KR102063936B1 - Energy Storage System Comprising Battery Modules Connected by Magnetic Connecting Structure - Google Patents

Abstract

The present invention relates to a power storage system including a plurality of battery modules coupled by a magnetic connection structure, the plurality of battery modules stacked up and down; And a magnetic connection structure formed between an upper surface of the lower battery module and a lower surface of the upper battery module facing up and down. The magnetic connection structure may include: a magnetic connector part formed on one side of the lower surface and the upper surface and including a connector body provided with a first magnet and a first connection contact exposed on a surface of the connector body; And an attachment body formed on the other side of the lower surface and the upper surface, the attachment body having a second magnet opposed to the first magnet and exposed to the surface of the attachment body at a position aligned with the first connection contact point. Magnetic attachment including two connecting contacts. The first connection contact point and the second connection contact point contact each other by magnetic attraction of the first magnet and the second magnet at a contact interface between the connector body and the attachment body.

Description

Power storage system including a plurality of battery modules connected using a magnetic connection structure {Energy Storage System Comprising Battery Modules Connected by Magnetic Connecting Structure}

The present invention relates to an improved connection between battery modules in a power storage system (ESS) comprising a plurality of battery modules.

The power storage system (ESS) is used to store power generated by a traditional power plant or a plant using renewable energy and to provide power to the grid in advance, and to prepare for emergency situations such as power outages or shutdowns. It is widely used for supplying power to an uninterrupted load, and for storing power at night, which is relatively inexpensive to charge electricity for efficient use of power.

The power storage system includes a plurality of battery modules that are electrically connected. The plurality of battery modules are stacked on a shelf called a rack. Then, electrical wiring work is performed between the battery modules adjacent up and down.

Electrical wiring work involves connecting the electrode terminals of adjacent battery modules in series or parallel using a power cable, and using a communication cable to communicate with a battery management system included in each battery module. And connecting a communication port provided in the battery module.

On the other hand, when some battery modules cause a failure or end of life, it is necessary to replace the battery module. At this time, the power cable and communication cable should be disconnected and reconnected. Therefore, an experienced worker is required and time consuming. In addition, since the power storage system has a high operating voltage, there is a possibility of an electric shock accident in the course of performing electrical wiring work.

In addition, since the power storage system generates a lot of heat during operation, it is common to attach a cooling fan to each battery module. By the way, since the interference occurs due to the power cable and the communication cable in the part where electrical wiring is performed, it is difficult to install a cooling fan. Therefore, the cooling fan has a space constraint that must be installed in the area where there is no electrical wiring.

Accordingly, the inventors of the present application have recognized that there is a need for a new connection scheme that can omit electrical wiring work between battery modules included in a power storage system.

The present invention has been made under the background of the prior art, and an object thereof is to provide a power storage system including a plurality of battery modules electrically connected without a separate electrical wiring work.

A power storage system for achieving the above technical problem, a plurality of battery modules stacked up and down; And a magnetic connection structure formed between an upper surface of the lower battery module and a lower surface of the upper battery module facing up and down.

Preferably, the magnetic connection structure, the magnetic connector portion is formed on one side of the lower surface and the upper surface, including a connector body provided with a first magnet and a first connection contact exposed on the surface of the connector body; And an attachment body formed on the other side of the lower surface and the upper surface, the attachment body having a second magnet opposed to the first magnet and exposed to the surface of the attachment body at a position aligned with the first connection contact point. It may include a magnetic attachment portion including a two connection contact.

Preferably, the first connection contact point and the second connection contact point may contact each other by magnetic attraction of the first magnet and the second magnet at a contact interface between the connector body and the attachment body.

In one aspect, the first magnet may be embedded along the edge of the connector body or at the central portion. Similarly, the second magnet may be embedded along the edge of the attachment body or at the central portion.

Preferably, the first connection contact may include at least a first positive electrode contact and a first negative electrode contact, and the second connection contact may include at least a second positive electrode contact and a second negative electrode contact.

In one aspect, the first positive electrode contact and the first negative electrode contact may be in electrical contact with the second positive electrode contact and the second negative electrode contact, respectively.

In another aspect, the first positive electrode contact and the first negative electrode contact may be in electrical contact with the second negative electrode contact and the second positive electrode contact, respectively.

Preferably, the first anode contact and the first cathode contact may be elastically biased by an elastic body embedded in the connector body. Alternatively, the second anode contact and the second cathode contact may be elastically biased by an elastic body embedded in the attachment body.

In one aspect, the elastic body may be a conductive metal spring.

In the present invention, the first positive electrode contact and the first negative electrode contact each made of a conductive metal piece protruding in a hemispherical shape, the second positive electrode contact and the second negative electrode contact is a conductive metal piece with a hemispherical groove, respectively Can be made.

Alternatively, the first positive electrode contact and the first negative electrode contact are each made of a semi-spherical grooved conductive metal piece, and the second positive electrode contact and the second negative electrode contact are each formed in a hemispherical conductive metal piece. Can be done.

In another aspect, the first connection contact may further include at least a first communication contact, and the second connection contact may further include at least a second communication contact.

Preferably, the first communication contact point and the second communication contact point may contact each other.

Preferably, the first communication contact may be elastically biased by an elastic body embedded in the connector body. Here, the elastic body may be a conductive metal spring. Alternatively, the second communication contact may be elastically biased by an elastic body embedded in the attachment body.

In one aspect, the first communication contact may be made of a conductive metal piece projecting in a hemispherical shape, and the second communication contact may be made of a conductive metal piece having a hemispherical groove.

Alternatively, the first communication contact may be made of a semi-spherical grooved conductive metal piece, and the second communication contact may be formed of a semi-spherical conductive metal piece.

In another aspect, at least one of the first anode contact, the first cathode contact, the second cathode contact, and the second cathode contact may be made of a fuse material.

According to the present invention, even when a plurality of battery modules are stacked up and down, the magnetic connector portion and the magnetic terminal portion are coupled to each other by magnetic attraction, so that the contact between the battery modules vertically adjacent to each other is not performed. Low resistance electrical coupling, preferably communication coupling with good communication quality, can be achieved automatically.

The following drawings appended hereto illustrate one embodiment of the present invention, and together with the following description serve to further understand the spirit of the present invention, the present invention is limited only to those described in such drawings. It should not be interpreted.
1 and 2 are top and bottom perspective views, respectively, of the battery module used in the configuration of the power storage system according to an embodiment of the present invention.
FIG. 3 is a cross-sectional view illustrating a vertical stack structure of battery modules when the battery modules illustrated in FIGS. 1 and 2 are stacked up and down to form a power storage system.
4 is a partial cross-sectional view illustrating an example of a magnetic connection structure formed by a magnetic connector portion and a magnetic terminal portion according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own applications. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only one embodiment of the present invention and do not represent all of the technical idea of the present invention, various equivalents that may be substituted for them in the present invention point of view. It should be understood that there may be variations and examples.

1 and 2 are top and bottom perspective views, respectively, of the battery module used in the configuration of the power storage system according to an embodiment of the present invention.

1 and 2, a battery module 10 according to an embodiment of the present invention includes a battery stack (see 11 in FIG. 3) and a battery management system (Battery Management System) 12 in a housing having a rectangular parallelepiped shape. Has a built-in structure.

The battery stack includes a plurality of unit cells connected in series and / or in parallel, and includes a positive electrode terminal and a negative electrode terminal exposed to the outside. The unit cell may be, for example, a lithium polymer battery.

The battery management system monitors the voltage of each unit cell included in the battery stack, the total voltage of the battery stack, the charge or discharge current of the battery stack, the temperature of each unit cell or the battery stack. To this end, the battery management system is electrically coupled with the battery stack.

Although the battery module 10 is not essential, the mounting recess 13 may be provided at the corner of the upper surface, and the mounting protrusion 14 may be provided at the corner of the lower surface. Positions in which the seating recess 13 and the seating protrusion 14 are formed may be interchanged with each other.

The battery module 10 may include a magnetic attachment portion 13 on an upper surface and a magnetic connector portion 14 on a lower surface. Unlike the drawings, positions at which the magnetic attachment portion 13 and the magnetic connector portion 14 are formed may be interchanged with each other.

The magnetic attachment portion 13 has a structure recessed from an upper surface of the battery module 10, and the magnetic connector portion 14 has a structure protruding from the lower surface. However, the present invention is not limited thereto.

3 is a cross-sectional view illustrating a vertical stack structure of the battery modules 10 when the power storage system is configured by stacking the battery modules 10 illustrated in FIGS. 1 and 2 up and down.

Referring to FIG. 3, the power storage system 20 may include a magnetic connection structure between a plurality of battery modules 10 stacked up and down, and a lower surface of an upper battery module facing up and down and an upper surface of a lower battery module. 21).

When the plurality of battery modules 10 are stacked up and down, the seating recess 13 and the seating protrusion 14 provided on the upper and lower surfaces of each battery module 10 are coupled to each other. Therefore, the plurality of battery modules 10 can maintain a stable vertical stack structure.

The magnetic connection structure 21 includes a magnetic attachment portion 15 and a magnetic connector portion 16 coupled by magnetic attraction.

When the plurality of battery modules 10 are stacked, the uppermost battery module 10 may not include the magnetic attachment portion 15, and the lowermost battery module 10 does not include the magnetic connector portion 16. You may not.

4 is a partial cross-sectional view showing the magnetic coupling structure 21 in more detail.

Referring to FIG. 4, the magnetic connector part 16 may include a connector body 16B provided with a first magnet 16A and a first connection contact 16C exposed on a surface of the connector body 16B. Can be.

Preferably, the first connection contact 16C is a first electrically coupled with each of the positive and negative terminals of the battery stack 11 included in the battery module 10 provided therewith, through the power line P, respectively. It may include an anode contact 16C ₁ and a first cathode contact 16C ₂ .

The magnetic attachment portion 15 is attached in a position aligned with the attachment body 15B on which the second magnet 15A faces the first magnet 16A and the first connection contact 16C. The second connection contact 15C exposed on the surface of the body 15B may be included.

Preferably, the second connection contact 15C is a second positive contact coupled to each of the positive and negative terminals of the battery stack 11 included in the battery module 10 having the second coupling contact via the power line P, respectively. 15C ₁ and the second cathode contact 15C ₂ .

Preferably, the polarity of the second magnet 15A and the polarity of the first magnet 16A are opposite to each other. Accordingly, the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ , and the second negative electrode contact 15C _{2 are} connected to the connector body 16B and the attachment body. At the contact interface of 15B, the first magnet 16A and the second magnet 15A may be in contact with each other by magnetic attraction.

Preferably, the first magnet 16A may be embedded along the edge of the connector body 16B. Alternatively, the first magnet 16A may be embedded in the central portion of the connector body 16B.

Similarly, the second magnet 15A may be embedded along the edge of the attachment body 15B. Alternatively, the second magnet 15A may be embedded in the central portion of the attachment body 15B.

Meanwhile, the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ may be elastically biased by an elastic body 16E embedded in the connector body 16B. Preferably, the elastic body 16E may be made of a conductive metal spring. Alternatively, the elastic body 16E may be replaced with another elastic material that is conductive.

Alternatively, instead of the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ and the second negative electrode contact 15C ₂ are embedded in the attachment body 15B. Elastically biased by the elastic body. In this case, as the elastically biased structure, the structure applied to the connector body 16B may be substantially the same.

When the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ or the second positive electrode contact 15C ₁ and the second negative electrode contact 15C ₂ are elastically biased, the first positive electrode contact 16C ₁ ) When the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ , and the second negative electrode contact 15C ₂ are in contact with each other, either side is pressed by the other side and moved toward the elastic body by elasticity. The degree of bias is further increased. An elastic biased contact strongly presses the other contact by an elastic force. Accordingly, the electrical contact between the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ , and the second negative electrode contact 15C ₂ is well maintained, resulting in a good contact resistance. Can be reduced.

Preferably, the first positive electrode contact 16C ₁ , the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ , and the second negative electrode contact 15C ₂ may have a shape that conforms to each other. Can be. Such a shape-matching structure provides contact resistance between the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ , and the second negative electrode contact 15C ₂ . Can be reduced.

Preferably, the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ may each be formed of a conductive metal piece protruding in a hemispherical shape. The second positive electrode contact 15C ₁ and the second negative electrode contact 15C ₂ may each be formed of a conductive metal piece having a hemispherical groove.

Alternatively, the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ may be formed of a semi-spherical grooved conductive metal piece, respectively, and the second positive electrode contact 15C ₁ and the first positive electrode contact 16C ₁ may be formed. The two cathode contacts 15C ₂ may be made of conductive metal pieces each protruding in a hemispherical shape.

In addition to the above configuration, the shape matching structure between the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ , and the second negative electrode contact 15C ₂ may be used. Many variations are possible.

In the present invention, although not essential, at least one of the first positive electrode terminal 16C ₁ , the first negative electrode terminal 16C ₂ , the second positive electrode terminal 15C1, and the second negative electrode terminal 15C2 is preferable. Preferably, at least one of the first cathode terminal 16C ₁ and the first cathode terminal 16C ₂ may be made of a fuse material.

The fuse material includes at least lead and tin. In this case, when a short circuit current flows through the power line P, the terminal connected to the power line P is melted to block a path through which the short circuit current flows. In particular, when the elastic body 16E is made of a spring, the short circuit current can be more effectively blocked because the fused fuse material is introduced into the spring to minimize the surface energy.

On the other hand, although not essential, the first connection contact 16C may be a first communication contact coupled to communicate with the battery management system 12 included in the battery module 10 provided with the communication line C. It may further include (16C ₃ , 16C ₄ ). In addition, the second connection contact 15C may include a second communication contact 15C ₃ coupled to communicate with the battery management system 12 included in the battery module 10 including the communication line C. 15C ₄ ) may be further included.

Preferably, the first communication contact 16C ₃ , 16C ₄ and the second communication contact 15C ₃ , 15C ₄ may contact each other at a contact interface between the connector body 16B and the attachment body 15B.

In this embodiment, when the first communication contact (16C ₃ , 16C ₄ ) and the second communication contact (15C ₃ , 15C ₄ ) between the up and down adjacent battery modules 10 is made, the battery module ( A serial communication interface may be formed between the devices 10, and the battery management system 12 included in each battery module 10 may perform data communication in two directions through the serial communication interface.

The serial communication interface is just one example. Therefore, the structure of the communication network formed by contacting the first communication contact 16C ₃ , 16C ₄ and the second communication contact 15C ₃ , 15C ₄ may be variously modified.

In addition, although the number of the contacts constituting the first communication contact 16C ₃ , 16C ₄ and the second communication contact 15C ₃ , 15C _{4 is} shown as two in FIG. ₄ , the number of contact points is shown in the first contact point. It is possible to change the number according to the communication network provided in the communication network or the battery management system 12 formed by the contact between the communication contact (16C ₃ , 16C ₄ ) and the second communication contact (15C ₃ , 15C ₄ ).

Preferably, the first communication contact 16C ₃ , 16C ₄ may be elastically biased by the elastic body 16E embedded in the connector body 16B. Preferably, the elastic body 16E may be made of a conductive metal spring. Alternatively, the elastic body 16E may be replaced with another elastic material that is conductive.

Alternatively, the second communication contact 15C ₃ , 15C ₄ may be elastically biased by an elastic body embedded in the attachment body 15B instead of the first communication contact 16C ₃ , 16C ₄ . In this case, as the elastically biased structure, the structure applied to the connector body 16B may be substantially the same.

As such, when the first communication contact 16C ₃ , 16C ₄ or the second communication contact 15C ₃ , 15C ₄ is elastically biased, the elastically biased contact strongly presses the counterpart contact by an elastic force. Accordingly, the contact between the first communication contact 16C ₃ , 16C ₄ and the second communication contact 15C ₃ , 15C ₄ is well maintained so that the first communication contact 16C ₃ , 16C ₄ and the first contact point are maintained. The contact resistance between the two communication contacts 15C ₃ , 15C ₄ can be reduced. As such, when the contact resistance is reduced, the quality of data communication through the first communication contacts 16C ₃ and 16C ₄ and the second communication contacts 15C ₃ and 15C ₄ may be improved.

Preferably, the first communication contact 16C ₃ , 16C ₄ and the second communication contact 15C ₃ , 15C ₄ may have a structure that conforms to each other. This shape matching structure may contribute to reducing the contact resistance between the first communication contact 16C ₃ , 16C ₄ and the second communication contact 15C ₃ , 15C ₄ .

Preferably, each of the first communication contacts 16C ₃ and 16C ₄ may be formed of a conductive metal piece protruding in a hemispherical shape. The second communication contacts 15C ₃ and 15C ₄ may each be formed of a conductive metal piece having a hemispherical groove.

Alternatively, the first communication contacts 16C ₃ , 16C ₄ may each be made of a semi-spherical grooved conductive metal piece, and the second communication contacts 15C ₃ , 15C ₄ may each protrude in a hemispherical shape. It may be made of metal pieces.

In addition to the above configuration, the shape matching structure between the first communication contacts 16C ₃ and 16C ₄ and the second communication contacts 15C ₃ and 15C ₄ may be modified in various forms.

In the above-described embodiment, the positions of the magnetic connector portion 16 and the magnetic terminal portion 15 may be interchanged with each other. That is, the magnetic connector portion 16 may be provided on the upper surface of the battery module 10, and the magnetic terminal portion 15 may be provided on the lower surface of the battery module 10. Even in this case, the structural features described in the above-described embodiments may be applied substantially the same. Therefore, the present invention is not limited by the relative positions of the magnetic connector portion 16 and the magnetic terminal portion 15.

In the above-described embodiment, the positions of the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ and the positions of the second positive electrode contact 15C ₁ and the second negative electrode contact 15C ₂ are up and down. It may vary depending on the electrical connection relationship between adjacent battery modules 10.

For example, when up and down adjacent battery modules 10 are connected in series, positions of the first positive electrode contact 16C ₁ and the first negative electrode contact 16C ₂ , the second positive electrode contact 15C ₁ , and The position of the second negative electrode contact 15C ₂ may be changed such that the contacts having opposite polarities face each other.

In the power storage system according to the present invention, even when a plurality of battery modules are stacked up and down, the magnetic connector unit and the magnetic terminal unit are coupled to each other by magnetic attraction, without performing a separate electrical wiring operation. Electrical couplings with low contact resistance, preferably communication couplings with good communication quality, can also be made automatically between them.

Although the present application has been described by way of limited embodiments and drawings, the present application is not limited thereto and will be described below by the person skilled in the art and the technical spirit of the present application. Of course, various modifications and variations are possible within the scope of the claims.

Claims (19)

A plurality of battery modules stacked up and down; And
It includes a magnetic connection structure formed between the upper surface of the lower battery module and the lower surface of the upper battery module facing up and down,
The magnetic connection structure,
A magnetic connector part formed on one side of the lower surface and the upper surface and including a connector body provided with a first magnet and a first connection contact exposed on a surface of the connector body; And
A second body formed on the other side of the lower surface and the upper surface and having a second magnet disposed to face the first magnet and exposed to the surface of the attachment body at a position aligned with the first connection contact; A magnetic attachment including a connection contact,
The first connection contact point and the second connection contact point contact each other by magnetic attraction of the first magnet and the second magnet at a contact interface between the connector body and the attachment body,
The first connection contact includes at least a first cathode contact and a first cathode contact, the second connection contact includes at least a second anode contact and a second cathode contact,
At least one of the first anode contact, the first cathode contact, the second cathode contact, and the second cathode contact is made of a fuse material,
And wherein the contact made of fuse material is elastically biased in contact with the spring.
The method of claim 1,
And the first magnet is embedded along an edge of the connector body or at a central portion thereof.
The method of claim 1,
And the second magnet is embedded along an edge of the attachment body or at a central portion thereof.
delete The method of claim 1,
And the first anode contact and the first cathode contact are in electrical contact with the second cathode contact and the second cathode contact, respectively.
The method of claim 1,
And the first anode contact and the first cathode contact are in electrical contact with the second cathode contact and the second cathode contact, respectively.
The method of claim 1,
And the first anode contact and the first cathode contact are elastically biased by a spring embedded in the connector body.
The method of claim 1,
And the second anode contact and the second cathode contact are elastically biased by a spring embedded in the attachment body.
The method according to claim 7 or 8,
And the spring is a conductive metal spring.
The method of claim 1,
The first positive electrode contact and the first negative electrode contact each made of a conductive metal piece protruding in a hemispherical shape,
And the second anode contact and the second cathode contact are each made of a conductive metal piece having a hemispherical groove.
The method of claim 1,
The first positive electrode contact and the first negative electrode contact each made of a conductive metal piece of hemispherical grooves,
And the second anode contact and the second cathode contact each comprise a conductive metal piece protruding in a hemispherical shape.
The method of claim 1,
The first connection contact further includes at least a first communication contact,
The second connection contact further comprises at least a second communication contact.
The method of claim 12,
And the first communication contact point and the second communication contact point contact each other.
The method of claim 12,
And the first communication contact is elastically biased by a spring embedded in the connector body.
The method of claim 12,
And the second communication contact is elastically biased by a spring embedded in the attachment body.
The method according to claim 14 or 15,
And the spring is a conductive metal spring.
The method of claim 12,
The first communication contact is made of a conductive metal piece protruding in a hemispherical shape,
The second communication contact is a power storage system, characterized in that made of a semi-spherical grooved conductive metal piece.
The method of claim 12,
The first communication contact is made of a conductive metal piece of hemispherical grooves,
And the second communication contact is made of a conductive metal piece protruding in a hemispherical shape.
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