and a second polar body, and being chargeable / dischargeable;
A first storage chamber for storing the first storage cell; a second storage chamber for storing the second storage cell; and a first electrode body of the first storage cell and a first electrode of the second storage cell. A conductor housing electrically connected to the body;
A first terminal electrically connected to the second polar body of the first storage cell and drawn out of the housing;
A second terminal electrically connected to the second polar body of the second storage cell and drawn out of the housing;
A partition member that partitions the space surrounded by the housing into the first storage chamber and the second storage chamber;
A communication portion for communicating the first storage chamber and the second storage chamber;
A pressure adjusting mechanism attached to the housing for adjusting the pressure of the first storage chamber and the second storage chamber;
A power storage device comprising:   The power storage device according to claim 1, wherein the pressure adjusting mechanism is disposed at a position of the communication portion.   The power storage device according to claim 1, wherein the pressure regulating mechanism has a gas inlet opening in the first storage chamber or the second storage chamber.   The power storage device according to claim 1, wherein the communication portion is provided in the partition member.   The power storage device according to claim 1, wherein the communication unit is provided in the housing.   A power storage device assembly, wherein a plurality of power storage devices according to claim 1 are connected in series and arranged in a casing.

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