CN218633363U - Household energy storage battery cabinet - Google Patents

Abstract

The utility model discloses a family is with energy storage battery cabinet, it includes: a cabinet body with a cabinet door; a top battery tray and a bottom battery tray; a top positive cable connector, a top negative cable connector, a bottom positive cable connector and a bottom negative cable connector; a power distribution box, comprising: the cable comprises at least two positive wiring terminals, at least two negative wiring terminals, a plurality of insulators, a positive copper bar, a positive short-circuit bar, a negative copper bar, a plurality of binding frames, a positive wire passing guard ring and a negative wire passing guard ring; at least two anode cables and at least two cathode cables; and at least two modules are integrated into an energy storage battery.

Description

Household energy storage battery cabinet

Technical Field

The utility model relates to an energy storage equipment field particularly, relates to an energy storage battery cabinet is used at family.

Background

The household energy storage battery cabinet is an energy storage device which can effectively reduce the expenditure of electricity charges for a terminal user and improve the quality of electric energy through low-price storage. Energy storage battery cabinet usually need assemble at the user scene, because the inside subassembly that needs to connect of energy storage battery cabinet is more, and current installation procedure is more complicated, walks the line also more in the cabinet, wastes time and energy when installer field installation, still appears the wiring mistake easily, consequently, needs a battery cabinet that can the modularized design to reduce the process of installer field installation, reduce the wiring fault rate.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a user carries out the integrated design with the product, through each subassembly of modularization to arrange the relevant position with the cable when dispatching from the factory, the corresponding position of battery compartment only needs to be put into with the battery to on-the-spot installer, and with cable joint plug to appointed socket, can accomplish quick and simple and easy equipment, thereby reduce on-the-spot installer's installation procedure, reduce artifical installation cost, reduce the fault rate of artifical wiring.

In order to achieve the above object, the utility model provides a family is with energy storage battery cabinet, it includes:

a cabinet body with a cabinet door;

the top battery bracket is arranged in the cabinet body and is positioned on the upper part of the middle part;

the bottom battery bracket is arranged in the cabinet body and is positioned at the bottom;

a top anode cable connector and a top cathode cable connector which are arranged in the cabinet body in parallel and are positioned at the top;

the bottom positive cable joint and the bottom negative cable joint are arranged in the cabinet body in parallel and are positioned on the side surface of the lower part of the cabinet body;

a block terminal, set up in cabinet body middle part, the block terminal includes:

the at least two positive connecting terminals and the at least two negative connecting terminals are sequentially arranged and fixed on one side surface of the distribution box body;

the insulators are fixedly arranged at the bottom of the distribution box;

the positive copper bar is fixedly arranged on two of the insulators and is opposite to the at least two positive wiring terminals;

the positive electrode short-circuit bar is fixedly arranged on the at least two positive electrode connecting terminals and is electrically connected with the positive electrode copper bar through a fuse;

the negative copper bar is fixedly arranged on the other two of the insulators and is electrically connected with the at least two negative wiring terminals;

the binding wire frames are fixedly arranged in the box body of the distribution box; and

the positive wire-passing guard ring and the negative wire-passing guard ring are arranged on the other side surface of the distribution box adjacent to the installation positive wiring terminal;

one end of each positive cable penetrates through the positive wire passing retainer and is connected to the positive copper bar through a screw, and the other end of each positive cable is connected to the top positive cable joint and the bottom positive cable joint respectively;

one end of each of the at least two negative cables penetrates through the negative wire passing retainer and is connected to the negative copper bar through a screw, and the other end of each of the at least two negative cables is connected to the top negative cable connector and the bottom negative cable connector respectively; and

and the at least two module integrated energy storage batteries are respectively placed on the top battery bracket and/or the bottom battery bracket, the positive interface of the corresponding module integrated energy storage battery is electrically connected with the top positive electrode cable connector or the bottom positive electrode cable connector, and the negative interface of the corresponding module integrated energy storage battery is electrically connected with the top negative electrode cable connector or the bottom negative electrode cable connector.

The utility model discloses an embodiment, wherein, anodal copper bar with correspond the insulator negative pole copper bar with correspond the insulator and the fuse all uses the fix with screw.

In an embodiment of the present invention, wherein the distribution box further includes an upper cover, and the upper cover is fixed by screws.

In an embodiment of the present invention, wherein the top positive cable connector, the bottom positive cable connector and the colors of the at least two positive cables and the top negative cable connector, the bottom negative cable connector and the colors of the at least two negative cables are set to two different colors respectively.

The utility model discloses an in, wherein, still set up an at least on-spot installation fixed orifices on the backplate of the cabinet body.

In an embodiment of the present invention, wherein a plurality of bridge-shaped wire binding frames are disposed on a side wall of the cabinet body.

The utility model discloses an in the embodiment, wherein, the both sides of the first half of the cabinet body and the latter half still are provided with a plurality of monocell mountings and bi-cell mountings respectively.

The utility model discloses an in embodiment, wherein, one side of the cabinet body still is provided with an anodal cabinet body and crosses line sheath and a negative pole cabinet body and cross the line sheath, and one of them anodal binding post passes through one the anodal cabinet body crosses the positive pole electric connection of line cable and external inverter of line sheath, and one of them negative pole binding post passes through one the negative pole cabinet body crosses the negative pole electric connection of line cable and external inverter of line sheath.

The utility model discloses an in, wherein, on the cabinet body with the positive pole cabinet body crosses the opposite side that the line sheath is relative still be provided with a cabinet-combining positive pole cabinet body and cross the line sheath and a cabinet negative pole cabinet body cross the line sheath.

The utility model discloses a family is with energy storage battery cabinet compares with current battery cabinet, has following advantage at least:

1) The integrated modular design makes the transportation and installation more convenient and faster;

2) The structure of each component is simple, and the whole layout is easy;

3) The circuit layout can be strictly controlled, the field installation and the wiring are convenient and not easy to make mistakes.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic view of an energy storage cabinet according to an embodiment of the present invention when a battery is not installed;

fig. 2 is a diagram of an internal structure of a distribution box without wires installed therein according to an embodiment of the present invention;

fig. 3 is a cross-sectional view of the distribution box according to an embodiment of the present invention after the wires are connected;

fig. 4 is an overall appearance view of the distribution box according to an embodiment of the present invention;

fig. 5 is a schematic view of the energy storage cabinet according to an embodiment of the present invention when two batteries are installed.

Description of reference numerals: 1-a distribution box; 2-an insulator; 3-positive copper bar; 4-a fuse; 5-positive electrode short-circuit arrangement; 6A-positive connecting terminal; 6B-a negative pole wiring terminal; 7-binding a wire frame; 8-negative electrode copper bar; 9-a positive cable; 10-a negative cable; 11-a cabinet body; 12-positive pole wire-passing guard ring; 13-negative pole wire-passing guard ring; 14-upper cover; 15-top battery carrier; 16-bottom battery tray; 17-top positive cable connector; 18-top negative cable connector; 19-bridge type wire binding frame; 20-bottom positive cable connector; 21-bottom negative cable connector; 22-installing fixing holes on site; 23-a module integrated energy storage battery; 24-single cell fixing member; 25-dual battery mount; 26-positive cabinet body wire-passing sheath; 27-negative pole cabinet body wire-passing sheath; 28-cabinet combination positive cabinet body threading sheath; 29-cabinet combination negative pole cabinet body wire-passing sheath.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without any creative effort belong to the protection scope of the present invention.

Fig. 1 is a schematic diagram of an embodiment of the present invention when a battery is not installed in an energy storage cabinet, as shown in fig. 1, this embodiment provides a user with an energy storage battery cabinet, which includes:

a cabinet body 11 with a cabinet door;

a top battery bracket 15 arranged in the cabinet body 11 and positioned at the upper part of the middle part;

a bottom battery bracket 16 disposed in the cabinet 11 and located at the bottom;

a top positive cable connector 17 and a top negative cable connector 18, which are arranged in parallel in the cabinet body 11 and located at the top, and are used for being inserted into positive and negative interfaces of the battery arranged at the upper part;

a bottom positive cable connector 20 and a bottom negative cable connector 21, which are arranged in the cabinet body 11 in parallel and positioned on the side surface of the lower part of the cabinet body, and are used for being inserted into positive and negative interfaces of a battery arranged on the lower part;

a block terminal 1, sets up in cabinet body middle part, and fig. 2 is the utility model discloses an embodiment does not install the inside structure chart of block terminal of walking the line, and fig. 3 is the utility model discloses an embodiment in-connection of block terminal is walked the cross-sectional view behind the line, as shown in fig. 2 and fig. 3, wherein, block terminal 1 includes:

at least two positive connecting terminals 6A and at least two negative connecting terminals 6B are sequentially arranged and fixed on one side surface of the box body of the distribution box 1;

the insulators 2 are fixedly arranged at the bottom of the distribution box 1; the plurality of insulators 2 are all made of insulating materials.

The positive copper bar 3 is fixedly arranged on two of the insulators 2 and is opposite to the at least two positive wiring terminals 6A, and the insulators 2 support the positive copper bar 3 and prevent the positive copper bar 3 from being connected with the distribution box 1 to cause short circuit;

the positive electrode short-circuit bar 5 is fixedly arranged on at least two positive electrode wiring terminals 6A and is electrically connected with the positive electrode copper bar 3 through a fuse 4; the positive electrode shorting bar 5 can short-circuit at least two positive electrode connecting terminals 6A, and when the current passing through the fuse 4 exceeds the rated current of the fuse 4, the heat generated by the fuse 4 melts the melt, so that the positive electrode circuit is disconnected.

The negative copper bar 8 is fixedly arranged on the other two of the insulators 2 and is electrically connected with the at least two negative wiring terminals 6B; the insulators 2 can play a role in supporting and insulating the negative copper bar 8.

The wire binding frames 7 are fixedly arranged in the box body of the distribution box 1 and used for binding wires in the distribution box; and

a positive wire-passing guard ring 12 and a negative wire-passing guard ring 13 are arranged on the other side surface of the distribution box 1 adjacent to the installation positive wiring terminal 6A and used for penetrating cables;

in this embodiment, the positive copper bar 3 and the corresponding insulator 2, the negative copper bar 8 and the corresponding insulator 2, and the fuse 4 are fixed by screws.

Fig. 4 is an overall appearance view of the distribution box according to an embodiment of the present invention, as shown in fig. 4, in this embodiment, wherein the distribution box 1 further includes an upper cover 14, and the upper cover 14 is fixed by screws.

One end of each of at least two positive cables 9 penetrates through the positive wire passing retainer 12 and is connected to the positive copper bar 3 through a screw, and the other end of each of the at least two positive cables 9 is connected to the top positive cable connector 17 and the bottom positive cable connector 20 respectively;

at least two negative cables 10, one end of each of which passes through the negative wire-passing retainer 13 and is connected to the negative copper bar 8 through a screw, and the other end of each of which is connected to the top negative cable connector 18 and the bottom negative cable connector 21; and

at least two module integrated energy storage batteries 23 are respectively arranged on the top battery bracket 15 and/or the bottom battery bracket 16, and the anode interface of the corresponding module integrated energy storage battery 23 is electrically connected with the top anode cable connector 17 or the bottom anode cable connector 20, and the cathode interface of the corresponding module integrated energy storage battery 23 is electrically connected with the top cathode cable connector 18 or the bottom cathode cable connector 21.

In this embodiment, the colors of the top positive cable connector 17, the bottom positive cable connector 20, and the at least two positive cables 9 and the colors of the top negative cable connector 18, the bottom negative cable connector 21, and the at least two negative cables 10 are set to two different colors respectively, so as to distinguish the positive and negative electrodes, for example, the colors of the top positive cable connector 17, the bottom positive cable connector 20, and the at least two positive cables 9 may be orange, and the colors of the top negative cable connector 18, the bottom negative cable connector 21, and the at least two negative cables 10 may be black.

In this embodiment, at least one field mounting fixing hole 22 is further disposed on the back plate of the cabinet 11, so that the cabinet 11 and the wall can be fixed by screws, and the energy storage battery cabinet is prevented from toppling over due to external force.

In the present embodiment, a plurality of bridge-type binding brackets 19 are disposed on one side wall (the side wall for routing) of the cabinet 11, and are used for binding and fixing at least two positive cables 9 and at least two negative cables 10, respectively.

In the present embodiment, a plurality of single battery fixing members 24 and dual battery fixing members 25 are further respectively disposed on both sides of the upper half portion and the lower half portion of the cabinet 11, and when one battery is placed corresponding to the battery tray, the single battery fixing member 24 fixes the battery, and when two batteries are placed corresponding to the battery tray, the second battery fixes the battery by the dual battery fixing member 25.

In this embodiment, a positive cabinet wire-passing sheath 26 and a negative cabinet wire-passing sheath 27 are further disposed on one side of the cabinet 11, and one of the positive wire terminals 6A is electrically connected to the positive electrode of the external inverter through a cable passing through the positive cabinet wire-passing sheath 26, and one of the negative wire terminals 6B is electrically connected to the negative electrode of the external inverter through a cable passing through the negative cabinet wire-passing sheath 27.

In this embodiment, wherein, the opposite side opposite to the positive cabinet body threading sheath 26 on the cabinet body 11 is further provided with a cabinet combination positive cabinet body threading sheath 28 and a cabinet combination negative cabinet body threading sheath 29, and when necessary, one of the positive wiring terminals 6A can be connected with the positive terminal of another energy storage cabinet through a cable passing through the cabinet combination positive cabinet body threading sheath 28, one of the negative wiring terminals 6B is connected with the negative terminal of another energy storage cabinet through a cable passing through the cabinet combination negative cabinet body threading sheath 29, thereby realizing cabinet combination.

According to the structure, the installation can be realized through the following installation processes when the installation is carried out on a specific site:

firstly, at least 4 positive and negative electrode connecting terminals 6A and 6B are arranged at corresponding positions of a distribution box 1 according to the positions of a figure 2, a plurality of insulators 2 are arranged at the bottom of the distribution box 1 according to the positions of the figure 2, and the insulators are insulators so as to support copper bars to prevent the positive electrode copper bars 3 from being connected with the distribution box 1 and causing short circuit. And then the positive copper bar 3 is fixed on the corresponding insulator 2 by using screws, the positive short-circuit bar 5 is installed at the position of the positive wiring terminal 6A, the positive short-circuit bar 5 plays a role in short-circuit the two positive wiring terminals 6A, the fuse 4 is fixed between the positive copper bar 3 and the positive short-circuit bar 5 by using screws, and when the current of the fuse 4 exceeds the rated current of the fuse 4, the fuse body is melted by the heat generated by the fuse body, so that the circuit is disconnected. The negative copper bar 8 is installed in negative binding post 6B side equally, and is fixed to corresponding insulator 2 below the negative copper bar 8 to play the supporting role.

Then, the assembled distribution box 1 is installed at a preset position in the cabinet body 11, as shown in fig. 3, the positive cable (orange) 9 and the negative cable (black) 10 are respectively connected to the positive copper bar 3 and the negative copper bar 8 through screws, and the positive cable (orange) 9 and the negative cable (black) 10 are respectively tied to the wire tying frame 7 through rolling bands. 9 positive pole cable (orange) passes through 12 positive poles and crosses the line protective shroud, 10 negative pole cable (black) passes 13 negative poles and crosses the line protective shroud. Two positive pole cables (orange) 9 can be divided into two paths, one path is upward, the other path is downward, and two negative pole cables (black) 10 are the same in principle, and after the cables are completely installed, the upper cover 14 is installed by using screws.

In the installation process of the embodiment, two modules of the energy storage battery 23 are taken as an example, and are respectively installed up and down. The corresponding cables are connected with a top positive cable joint (orange) 17 and a top negative cable joint (black) 18 respectively, and are bound to the top of the cabinet body 11 upwards through a bridge-shaped binding frame 19, and the corresponding cables are connected with a bottom positive cable joint (orange) 20 and a bottom negative cable joint (black) 21 respectively and are bound to a preset position downwards through the bridge-shaped binding frame 19.

When the energy storage battery cabinet arrives at an installation site, the cabinet body 11 is fixed with the wall through the site installation fixing holes 22 by using screws, so that the energy storage battery cabinet is prevented from toppling over due to external force. The two module-integrated energy storage batteries 23 are pushed into the top battery holder 15 and the bottom battery holder 16, respectively, and are fixed by the cell fixing members 24. If the number of the mounted batteries of the upper or lower layer is two, the second battery is fixed using the dual battery fixing member 25.

A top anode cable connector (orange) 17 and a top cathode cable connector (black) 18 are respectively inserted into the corresponding interfaces of the module integrated energy storage battery 23 placed in the upper half part, the interfaces can also distinguish the anode and the cathode by colors, and when the cable connectors make a 'click', the connection is normal. A bottom positive cable connector (orange) 20 and a bottom negative cable connector (black) 21 are respectively inserted into the corresponding interfaces (color differentiation) of the module integrated energy storage battery 23 placed at the bottom.

Finally, the external inverter positive and negative cables are connected to the positive wiring terminal 6A and the negative wiring terminal 6B through the positive cabinet body wire passing sheath 26 and the negative cabinet body wire passing sheath 27, respectively, so that the installation of the battery cabinet is completed.

Because the design of this battery cabinet is that 4 module integration energy storage batteries 23 are installed to a battery cabinet at most, if user's demand exceeds 4 batteries, can expand the same battery cabinet in battery cabinet one side (for example right side), the assembly sequence of battery cabinet is the same as the aforesaid, therefore no longer describe. The difference lies in that positive and negative cables of the battery cabinets to be connected in parallel are connected to corresponding wiring terminals 6A and 6B of the distribution box through a combination positive cabinet body wire-passing sheath 28 and a combination negative cabinet body wire-passing sheath 29 of the battery cabinet on the left side, and the connection can be called as combination, so that the parallel connection of more battery cabinets can be realized to meet the requirement of larger energy storage.

The utility model discloses a family is with energy storage battery cabinet compares with current battery cabinet, has following advantage at least:

1) The integrated modular design makes the transportation and installation more convenient and faster;

2) The structure of each component is simple, and the overall layout is easy;

3) The circuit layout can be strictly controlled, the field installation and the wiring are convenient and not easy to make mistakes.

Those of ordinary skill in the art will understand that: the figures are schematic representations of one embodiment, and the blocks or processes in the figures are not necessarily required to practice the present invention.

Those of ordinary skill in the art will understand that: modules in the devices in the embodiments may be distributed in the devices in the embodiments according to the description of the embodiments, or may be located in one or more devices different from the embodiments with corresponding changes. The modules of the above embodiments may be combined into one module, or further split into multiple sub-modules.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the embodiments of the present invention.

Claims (9)

1. A household energy storage battery cabinet, comprising:

a cabinet body with a cabinet door;

the top battery bracket is arranged in the cabinet body and is positioned on the upper part of the middle part;

the bottom battery bracket is arranged in the cabinet body and is positioned at the bottom;

a top anode cable connector and a top cathode cable connector which are arranged in the cabinet body in parallel and are positioned at the top;

the bottom positive cable joint and the bottom negative cable joint are arranged in the cabinet body in parallel and are positioned on the side surface of the lower part of the cabinet body;

a block terminal, set up in cabinet body middle part, the block terminal includes:

the at least two positive connecting terminals and the at least two negative connecting terminals are sequentially arranged and fixed on one side face of the distribution box body;

the insulators are fixedly arranged at the bottom of the distribution box;

the positive copper bar is fixedly arranged on two of the insulators and is opposite to the at least two positive wiring terminals;

the positive electrode short-circuit bar is fixedly arranged on the at least two positive electrode connecting terminals and is electrically connected with the positive electrode copper bar through a fuse;

the negative copper bar is fixedly arranged on the other two of the insulators and is electrically connected with the at least two negative wiring terminals;

the binding wire frames are fixedly arranged in the box body of the distribution box; and

the positive wire-passing retainer and the negative wire-passing retainer are arranged on the other side surface of the distribution box adjacent to the installation positive wiring terminal;

one end of each positive cable penetrates through the positive wire passing retainer and is connected to the positive copper bar through a screw, and the other end of each positive cable is connected to the top positive cable joint and the bottom positive cable joint respectively;

one end of each of the at least two negative cables penetrates through the negative wire passing retainer and is connected to the negative copper bar through a screw, and the other end of each of the at least two negative cables is connected to the top negative cable connector and the bottom negative cable connector respectively; and

and the at least two module integrated energy storage batteries are respectively placed on the top battery bracket and/or the bottom battery bracket, the positive interface of the corresponding module integrated energy storage battery is electrically connected with the top positive electrode cable connector or the bottom positive electrode cable connector, and the negative interface of the corresponding module integrated energy storage battery is electrically connected with the top negative electrode cable connector or the bottom negative electrode cable connector.

2. The household energy storage battery cabinet as claimed in claim 1, wherein the positive copper bar and the corresponding insulator, the negative copper bar and the corresponding insulator, and the fuse are fixed by screws.

3. The household energy storage battery cabinet as claimed in claim 1, wherein the distribution box further comprises an upper cover, and the upper cover is fixed by screws.

4. The household energy storage battery cabinet of claim 1, wherein the colors of the top positive cable tab, the bottom positive cable tab and the at least two positive cables and the colors of the top negative cable tab, the bottom negative cable tab and the at least two negative cables are set to two different colors respectively.

5. The household energy storage battery cabinet as claimed in claim 1, wherein the back plate of the cabinet body is further provided with at least one field mounting fixing hole.

6. The household energy storage battery cabinet as claimed in claim 1, wherein a plurality of bridge-type wire binding frames are arranged on one side wall of the cabinet body.

7. The household energy storage battery cabinet as claimed in claim 1, wherein a plurality of single battery fixing pieces and double battery fixing pieces are respectively arranged on two sides of the upper half part and the lower half part of the cabinet body.

8. The household energy storage battery cabinet as claimed in claim 1, wherein a positive cabinet body wire-passing sheath and a negative cabinet body wire-passing sheath are further disposed on one side of the cabinet body, and one positive terminal is electrically connected to the positive electrode of the external inverter through a cable passing through the positive cabinet body wire-passing sheath, and one negative terminal is electrically connected to the negative electrode of the external inverter through a cable passing through the negative cabinet body wire-passing sheath.

9. The household energy storage battery cabinet as claimed in claim 8, wherein a combined positive cabinet body line-passing sheath and a combined negative cabinet body line-passing sheath are further disposed on the other side of the cabinet body opposite to the positive cabinet body line-passing sheath.

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