KR101507222B1 - Energy storage system with connector easy connecting wire - Google Patents

Abstract

The present invention relates to an energy storage system having a surge-preventive module connector, and more particularly, to an energy storage system for generating energy by electrically connecting one or more battery modules, a plurality of battery modules, And more particularly to an energy storage system having a connector that facilitates the wiring between several slaves for controlling and sensing the slaves.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an energy storage system,

The present invention relates to an energy storage system having a surge-preventive module connector, and more particularly, to an energy storage system for generating energy by electrically connecting one or more battery modules, a plurality of battery modules, And more particularly to an energy storage system having a connector that facilitates the wiring between several slaves for controlling and sensing the slaves.

The energy storage system is associated with renewable energy and power systems such as solar cells and is configured to store power when load demand is low and to use stored power when the load demand is high. It is an energy storage device containing a large amount of secondary batteries used in electronic devices such as mobile phones and notebook computers.

The secondary battery is accommodated in a plurality of trays, a plurality of trays are accommodated in the rack, and a plurality of racks are housed in the cabinet.

The plurality of racks each have one or more battery modules mounted thereon, and the battery modules are electrically connected to each other to output power supplied to the load.

At this time, when one or more battery modules are connected in series or in parallel, a surge may be generated due to contact resistance. Such a surge may lead to burnout of electrical components, and the electric shock of the operator may cause a risk of burns, which must be urgently improved.

In addition, the conventional energy storage system has a plurality of racks which are provided with a plurality of racks in one cabinet and are fastened in a sliding manner. Wherein each rack has at least one battery module mounted thereon and is electrically connected to each battery module. In addition, each rack must be electrically connected to each other, so wiring work must be done to connect the rack and rack from the back of the cabinet.

However, conventionally, a method of directly connecting the battery module group formed in the rack and the battery module group of the other rack in the cabinet is adopted, and thus the wiring on the rear side of the cabinet is complicated. Therefore, if any one of the racks that are slidably coupled to the cabinet is broken, the wirings connected to the battery module groups of the corresponding racks must be disconnected from each other and interconnected with the battery module groups stored in the other racks. The replacing operation of the battery module was not easy.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a battery module having a detachable module connector for facilitating electrical connection of at least one battery module in an energy storage system, And it is an object of the present invention to provide an energy storage system that can be easily wired to prevent an electric shock accident.

It is another object of the present invention to provide a cabinet in which wiring work for electrically connecting a plurality of racks and racks is simple, and rear wirings of a cabinet having a plurality of racks are simple, And an energy storage system in which wiring is easy.

The present invention includes the following embodiments in order to achieve the above object.

A preferred embodiment of an energy storage system that facilitates wiring according to the present invention includes: a cabinet having a storage space divided into at least one from the inside; One or more racks accommodating one or more battery modules to be electrically connected to each other and being slidably received in a receiving space of the cabinet and electrically connected to each other; A rack connector to which a power cable extending from the battery module is connected at a rear surface of the rack; And a cabinet connector electrically connected to a power cable at a back surface of the cabinet in which the rear surface of the rack is closely contacted, wherein the rack connector and the cabinet connector are coupled with each other while the rack is drawn into the cabinet storage space Wherein the rack comprises at least one battery module group in which the at least one battery module is connected and grouped; A module connector to which the power cables connected in the at least one battery module group are respectively connected and fix the connected power cables so as to maintain the mutually disconnection state; And a module connector which is detachably attached to the module connector so as to be disconnected from the module connector when the module connector is pulled out of the module connector, And a formed module plug.

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In another embodiment of the present invention, the rack has a detachable opening formed at the front surface thereof; And a door rotatably fixed on the front surface to open and close the attachment / detachment opening.

According to another embodiment of the present invention, the door further includes an insertion protrusion protruding from one surface, and the front surface further includes an insertion hole into which the insertion protrusion is inserted and fixed.

In another embodiment of the present invention, the rack includes a front frame, which is decorated with any one of a symbol, a number, and a pattern as a wall surface that protrudes forward and extends downward from the upper side of the front side; And a switch installed at an end face of the front frame so as not to be exposed from the outside and unlocking the door.

In another embodiment of the present invention, the rack connector includes a first plate which is brought into close contact with the rear surface of the rack; An embossed portion formed on the first plate so as to be embossed; And a first power terminal protruded from the raised portion and projecting from the first power terminal.

In another embodiment of the present invention, the embossed portion further includes a terminal withdrawing groove which is directed to form a spaced-apart space from an outer surface of the first power terminal.

In another embodiment of the present invention, the cabinet connector includes: a second plate which is fixedly attached to a rear surface of the cabinet; An engraved portion formed in the second plate and formed with an embossed portion projecting from the rack connector; And a second power terminal to which a power cable electrically connected to the other cabinet connector is connected to the engraved portion.

In another embodiment of the present invention, the embossed portion includes a first power terminal to which a power cable extending from the inside of the rack is connected, and the second power terminal is electrically connected to the first power terminal And a terminal hole formed on the inner surface of the conductor so as to be energized.

In another embodiment of the present invention, the energy storage system includes at least one slave for detecting an abnormal condition of the battery module in the rack, and a master for controlling the at least one slave, And a first signal line connector to which a signal line extending from the slave is connected, wherein the cabinet connector further comprises a second signal line connector to which a signal line connected to the slave of the master or the other rack is connected from the rear side, And the first signal line connector and the second signal line connector are mated together.

In another embodiment of the present invention, the rack further includes a partition wall which is a wall surface erected on the bottom surface and insulates and separates between at least one battery module fixed at one side and the other side, respectively.

In the energy storage system having a plurality of racks mounted with one or more battery modules, the wiring between the battery module, the battery module, and the rack and the rack can be easily performed by the removable connector, Is prevented.

Further, the present invention provides a connector having a male / female coupling structure on the rear surface of the cabinet and on the rear surface of the rack, so that a plurality of racks can be connected in series or parallel, or a plurality of slaves It is possible to simplify the connection and arrangement of the signal lines extended to the signal lines, thereby shortening the working time.

1 is a perspective view of an energy storage system using wiring according to the present invention,
FIG. 2 is a perspective view showing a connection between a rack and a cabinet in an energy storage system in which wiring is easy according to the present invention, FIG.
FIG. 3 is a block diagram showing a master and a slave in an energy storage system in which wiring is easy according to the present invention,
4 is a plan view of a rack in an energy storage system in which wiring is easy according to the present invention,
Figure 5 is a side view of a rack in an energy storage system that facilitates wiring according to the present invention;
6 is a perspective view showing a rack in an energy storage system in which wiring is easy according to the present invention,
FIG. 7 is a plan view showing a joining process of a module connector in an energy storage system in which wiring is easy according to the present invention, FIG.
8A and 8B show front and rear views of a rack connector in an energy storage system that facilitates wiring according to the present invention,
FIGS. 9A and 9B illustrate front and rear views of a cabinet connector in an energy storage system that facilitates wiring according to the present invention;
10 and 11 are front and rear views, respectively, of a cabinet and a rack connector in an energy storage system in which wiring is easy according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of an energy storage system that facilitates wiring according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of an energy storage system that facilitates wiring according to the present invention, FIG. 2 is a perspective view showing a connection between a rack and a cabinet in an energy storage system in which wiring is easy according to the present invention, Fig. 2 is a block diagram showing a master and a slave in this energy storage system.

1 to 3, an energy storage system according to an embodiment of the present invention includes one or more racks 200 in which at least one battery module is electrically connected, and at least one rack 200, (Not shown).

The cabinet 100 is formed with a plurality of storage spaces divided in the vertical direction and a sliding rail structure for supporting the racks 200 in a sliding manner in divided storage spaces is formed. Here, the sliding rail structure is generally known in the art and its detailed description will be omitted.

In addition, the energy storage system includes a slave 320 for sensing power input / output and abnormal conditions of one or more battery module groups to which one or more battery modules are electrically connected in each rack 200, And a master 310. The master 310 is installed in one rack 200 located at the uppermost position in the cabinet 100 and a plurality of slaves 320 are installed at one or more racks 200 And controls each battery module group.

The cabinet 100 includes an arm or a male cabinet connector 120 so as to be electrically connected to a battery module mounted on the inner side of the rack 200 from the rear surface of each storage space.

The cabinet connector 120 will be described later with reference to Figs. 8 to 10. Fig.

The rack 200 is coupled to the cabinet 100 so as to be slidably received in a space divided into a plurality of spaces, and one or more battery modules are electrically connected to the inside of the rack 200. Such a structure of the rack 200 will be described with reference to Figs.

FIG. 4 is a plan view showing a rack 200 in an energy storage system that facilitates wiring according to the present invention. FIG. 5 is a side view showing the rack 200 in an energy storage system in which wiring is easy according to the present invention. 7 is a plan view showing a coupling process of the module connector 220 in an energy storage system in which wiring is easy according to the present invention .

Referring to FIGS. 4 to 7, the rack 200 includes a main body 210 that forms a separate receiving space from the inside, and at least one battery cell is electrically connected to the inside of the main body 210, And a module plug 250 coupled to the module connector 220 so as to be detachably connected to power lines on both sides of the module connector 220. The module connector 220 is electrically connected to the battery module, And a rack connector 260 coupled to the cabinet connector 120 in an arcuate manner.

The main body 210 has a wall surface (not numbered) protruding upward from the front, rear, left and right corners of the bottom surface (not numbered), and a plurality of battery module groups And partitioning walls 218 that isolate and compartmentalize. At least one or more heat dissipation holes 217 are formed in the wall surface so as to dissipate the heat radiated from the inside to the outside.

In addition, the main body 210 includes a front frame 212 protruding forward and decorated with a variety of patterns and / or shapes for esthetics, a front surface forming an upright wall on the lower side of the front frame 212, A door 214 that is rotated to close the attachment / detachment opening 211, and a door 214 that locks the door 214. In addition, (Not shown).

The front frame 212 protrudes forward so that various shapes, symbols, and / or logos are formed on the wall surface to provide a sense of beauty. More preferably, the length is adjusted so that the lower part of the front surface protrudes forward from the upper side of the front surface and extends downward. Particularly, the end face of the front frame 212 is formed in the shape of "∩" so that the switch 216 is not exposed to the outside. That is, the end face of the front frame 212 is formed with an upward groove or a hemispherical shape so that the switch 216 is not exposed from the outside.

The front surface 213 is vertically erected on the lower side of the front frame 212 and is closed by the rotation of the door 214.

The door 214 is hinged to a hinge shaft (not shown) formed at the lower end of the front surface 213 to be rotatable so that the door 214 is rotated in the vertical direction in the front surface 213. The door 214 is preferably configured to be rotated when the switch 216 is turned on. To this end, the door 214 includes an insertion protrusion 214 protruding from the upper end thereof.

In addition, a locking means (not shown) is provided inside the front surface 213 to form an insertion port 213a into which the insertion protrusion 214 is inserted and to release the engagement when the switch 216 is turned on inside .

The insertion protrusion 214 and the locking means (not shown) as described above can be selectively applied to a known apparatus. For example, the insertion protrusion 214 is formed with grooves (not shown) on both sides of both sides thereof, and the locking means (not shown) is rotatable in the left and right direction by elastic force, (Not shown), which are respectively fastened to both side surface grooves of the base plate 10, respectively.

That is, the latches (not shown) are pressed while being inserted while the insertion protrusions 214 are inserted, and are returned to their original positions by the elastic force, and the ends are seated in the grooves formed on both sides of the insertion protrusions 214, Thereby fixing the projection 214. At this time, when the switch 216 is pressed, the latch is forcibly rotated outward to release the latching of the insertion protrusion 214. Accordingly, when the switch 216 is pressed, the latch is rotated outward to release the latching state of the insertion protrusion 214. The door 214 is rotated when the force applied to the insertion protrusion 214 disappears from the latch so as to expose the attachment / detachment opening 211.

Such a configuration corresponds to any one of various embodiments, and if the person is engaged in the same industry, the configuration of the switch 216 and the locking means can be realized by the above description, and therefore, the drawings are omitted and the explanation is briefly described Respectively.

The attachment / detachment opening 211 exposes an insertion end 221 of the module connector 220, which is open at the lower end of the front surface and is fixed to the inside.

The rear opening 219 is formed in such a manner that a rack connector 260, which will be described later, can be inserted and fixed from the outside to the inside of the main body 210.

One or more battery modules 241 to 244 are electrically connected to the battery module groups 240 and 240 '. In more detail, the battery modules 241 to 244 are stacked one upon another with at least one battery cell electrically connected to form the battery modules 241 to 244. The battery modules 241 to 244 are fixed at positions opposite to each other on the inside of the main body 210 with respect to the partition wall 218.

That is, the battery module group 240 or 240 'includes a first battery module group 240 in which the first battery module 241 and the second battery module 242 are electrically connected to each other at one side of the rack 200, And a second battery module group 240 'in which the third battery module 243 and the fourth battery module 244 are connected in series or in parallel and electrically energized from the other side of the rack 200.

The first battery module group 240 is connected to the first battery module 241 and the second battery module 242 and the third battery module 243 and the fourth battery module 244 are connected to each other. The electrically connected second battery module groups 240 'are connected to different power terminals (not shown) of the module connector 220, respectively.

The module connector 220 has an insertion end 221 to which the module plug is fastened at the side of the attachment and detachment opening 221 and an outermost end 223 of the second battery module group 240 ' The battery modules 242 and 244 may be connected to each other via a power supply terminal. Here, a power terminal connected to the first battery module group 240 of the module connector 220 and a power terminal connected to the second battery module group 240 'are disconnected from each other.

In FIG. 4, the disconnected power terminal of the module connector 220 is shown connected by the module plug 250.

The module plug 250 is detachably coupled to the module connector 220 and is connected to the first battery module group 240 and the second battery module group 240 'on one side and the other side, And power terminals of the module connector 220 are connected to energize the battery module groups 240 and 240 'on both sides. That is, the module plug 250 is coupled to the module connector 220 and connects the power terminals of the two battery module groups 240 and 240 'to each other. The connection system of the first battery module group 240 and the second battery module group 240 'is disconnected.

This is to prevent the occurrence of surges due to the contact resistance accumulated due to the increase in the number of the battery modules 241 to 244 in the process of electrically connecting the plurality of battery modules 241 to 244 in the rack 200 in the related art. That is, the operator electrically connects the first battery module 241 and the second battery module 242 on one side and electrically connects the third battery module 243 and the fourth battery module 244 on the other side .

As the number of the battery modules 241 to 244 forming the battery module groups 240 and 240 'on one side and the other side is increased, the contact resistance is increased to connect the battery module groups 240 and 240' Surge may occur.

For example, even if the battery module groups 240 and 240 'on both sides are connected to the module connector 220 by the operator, the surge is not generated because the module plug 250 is disconnected before the module plug 250 is fastened . Therefore, the operator connects both battery module groups 240 and 240 'to the module connector 220 and inserting the module plug 250 into the module connector 220 to connect the battery module groups 240 and 240' Is electrically energized.

In addition, when the module plug 250 and the module connector 220 are easily detachable as described above, if a failure occurs in any one of the battery module groups 240 and 240 'on both sides, The battery module may be replaced or the power module may be formed with only the battery modules other than the battery module.

In addition, in the energy storage system, the rack 200 on which a plurality of battery modules are mounted is provided with a protection circuit for detecting an abnormal condition of the battery module and a slave 320 on which components for communicating with the master 310 are mounted . Each of the slaves 320 senses power input / output and abnormal conditions of the battery modules 241 to 244 and transmits control and detection signals through communication with the master 310.

The master 310 is installed in any one of a plurality of racks 200 of the cabinet 100 and is connected to one of the battery modules 241 to 244 through one or more slaves 320 installed for each of the racks 200. [ It is possible to detect and display an abnormal situation. The configuration and operation of the master 310 and the slave 320 are the same as those of the conventional art, and detailed descriptions and drawings are omitted.

Although the slaves 320 are not shown in FIGS. 4 to 7, the slaves 320 are connected to the battery module groups 240 and 240 ', and are connected to the rack connector 260 and the cabinet connector 120 And is connected to the master 310. To this end, the rack 200 further includes signal line guiding means 230 for insulating and guiding signal lines connected for communication between the slave 320 and the master 310.

4 and 7, the signal line guide unit 230 extends from both sides of the partition wall 218 that extends between the battery module groups on both sides to insulate and partition the battery module groups on both sides. The signal line guiding means 230 includes a rack connector 260 formed on the rear side of the rack 200 and a signal line connected to the slave 320 on the inside thereof is connected to the rear opening 219, To the rack connector (260) which is fixed to the rack connector (260).

The rack connector 260 and the cabinet connector 120 will be described with reference to FIGS. 8 to 10. FIG.

 8A and 8B are views showing a rack connector in an energy storage system that facilitates wiring according to the present invention. Fig. 8A is a front view of the rack connector 260, and Fig. 8B is a rear view of the rack connector 260. Fig.

8A and 8B, the rack connector 260 includes a first plate 261 which is in close contact with the outside of the rear opening 219 of the rack 200 and is fixed by fastening means such as screws, A first power terminal 254 connected to a power cable connected to the battery module groups 240 and 240 'on both sides of the raised portion 264, And a first signal line connector 263 to which an end of a signal line 271 extending from the slave 320 is fastened at the embossed portion 264.

The first plate 261 is closely attached to the rear surface of the rack 200, and a screw is inserted and fixed. For this, the first plate 261 is formed with at least one first screw hole 261a through which a screw is inserted, and a raised portion 264 is formed to be protruded from the front surface.

A power cable connected to a group of the battery modules is connected to the rear surface of the first plate 261 at an end of the first power terminal 262 and an inlet of the first signal line connector 263 is formed.

The embossed portion 264 protrudes forward from the center of the first plate 261 and is inserted into the engraved portion 124 formed on the second plate 121 of the cabinet connector 120. The embossed portion 264 is formed with a terminal lead-out groove 264a which is recessed to form a space in which the second power terminal 122 of the cabinet connector 120 is fastened to the first power terminal 262, do.

The terminal lead-out groove 264a is formed such that the first power terminal 262 protrudes and is recessed inward from the boss 264 so as to form an empty space therebetween. The first power terminal 262 is inserted into the second power terminal 122 of the cabinet connector 120 and the second power terminal 122 is seated in the terminal lead groove 264a .

The first power terminal 262 is a terminal through which one or more battery modules 241 to 244 are inserted and output from the inside of the rack 200. The second power terminal of the cabinet connector 120 122, respectively. 8A, the first power terminal 262 protrudes from the terminal lead-out groove 264a, and the second power terminal 122 is connected to the first power terminal 262 Shaped terminal hole 262a to be inserted.

The first signal line connector 263 has an end 271 of a signal line connected to the slave 320 extending through the signal line guiding means 230 at the rear side, And at least one fastening hole into which the connector is inserted. The first signal line connector 263 is male and female connected to the second signal line connector 123 of the cabinet connector 120.

Therefore, when a worker fixes and connects the power cable of the battery module group 240 or 240 'to the first power terminal 262 from the rear surface of the first plate 261 of the rack connector 260 through a mechanism such as a bolt And the end 271 of the signal line connected through the signal line guide unit 230 is inserted into the first signal line connector 263 so that the battery module groups 240 and 240 ' The power cable and the signal line 271 connected to the slave 320 can be fastened to the rack connector 260.

9A and 9B are perspective views illustrating a cabinet connector in an energy storage system that facilitates wiring according to the present invention. 9A is a front view of the cabinet connector, and FIG. 9B is a rear view.

9A and 9B, the cabinet connector 120 includes an engraved portion 124 formed to be engraved so as to insert the convex portion 264 of the first plate 261 into the rack connector 260, A second power terminal 122 having a terminal hole 122a protruding from the engraved portion 124 and having the first power terminal 262 inserted therein; And a second signal line connector 123 protruded from the engraved portion 124 to the second power terminal 122 and inserted into the first signal line connector 263.

The second plate 121 is provided with an engraved portion 124 engraved so that the embossed portion 264 is drawn in. The second plate 121 is closely attached to the rear surface 110 of the cabinet 100 outside the engraved portion 124 And fixed by screws. To this end, the second plate 121 includes at least one second screw hole 121a.

The second power source terminal 122 includes a terminal hole 122a protruding from the engraved portion 124 and having a central portion into which the first power source terminal 262 is inserted. That is, if the first power terminal 262 has a male shape, the second power terminal 122 has a female shape so that the first power terminal 262 can be inserted.

The second signal line connector 123 includes one or more coupling terminals that are connected to signal lines connected to the slave of the master or the other rack from the rear and protrude from the engraved portion 124 of the front side, 263).

When the cabinet connector 120 and the rack connector 260 having the male and female coupling structures mutually corresponding to each other are drawn into one of the plurality of storage spaces divided into one or more from the cabinet, . That is, when the operator pushes the rack 200 into the storage space of the cabinet 100, the rack connector 260 is inserted into the cabinet connector 120 mounted on the rear surface 110 of the cabinet, and is electrically energized. This is as shown in Figs. 10 and 11. Fig.

FIG. 10 is a view showing a coupling state of the cabinet connector 120 and the rack connector 260 in an energy storage system in which wiring is easy according to the present invention, and FIG. 11 is a side view of the rear surface of the cabinet connector 120 Fig.

10 and 11, the embossed portion 264 protruding from the front surface of the first plate 261 of the rack connector 260 includes a depressed portion 124 formed at an obtrusive angle on the front surface of the cabinet connector 120, . The first power terminal 262 is inserted into the terminal hole 122a of the second power terminal 122 and the second signal line connector 123 is inserted into the first signal line connector 263 . Here, the second power terminal 122 is seated such that its outer surface is in close contact with the outer surface of the terminal lead-out groove 264a of the relief portion 264.

The internal structure of the first power supply terminal 262 and the second power supply terminal 122, the first signal line connector 263, and the second signal line connector 123 is generally a well-known connector and terminal fastening structure A detailed description thereof will be omitted.

The second power terminal 122 is fixed to the rack connector 260 at the front side and the power cable 150 connected to the second power terminal 122 of the other cabinet connector 120 is fixed at the rear side. The power cable 150 is connected between the second power terminals 122 of the cabinet connector 120 coupled to the power terminals of the different rack connectors 260 to electrically connect the one or more racks 200 .

The connection terminal of the power supply cable 150 is seated on the second power supply terminal 122 at the rear of the second power supply terminal 122 and the bolt 140 is fastened to the terminal hole 122a, A power cable is fixed to the power terminal 122.

In addition, the second signal line connector 123 has a terminal 131 to which a signal line 132 connected from the master 310 is connected. Therefore, the second signal line connector 123 is inserted into the first signal line connector 263 while the rack connector 260 and the cabinet connector 120 are fastened. Therefore, the slave 320 of the rack 200 is capable of transmitting and receiving signals with the master 310.

The present invention includes the above-described configuration, and an operation achieved through the above-described configuration will be described below.

The operator firstly installs one or more battery modules in the rack 200 stacked in the vertical direction in the cabinet 100 and installs one or more battery modules 241 fixed to one side and the other side through the partition wall 218 244 are electrically connected to each other to form a first battery module group 240 and a second battery module group 240 '. The worker then inputs the power of each of the battery modules 241 to 244 in the first battery module group 240 and the second battery module group 240 ' Connect the signal lines.

The worker inserts the battery modules 242 and 244 disposed at the outermost positions in the first battery module group 240 and the second battery module group 240 ' . The power source terminals of the module connector 220 are connected to different terminals of the first battery module group 240 and the second battery module group 240 'and are disconnected from each other. Therefore, even though the first battery module group 240 and the second battery module group 240 'are connected to the module connector 220, the module plug 250 is disconnected because it is not fastened.

The operator connects the power cable 150 to the second power terminal 122 from the rear surface of the cabinet connector 120 fixed to the rear surface 110 of the cabinet 100 according to the storage space, And connects the connected signal lines to the second signal line connector 123, respectively.

When the operator pushes the rack 200 into the storage space of the cabinet 100, the rack 200 slides and is seated in the storage space. At this time, the rear surface of the rack 200 is closely attached to the rear surface 110 of the cabinet 100, so that the rack connector 260 and the cabinet connector 120 are fastened to each other.

Accordingly, the rack 200 is electrically connected to the rack 200 by being electrically connected to the cabinet connector 120. The rack 200 is connected to the second signal line connector 123 by a first signal line connector 263 to which a signal line connected by a slave 320 sensing an abnormality of the battery module is coupled, And is communicably connected to the master 310 of the cabinet 100.

As described above, the present invention can prevent fire and electric shock accidents due to surge due to contact resistance when connecting the module connector 220 and the battery module groups to which one or more battery modules are connected by the module plug 250. In addition, since the rack connector 260 and the cabinet connector 120 are formed in a male and female coupling structure, the electrical connection between the rack 200 and the cabinet 100 can be achieved only by simply housing the rack 200 inside the cabinet. It is possible. The coupling structure of the rack connector 260 and the cabinet connector 120 may include a cable connection process for connecting the racks 200 in series or parallel and a signal for communication between the master 310 and the slaves 320. [ The wiring process of the line is easy.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the following claims And changes may be made without departing from the spirit and scope of the invention.

100: cabinet 110: rear of cabinet
120: cabinet connector 121: second plate
121a: second screw hole 122: second power terminal
123: second signal line connector 124: engraved portion
131: signal line end 132: signal line
140: Bolt 150: Power cable
200: rack 210:
211: removable port 212: front frame
213: Front 213a:
214: Door 214a: Insertion projection
216: switch 217:
218: compartment wall 219: rear opening
220: module connector 221: insertion end
230: Signal line guide means 240, 240 ': Battery module group
250: Module plug 260: Rack connector
261: first plate 262: first power supply terminal
263: first signal line connector 264:
310: Master 320: Slave

Claims (11)

A cabinet having a storage space divided from the inner side by one or more;
One or more racks accommodating one or more battery modules to be electrically connected to each other and being slidably received in a receiving space of the cabinet and electrically connected to each other;
A rack connector to which a power cable extending from the battery module is connected at a rear surface of the rack; And
And a cabinet connector electrically connected to a power cable at a rear surface of the cabinet in which the rear surface of the rack is closely contacted,
Wherein the rack connector and the cabinet connector are male and female coupling structures in which the racks are connected to each other while being drawn into a receiving space of the cabinet,
The rack
One or more battery module groups in which one or more battery modules are connected and grouped;
A module connector to which the power cables connected in the at least one battery module group are respectively connected and fix the connected power cables so as to maintain the mutually disconnection state; And
The module connector is detachably attached to the module connector so as to be disconnected from the module connector when the module connector is pulled out of the module connector, An energy storage system that facilitates wiring with a module plug. delete 2. The apparatus of claim 1,
A removable opening formed in the front surface; And
And a door that is rotatably fixed on the front surface and opens and closes the attachment / detachment port. 4. The apparatus of claim 3, wherein the door
Further comprising an insertion projection projecting from one surface,
Wherein the front surface further includes an insertion port through which the insertion protrusion is inserted and fixed. 4. The method of claim 1 or 3, wherein the rack
A front frame protruding forward and downward from the upper side of the front face and being decorated as any one of a symbol, a number, and a pattern; And
Further comprising a switch installed on an end face of the front frame so as not to be exposed from the outside and unlocking the door. The connector according to claim 1, wherein the rack connector
A first plate which is brought into close contact with the rear surface of the rack;
An embossed portion formed on the first plate so as to be embossed; And
And a first power terminal connected to the power cable at a rear side of the first power terminal. The method of claim 6, wherein the embossed portion
Further comprising a terminal withdrawing groove which is inwardly directed to form a space separated from an outer surface of the first power source terminal. The cabinet of claim 1, wherein the cabinet connector
A second plate closely attached to the rear surface of the cabinet;
An engraved portion formed in the second plate and formed with an embossed portion projecting from the rack connector; And
And a second power terminal to which a power cable electrically connected to the other cabinet connector in the engraved portion is connected. The battery pack according to claim 8, wherein the embossed portion includes a first power terminal to which a power cable extending from the inside of the rack is connected,
Wherein the second power terminal further comprises a terminal hole formed on the inner surface of the conductor so that the first power terminal is electrically connected to the first power terminal when the first power terminal is inserted. The system of claim 1, wherein the energy storage system
At least one slave for detecting an abnormal state of the battery module in the rack, and a master for controlling the at least one slave,
Wherein the rack connector has a first signal line connector to which a signal line extending from the slave at a rear surface is connected,
The cabinet connector further comprises a second signal line connector to which a signal line connected to the slave of the master or the other rack is connected from the rear surface,
Wherein the first signal line connector and the second signal line connector are mated together. 2. The apparatus of claim 1,
Further comprising a partition wall which is composed of a wall surface upright on the bottom surface and insulates and divides the at least one battery module fixed at one side and the other side respectively.

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