JP2018003367A - Storage battery system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a storage battery system that makes it easy to take out a storage battery from furniture, or an interior member.SOLUTION: A storage battery system 1 has an interior member 31, and a storage battery 11 stored in the interior member 31. The interior member 31 is provided with an opening 34 through which the storage battery 11 can be taken out.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a storage battery system.

Conventionally, when a user uses a building, studies have been made to reduce the influence of the building on the environment. As one example, there is a method in which a photovoltaic power generation device or the like is provided on the roof of a building to generate power and the generated power is stored in a storage battery. By configuring the building in this way, the power that needs to be supplied from the outside among the power used by the user can be suppressed.
For example, Patent Document 1 describes that a storage battery is provided in a storage battery storage (interior) of a staircase in order to effectively use a space in a building.

JP 2010-174582 A

  However, when a storage battery is provided in the storage battery storage, it becomes difficult to take out the storage battery from the storage battery storage during maintenance or replacement of the storage battery.

  This invention is made | formed in view of such a problem, Comprising: It aims at providing the storage battery system which made it easy to take out a storage battery from furniture or interior.

In order to solve the above problems, the present invention proposes the following means.
The storage battery system of the present invention comprises furniture or interior and a storage battery accommodated in the furniture or interior, and the furniture or interior is provided with an opening from which the storage battery can be taken out. It is a feature.
According to this invention, since the opening is formed in the furniture or the interior, the storage battery can be taken out of the furniture or the interior through the opening.

In the above storage battery system, a plurality of the storage batteries are formed in a sheet shape, the plurality of storage batteries are stacked in the thickness direction of the storage battery, and the plurality of storage batteries are in the thickness direction, and You may accommodate so that the taking-out direction of a some storage battery may cross | intersect.
According to this invention, when taking out some of the plurality of storage batteries, the remaining portion can be made less likely to be an obstacle.

In the above storage battery system, the furniture or the interior may be a staircase, and the opening may be formed by moving a kick plate of the staircase with respect to the footboard.
According to the present invention, in the staircase, the kick plate can be moved relative to the tread plate to form the opening, and the storage battery can be taken out.

Further, in the above storage battery system, the furniture or the interior is a sofa, and the sofa includes a seat portion and a support portion that supports the seat portion from below, and the seat portion serves as the support portion. The said opening part may be formed by moving with respect to.
According to this invention, in the sofa, the seat portion can be moved with respect to the support portion to form the opening, and the storage battery can be taken out.

  According to the storage battery system of the present invention, it is possible to easily take out the storage battery from furniture or interior.

It is sectional drawing of the front of the house where the storage battery system of embodiment of this invention is used. It is a figure which shows typically the cross section of the side surface of the lithium ion secondary battery of the storage battery system. It is sectional drawing of the principal part of the storage battery system of 1st Embodiment of this invention. It is sectional drawing of the side surface of the storage battery system of 2nd Embodiment of this invention. It is a perspective view of the storage battery system of 3rd Embodiment of this invention.

(First embodiment)
Hereinafter, a first embodiment of a storage battery system according to the present invention will be described with reference to FIGS. 1 to 3.
FIG. 1 shows an example of a house (building) 101 in which various storage battery systems of this embodiment are used. The house 101 is provided with a lower floor 102, a first floor 103, a second floor 104, an attic 105, and a roof 106 in this order from the bottom to the top. Hereinafter, a case where the storage battery is a lithium ion secondary battery (hereinafter abbreviated as a secondary battery) 11 will be described as an example, but the storage battery is not limited thereto. As the storage battery, a lead storage battery, a lithium ion polymer secondary battery, a nickel / hydrogen storage battery, a nickel / cadmium storage battery, and the like can be used.

In FIG. 1, the secondary battery 11 is housed in a floor lower part 102, a wall 107, and an attic 105 which are interiors. As the interior in which the secondary battery 11 is accommodated, for example, a staircase, a closet, a pillar, a floor (floor material), a tatami mat, and the like can be given. Examples of the furniture in which the secondary battery 11 is accommodated include a carpet and a chest.
The secondary battery 11 is accommodated in a so-called dead space in the house 101 that is a space that cannot be used well.
A known photovoltaic power generation device 111 is attached on the roof 106.
Below, the secondary battery 11 is demonstrated first.

The configuration of the secondary battery 11 is not particularly limited. As shown in FIG. 2, the secondary battery 11 is formed in a sheet shape (plate shape). The secondary battery 11 includes a power storage unit 12, an exterior body 13 that houses the electrical storage body 12, and an electrolyte 14 that is filled in the exterior body 13.
The power storage unit 12 is configured by alternately stacking positive electrode portions 15 and negative electrode portions 16 in the thickness direction Z of the secondary battery 11. Although not shown, the positive electrode part 15 is configured by providing a positive electrode active material layer on the main surface of the positive electrode sheet. The negative electrode part 16 is configured by providing a negative electrode active material layer on the main surface of the negative electrode sheet.
A separator 17 is disposed between the positive electrode part 15 and the negative electrode part 16. That is, the power storage unit 12 is configured by stacking the positive electrode part 15, the separator 17, the negative electrode part 16, the separator 17, the positive electrode part 15,.

An aluminum foil or the like can be used as the positive electrode sheet. The positive electrode active material layer has a lithium metal oxide compound represented by the general formula “LiM _x O _y (wherein M is a metal; x and y are composition ratios of metal M and oxygen O)”. Etc. are used. Examples of such a metal acid lithium compound include lithium cobaltate (LiCoO ₂ ) and lithium nickelate (LiNiO ₂ ).
A copper foil or the like can be used as the negative electrode sheet. For the negative electrode active material layer, graphite (graphite), silicon oxide, or the like is used.
Although the material of the separator 17 is not specifically limited, A microporous polymer film, a nonwoven fabric, glass fiber etc. are mentioned.

The configuration of the exterior body 13 is not particularly limited. Although not shown in detail, in this embodiment, the exterior body 13 is, for example, a first laminated film 20 in which a modified PP (polypropylene) layer, an aluminum layer, a nylon layer, and a PET (polyethylene terephthalate) layer are laminated from the inner layer side. And a second laminated film 21.
The exterior body 13 is formed in a bag shape by welding the edge of the modified PP layer of the first laminated film 20 and the edge of the modified PP layer of the second laminated film 21.

The electrolyte 14 is not particularly limited, and for example, an electrolyte, an electrolytic solution, and the like used in a known lithium ion secondary battery can be applied. Examples of the electrolytic solution include a mixed solution in which an electrolyte salt is dissolved in an organic solvent.
The secondary battery 11 includes a pair of tabs (terminals) not shown. The secondary battery 11 can be charged and discharged through a pair of tabs.
The secondary battery 11 has a relatively heavy mass, for example, several tens of kg or 100 kg.

  As shown in FIG. 3, the storage battery system 1 in the first embodiment includes a staircase (interior) 31 and the plurality of secondary batteries 11 housed in the staircase 31. The staircase 31 is configured by alternately arranging treads 32 extending along a horizontal plane and kicking plates 33 extending along a vertical direction. A step portion 34 is formed by the tread plate 32 and the kick plate 33 immediately below the tread plate 32.

For example, the first arm portion of the hinge 36 is fixed to the lower end portion of the kick plate 33. The second arm portion of the hinge 36 is fixed to the upper surface of the tread plate 32. A stopper 37 is fixed to the lower surface of the tread 32 and corresponding to the position above the hinge 36. The upper end portion of the kick plate 33 and the stopper 37 can be attached and detached with a permanent magnet or the like (not shown). The kick plate 33 can be rotated (moved) to a position P <b> 1 substantially parallel to the tread plate 32 by rotating about 90 ° to the lower step 34 side with the hinge 36 as the center of rotation. On the other hand, the kick plate 33 is restricted by the stopper 37 from rotating to the upper step 34 (not shown).
The kick plate 33 is rotationally moved around the hinge 36 to the position P1 with respect to the tread plate 32, so that an opening 34a is formed in the step portion 34.

The plurality of secondary batteries 11 are arranged in a storage chamber S1 formed between the treads 32 that are stacked in the thickness direction Z and adjacent in the vertical direction. In this example, in the plurality of secondary batteries 11, the thickness direction Z extends in the vertical direction, and the take-out direction X1 and the thickness direction Z of the plurality of secondary batteries 11 from the storage chamber S1 toward the opening 34a are orthogonal ( It is accommodated in the accommodation room S1 so as to intersect. The take-out direction X1 is a direction along the main surface 11a of each secondary battery 11 formed in a sheet shape.
Although not shown, the tabs of the plurality of secondary batteries 11 are connected to the photovoltaic power generation device 111 via wiring (electrical connection unit) and a power conditioner (electrical device). The power conditioner converts a DC voltage (current) into an AC voltage or adjusts the magnitude of the voltage. The power conditioner is connected to an outlet provided on the wall 107 of the house 101 or the like.
That is, the user uses the storage battery system 1 by connecting the terminal of the secondary battery 11 to the electrical equipment and the electrical connection portion provided in the house 101.

The storage battery system 1 configured as described above stores the power generated by the solar power generation device 111 in a plurality of secondary batteries 11. Then, the electric power generated by the solar power generation device 111 or the electric power stored in the plurality of secondary batteries 11 is sent to the power conditioner as a direct current (DC) voltage. The power conditioner appropriately converts a DC voltage into an AC voltage and supplies it to the outlet. An electrical product such as a refrigerator is connected to the outlet, and electric power is used as power for the electrical product.
When the electric product is driven with a DC voltage, the electric power stored in the secondary battery 11 may be directly supplied to the electric product, or may be supplied to the electric product after DC / DC conversion. .
If the storage battery system 1 is used for a certain period of time, a desired secondary battery 11 is taken out from the storage chamber S1 for maintenance or replacement. At this time, the kick plate 33 is rotated to the position P1, and the secondary battery 11 is taken out from the storage chamber S1 through the opening 34a. At this time, the thickness direction Z in which the plurality of secondary batteries 11 are stacked is perpendicular to the take-out direction X1. When a part of the plurality of secondary batteries 11 is taken out, there is no remaining secondary battery 11 on the take-out direction X1 side with respect to the part of the secondary batteries 11, and therefore the remaining secondary battery 11 becomes an obstacle to taking out. Hateful.

  The secondary battery 11 and the new secondary battery 11 that have undergone maintenance are moved in the direction opposite to the take-out direction X1, and are inserted into the storage chamber S1 through the opening 34a. The kick plate 33 is returned to the position extending along the vertical direction, and the maintenance and replacement of the secondary battery 11 are completed.

As described above, according to the storage battery system 1 of the present embodiment, since the opening portion 34a is formed in the staircase 31, the secondary battery 11 can be taken out of the staircase 31 through the opening portion 34a. .
The plurality of secondary batteries 11 are accommodated in the accommodation chamber S1 such that the take-out direction X1 and the thickness direction Z of the plurality of secondary batteries 11 are orthogonal to each other. Therefore, when taking out some of the plurality of secondary batteries 11, the remaining secondary batteries 11 can be made difficult to interfere.
In the stairs 31, the kick plate 33 is rotated with respect to the tread plate 32 to form the opening 34 a, and the secondary battery 11 can be taken out.
Space efficiency in the house 101 can be improved by installing the secondary battery 11 using the accommodation room S1 which is a dead space in the stairs 31.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 4, the storage battery system 2 of this embodiment includes a sofa (furniture) 41 and the plurality of secondary batteries 11 housed in the sofa 41.

The sofa 41 includes a seat portion 42 on which a user sits, a support portion 43 that supports the seat portion 42 from below, and a backrest portion 44 that is disposed behind the seat portion 42. The seat portion 42 is supported by the support portion 43 when it is disposed at the position P2.
The seat portion 42 is formed of urethane, wood, or the like, and enhances cushioning when the user is seated. The support part 43 is formed in a box shape whose upper part is an opening part 43a made of wood, metal, or the like.
The seat portion 42 is arranged at the position P2 on the support portion 43 to seal the opening portion 43a, and the seat portion 42 moves from the position P2 to the position P3 with respect to the support portion 43, so that 43a is formed.
The backrest portion 44 is formed of urethane, wood, or the like, like the seat portion 42, and extends upward from the support portion 43.

  The plurality of secondary batteries 11 are arranged in a state of being stacked in the thickness direction Z in the storage chamber S <b> 2 formed in the support portion 43. In this case, the thickness direction Z is a direction along the horizontal plane. The take-out direction X1 of the plurality of secondary batteries 11 from the storage chamber S2 toward the opening 43a is upward, and the take-out direction X1 is orthogonal to the thickness direction Z.

According to the storage battery system 2 of the present embodiment configured as described above, the secondary battery 11 can be easily removed from the sofa 41.
The sofa 41 may be a chair.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 5, the storage battery system 3 of the present embodiment includes a closet (interior) 51 and the plurality of secondary batteries 11 housed in the closet 51.
When a pair of bran 53 is moved on the threshold 52 of the closet 51 and moved to one side, an opening 51 a is formed in the closet 51.

In this example, a storage case 55 having an upper opening is disposed in the storage chamber S3 of the closet 51. The housing case 55 is made of an electrically insulating material such as plastic. The plurality of secondary batteries 11 are arranged in the housing case 55 so as to be stacked in the thickness direction Z. In this case, the thickness direction Z is a direction along the horizontal plane, and the take-out direction X1 of the secondary battery 11 is upward.
The housing case 55 is provided with a terminal 56. The tab of each secondary battery 11 is connected to the terminal 56. Although not shown, the terminal 56 is connected to a connection terminal provided on a wall in the closet 51. The connection terminal is connected to the power conditioner via wiring.

According to the storage battery system 3 of the present embodiment configured as described above, the secondary battery 11 can be easily taken out from the closet 51 through the opening 51a.
In the present embodiment, the housing case 55 may be configured in a tapered shape having an inner diameter that increases toward the top. With this configuration, the secondary battery 11 housed in the housing case 55 can be easily taken upward.
The housing case may be formed of a conductor such as metal, and the tab and the wiring of the secondary battery 11 may be connected to the housing case. In this case, the housing case becomes a power line. By generating a potential in the storage case, it is possible to suppress rust and the like from being generated in the storage case.
A plurality of secondary batteries 11 may be directly stored in the closet 51 without using the storage case 55.

The first to third embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and the configuration does not depart from the gist of the present invention. Changes, combinations, deletions, and the like. Furthermore, it goes without saying that the configurations shown in the embodiments can be used in appropriate combinations.
For example, in the first to third embodiments, the number of secondary batteries 11 housed in furniture or interior is not particularly limited, and may be one or two or more.
A support member that supports the secondary battery 11 may be attached to furniture or interior, and the secondary battery 11 may be attached to the support member. Since the secondary battery 11 may be relatively heavy, for example, by attaching a support member formed of metal in a plate shape or a bar shape to the furniture or the interior, the furniture or the interior can easily withstand the weight of the secondary battery 11. be able to. In this case, a connection terminal may be provided on the support member, and the tab of the secondary battery 11 may be connected to the connection terminal of the support member when the secondary battery 11 is attached to the support member.
Moreover, you may supply the electric power stored by the secondary battery 11 to wiring etc. through the metal support members. That is, the tab of the secondary battery 11 is configured to be electrically connected to the wiring or the like through the support member. In this case, the support member becomes a power line.

In addition to the above, it may be configured as follows.
-The secondary battery 11 is integrated with the solar power generation device.
-The secondary battery 11 is used as a weight to configure an earthquake resistant device. In this case, the seismic device includes, for example, a device that detects the shaking of the house 101 and a driving device that moves the secondary battery 11 so that the phase of the detected shaking is opposite to the phase. The seismic device is preferably provided on the attic beam.
A configuration in which the secondary battery 11 is attached to another device that generates heat. A lithium ion secondary battery becomes difficult to operate when, for example, the outside air temperature is lower than −20 ° C. For this reason, when the outside air temperature is low, such as in winter, the secondary battery 11 is heated with the heat generated by other devices. Thereby, the energy originally discarded by other devices can be utilized as energy for heating the secondary battery 11.
-As a countermeasure when the outside air temperature is low, the storage battery system may have a heat insulating function. The heat insulation function is achieved, for example, by arranging a member having a heat storage function around the secondary battery 11.

The storage battery system is configured to include a control circuit, a memory, an input unit, and a display unit. In this case, the history data that the secondary battery 11 has been used is stored in the memory. The history data may be displayed on the display unit when the user gives an instruction from the input unit as necessary. The control circuit may detect whether the state of the secondary battery 11 is normal or abnormal and display it on the display unit as necessary.
Furthermore, the input unit and the display unit of the storage battery system may be configured as a portable controller, and the controller may be able to communicate with the control circuit by wireless communication. By comprising in this way, the historical data of the secondary battery 11 and the abnormality of the secondary battery 11 can be confirmed in the display part of a controller in the place away from the secondary battery 11. FIG. Further, when the control circuit detects an abnormality, the abnormality may be notified to the maintenance company of the storage battery system.

-The exchange of power between the secondary battery 11 of the storage battery system and the outlet (wiring) of the house 101 may be electrically connected directly by a connector or the like, or indirectly by an electromagnetic induction method. You may go. As a method of indirectly electrically connecting, for example, CHAdeMO (registered trademark), which is a rapid charging method used for an electric vehicle (EV), is preferably used.
The wireless power feeding apparatus that is indirectly electrically connected is installed in, for example, a car port.

1, 2, 3 Storage battery system 11 Lithium ion secondary battery (storage battery)
31 Stairs (interior)
32 Step board 33 Kick board 34a, 43a, 51a Opening 41 Sofa (furniture)
51 Closet (interior)
X1 Extraction direction Z Thickness direction

Claims (4)

Furniture or interior;
A storage battery housed in the furniture or the interior;
With
The furniture or interior is provided with an opening through which the storage battery can be taken out. A plurality of the storage batteries are formed in a sheet shape,
The plurality of storage batteries are stacked in the thickness direction of the storage battery,
2. The storage battery system according to claim 1, wherein the plurality of storage batteries are accommodated such that the thickness direction intersects with the take-out direction of the plurality of storage batteries. The furniture or the interior is a staircase,
The storage battery system according to claim 1 or 2, wherein the opening is formed by moving the kick plate of the staircase with respect to the tread plate. The furniture or the interior is a sofa;
The sofa includes a seat portion and a support portion that supports the seat portion from below.
The storage battery system according to claim 1 or 2, wherein the opening is formed by moving the seat portion with respect to the support portion.

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