CN217035825U - Energy storage container and energy storage equipment - Google Patents

Abstract

The utility model discloses an energy storage container and energy storage equipment. The energy storage container comprises a box body, a battery bin, a heat exchange bin, an equipment bin and a top cover. The battery compartment is located the box, is provided with at least one group of battery frame in the battery compartment, and every group battery frame has two at least mounted position to be used for installing two at least battery unit. The heat exchange bin is positioned in the box body and above the battery bin. The equipment bin is positioned in the box body and above the heat exchange bin. The top cover is movably coupled to the top of the cabinet between an open position and a closed position to open or close the equipment compartment. According to the energy storage container, the number of the battery units can be adjusted according to needs, so that the capacity of the energy storage container is variable, the heat exchange bin can reduce the heat exchange between the battery bin and the equipment bin, the stability of a system is facilitated, various equipment can be installed and maintained through the top cover, and the use experience is improved.

Description

Energy storage container and energy storage equipment

Technical Field

The utility model relates to the technical field of energy, in particular to an energy storage container and energy storage equipment.

Background

The effective utilization, storage and transfer of energy are important subjects in the technical field of energy storage in China at present, and the energy storage container is an effective energy storage device and is widely used in the field. At present, energy storage equipment, cooling equipment, conversion equipment and the like are mostly integrated in a standard 20-foot or 40-foot container in the market, so that the standardized transportation and integrated management of the equipment are facilitated.

However, once the above devices are integrated, the output power is fixed and cannot be adjusted at any time according to the use condition.

There is therefore a need for an energy storage container and energy storage apparatus that at least partially addresses the above problems.

SUMMERY OF THE UTILITY MODEL

A series of concepts in a simplified form are introduced in the summary section, which will be described in further detail in the detailed description section. The summary of the utility model is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

To at least partially solve the above problems, a first aspect of the present invention provides an energy storage container comprising:

a box body;

the battery bin is positioned in the box body, at least one group of battery racks is arranged in the battery bin, and each group of battery racks is provided with at least two mounting positions for mounting at least two battery units;

the heat exchange bin is positioned in the box body and above the battery bin;

the equipment bin is positioned in the box body and above the heat exchange bin; and

a top cover movably coupled to a top of the cabinet between an open position and a closed position to open or close the equipment compartment.

According to the energy storage container disclosed by the utility model, the number of the battery units can be adjusted as required, so that the capacity of the energy storage container is variable, the heat exchange bin can reduce the heat exchange between the battery bin and the equipment bin, the stability of a system is facilitated, various equipment can be mounted and maintained through the top cover, and the use experience is improved.

Further, the box includes:

the chassis comprises two longitudinal bottom beams arranged longitudinally and two transverse bottom beams;

the top frame comprises two top longitudinal beams arranged along the longitudinal direction, and the top cover is arranged on the top frame and is positioned between the two top longitudinal beams;

the corner columns are vertically arranged and connected among the end parts of the bottom longitudinal beam, the bottom end beam and the top longitudinal beam; and

the first middle frame is positioned between the bottom frame and the top frame and connected with the corner posts, and a space between the first middle frame and the bottom frame forms the battery bin;

the second middle frame is located between the first middle frame and the top frame and connected with the corner post, the space between the second middle frame and the top frame forms the equipment bin, and the space between the first middle frame and the second middle frame forms the heat exchange bin.

Further, the first intermediate frame includes:

the two first longitudinal beams are longitudinally arranged, the end parts of the first longitudinal beams are connected with the corner posts, and the first longitudinal beams are positioned above the bottom longitudinal beams;

the first cross beams are transversely arranged, the end parts of the first cross beams are connected with the corner posts, and the first cross beams are positioned above the bottom end beams.

Further, a set of the battery racks includes two mounting racks, the mounting racks including:

the two mounting vertical beams are vertically arranged and connected between the first longitudinal beam and the bottom longitudinal beam;

the mounting cross beams are transversely arranged and connected between the two mounting vertical beams, and the at least two mounting vertical beams are vertically arranged at intervals;

wherein two mounting beams of a group of the battery racks located at the same height are configured as one mounting position. According to the arrangement, the mountable number of the battery units can be increased, and the number of the battery units can be adjusted at any time.

Further, the second intermediate frame includes:

the two second longitudinal beams are longitudinally arranged, the end parts of the second longitudinal beams are connected with the corner posts, and the second longitudinal beams are positioned above the first longitudinal beams;

the second cross beams are arranged along the transverse direction, the end parts of the second cross beams are connected with the corner posts, and the second cross beams are located above the first cross beams.

Further, the air conditioner is characterized in that,

the top frame further comprises a top cross beam which is arranged transversely and connected between the two top longitudinal beams;

the box body further comprises a partition plate, the partition plate is arranged in the equipment bin, and the partition plate is connected to the bottom of the top cross beam, so that the equipment bin is divided into two bin bodies.

Further, the top cap includes two opening and closing doors, the opening and closing doors include:

one end of the top plate is arranged close to the top cross beam and is pivotally connected between the two top longitudinal beams, or one end of the top plate is pivotally connected with the top cross beam;

the vertical plate is arranged at the end part, far away from the top cross beam, of the top plate, and extends downwards to the first middle frame;

wherein the risers of each of the two opening and closing doors are remote from each other. According to the arrangement, the top cover is more convenient to open due to the open-wing design, the installation and maintenance of equipment are facilitated, and the use experience is further improved.

Further, the air conditioner is characterized in that,

the vertical plate is provided with a vent hole; and/or

The first middle frame further comprises a first covering plate, the first covering plate is connected between the first cross beam and the first longitudinal beam, and the first covering plate is provided with vent holes.

Further, the box body also comprises at least one box door,

the box door is arranged between the bottom end beam and the first cross beam, the box body further comprises a door frame vertical beam, and the door frame vertical beam is connected between the first cross beam and the bottom end beam and/or

The chamber door set up in end longeron with between the first longeron.

A second aspect of the utility model provides an energy storage apparatus comprising at least two energy storage containers according to the first aspect, at least two of the energy storage containers being connected to each other.

Further, the energy storage container comprises a connecting frame, wherein the connecting frame is connected between the two energy storage containers or one end of any energy storage container.

Further, the energy storage device is of a size of 20 feet or 40 feet international standard dry goods container.

The energy storage device provided by the utility model can achieve the technical effects similar to those of an energy storage container, and can achieve the technical effects of convenience in transportation, rapidness in combination, convenience in power adjustment and the like.

Drawings

The following drawings of the present invention are included to provide a further understanding of the utility model. The drawings illustrate embodiments of the utility model and, together with the description, serve to explain the principles of the utility model.

In the drawings:

fig. 1 is a schematic structural view of an energy storage container according to a preferred embodiment of the present invention;

fig. 2 is a schematic structural diagram of an energy storage device according to a preferred embodiment of the present invention.

Description of reference numerals:

100: energy storage container 101: the battery compartment 102: heat exchange bin

103: the equipment bin 110: a box body 111: corner post

112: the corner fitting 113: partition plate 114: box door

115: door frame vertical beam 116: the top cover 117: opening and closing door

118: top plate 119: a vertical plate 300: battery unit

121: threshold 130: the chassis 131: bottom end beam

132: bottom longitudinal beam 140: the top frame 141: roof longitudinal beam

142: the top cross member 150: first intermediate frame 151: first longitudinal beam

152: first cross member 153: first vertical beam 154: first shroud plate

160: second intermediate frame 161: second longitudinal beam 162: second beam

163: second vertical beam 164: second shroud plate 170: battery rack

171: mounting bracket 172: mounting the vertical beam 173: mounting cross beam

200: the energy storage device 210: connecting frame

Detailed Description

In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without one or more of these specific details. In other instances, well-known features have not been described in order to avoid obscuring the utility model.

In the following description, a detailed description will be given in order to thoroughly understand the present invention. It is understood that these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of these exemplary embodiments to those skilled in the art. It is apparent that the implementation of the embodiments of the utility model is not limited to the specific details familiar to those skilled in the art. The following detailed description of the preferred embodiments of the utility model, however, the utility model can be practiced otherwise than as specifically described.

It should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the utility model. As used herein, the singular is intended to include the plural unless the context clearly indicates otherwise. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

Ordinal words such as "first" and "second" are referred to herein merely as labels, and do not have any other meaning, such as a particular order, etc. Also, for example, the term "first component" does not itself imply the presence of "second component", and the term "second component" does not itself imply the presence of "first component". It is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "inner", "outer", and the like are used herein for purposes of illustration only and are not limiting.

An exemplary embodiment according to the present invention will now be described in more detail with reference to fig. 1 and 2.

Reference is first made to fig. 1. In one aspect, the utility model provides an energy storage container 100, which includes a container body 110, a battery compartment 101, a heat exchange compartment 102, an equipment compartment 103, and a top cover 116.

The battery compartment 101 is used for mounting the battery unit 300. The heat transfer bin 102 is used to slow down the transfer of heat. The equipment bin 103 is used for installing equipment such as a cooling system, a power system, a control system and a conversion system.

The battery bin 101, the heat exchange bin 102 and the equipment bin 103 are all located in the box body 110. And heat exchange chamber 102 is located between battery chamber 101 and equipment chamber 103. Or, the heat exchange bin 102 is located above the battery bin 101, and the equipment bin 103 is located above the heat exchange bin 102. Preferably, the heat exchange bin 102 is connected with both the battery bin 101 and the equipment bin 103, that is, the heat exchange bin 102 is connected between the battery bin 101 and the equipment bin 103.

At least one set of battery racks 170 is disposed in the battery compartment 101, and each set of battery racks 170 has at least two mounting positions for mounting at least two battery units 300. The top cover 116 is movably coupled to the top of the cabinet 110 between an open position and a closed position to open or close the equipment bin 103.

According to the energy storage container 100 disclosed by the utility model, the number of the battery units 300 can be adjusted as required, so that the power of the energy storage container 100 is variable, the heat exchange bin 102 can reduce the heat exchange between the battery bin 101 and the equipment bin 103, the stability of a system is facilitated, and the installation and maintenance of various equipment can be performed through the top cover 116, so that the use experience is improved.

In particular, continued reference is made to fig. 1 and 2. The cabinet 110 includes a bottom frame 130, a top frame 140, a first intermediate frame 150, a second intermediate frame 160, and corner posts 111 supporting the above components. The bottom frame 130 and the top frame 140 may have a structure similar to a general container, thereby increasing the load of the box body 110, and having a larger load capacity and structural stability than a general electrical cabinet. For example, the bottom frame 130 includes two bottom longitudinal beams 132 disposed in the longitudinal direction and two bottom end beams 131 disposed in the transverse direction, thereby constituting a rectangular bottom frame 130. It will be readily appreciated that the floor may be laid on the base frame 130.

The four corner posts 111 are respectively disposed at four corners of the bottom frame 130, and are connected to the bottom frame 130 via the corner members 112. The top ends of the four corner posts 111 are connected to the top frame 140. Specifically, the top frame 140 has two top longitudinal beams 141 arranged in the longitudinal direction. The corner post 111 is preferably provided with a corner fitting 112 at the end, i.e. the corner post 111 and the bottom end beam 131, the corner post 111 and the bottom longitudinal beam 132, and the corner post 111 and the top longitudinal beam 141 can be connected through the corner fitting 112. Thereby, a substantially rectangular or square frame of the tank 110 of the energy storage container 100 is formed.

A first intermediate frame 150 is located between the bottom frame 130 and the top frame 140, and includes two longitudinally disposed first longitudinal beams 151 and two transversely disposed first transverse beams 152, thereby constituting a rectangular first intermediate frame 150. And four corner posts 111 are respectively connected with four corners of the first middle frame 150, and preferably, corner pieces 112 are also arranged at the connection positions. The first longitudinal beam 151 is located above the bottom longitudinal beam 132, and the first cross beam 152 is located above the bottom end beam 131. And, the space between the first intermediate frame 150 and the bottom frame 130 forms the above-mentioned battery compartment 101. It will be readily appreciated that the first intermediate frame 150 is also provided with a first skin panel 154 which is connected between the two first longitudinal beams 151 and the two first transverse beams 152. The first shroud 154 preferably defines ventilation and/or wire holes.

The battery rack 170 is disposed in the battery chamber 101. In the illustrated embodiment, two sets of battery racks 170 are disposed within the battery compartment 101. In embodiments not shown, three, four, or more sets of battery holders 170 may also be provided. And the plurality of sets of battery holders 170 are preferably arranged in a longitudinal direction.

The battery rack 170 includes two mounting racks 171, or an even number of mounting racks 171 are disposed in the battery compartment 101. The mounting bracket 171 includes two mounting vertical beams 172 and at least two mounting cross beams 173. Wherein, the vertical installation beams 172 are vertically arranged and connected between the first longitudinal beam 151 and the bottom longitudinal beam 132, and the horizontal installation beams 173 are transversely arranged and connected between the two vertical installation beams 172. Also, at least two mounting mullions 172 are vertically spaced. Thus, the mounting bracket 171 is configured to resemble a ladder.

Two mounting beams 173 of a set of battery racks 170 at the same height are configured as one mounting position. When the battery unit 300 is mounted, the battery unit 300 can be mounted to or withdrawn from the mounting position in a manner of pushing and pulling the drawer. According to the above arrangement, the mountable number of the battery cells 300 can be increased, and it is advantageous to adjust the number of the battery cells 300 at any time.

The second intermediate frame 160 is located between the first intermediate frame 150 and the top frame 140, and includes two second longitudinal beams 161 arranged in a longitudinal direction and two second transverse beams 162 arranged in a transverse direction, thereby constituting a rectangular second intermediate frame 160. And the four corner posts 111 are respectively connected with the four corners of the second intermediate frame 160, it is easy to understand that the corner pieces 112 can also be arranged at the connection positions. The second longitudinal beam 161 is located above the first longitudinal beam 151, and the second transverse beam 162 is located above the first transverse beam 152. The space between the second intermediate frame 160 and the upper frame 140 forms the equipment compartment 103, and the space between the first intermediate frame 150 and the second intermediate frame 160 forms the heat exchange compartment 102. It will be readily appreciated that the second intermediate frame 160 is also provided with a second skin 164 which is connected between the second cross member 162 and the second longitudinal member 161. Preferably, the second cover plate 164 is provided with a wire hole so that the battery unit 300 in the battery compartment 101 can be electrically connected to various devices in the equipment compartment.

In order to improve the structural strength, it is preferable that a first vertical beam 153 is provided between the first longitudinal beam 151 and the second longitudinal beam 161, and a second vertical beam 163 is provided between the second longitudinal beam 161 and the top longitudinal beam 141.

Continuing with reference to fig. 1 and 2. The top frame 140 also has a top cross member 142 disposed in the lateral direction and connected between two top longitudinal members 141. Preferably, it is in the same plane as the second vertical beam 163. The divider plate 113 is connected between the top cross beam 142 and the second vertical beam 163. Thereby, the partition plate 113 divides the equipment compartment into two compartment bodies in the equipment compartment.

In order to facilitate the independent opening and closing of the two cartridges, the top cover 116 includes two opening and closing doors 117. The opening and closing door 117 includes a top plate 118 and a riser 119. Wherein one end of the top plate 118 is pivotally connected between two top longitudinal beams 141 at a top cross beam 142. Alternatively, one end of the top plate 118 may be pivotally connected directly to the top cross member 142.

Risers 119 are disposed at the end of the top plate 118 remote from the top cross member 142 and extend downwardly to the first intermediate shelf 150. Thus, the opening/closing door 117 is substantially L-shaped. Also, the risers 119 of the two opening and closing doors 117 are distant from each other. According to the arrangement, the wing-opening design enables the door to be opened more conveniently, installation and maintenance of equipment are facilitated, and use experience is further improved. In embodiments that are not shown, the opening and closing door can also be configured as a single-opening door or as a split-opening door.

Preferably, the riser 119 may also be provided with ventilation holes. For example, the risers 119 may be configured as a grid, honeycomb, mesh, or the like to facilitate heat dissipation, cooling, and increase the efficiency of the device.

Referring now to fig. 2, the container body 110 further includes at least one door 114 disposed on a side of the energy storage container 100. Preferably, it is disposed between the bottom end beam 131 and the first cross beam 152. Alternatively, the door 114 may also be disposed between the bottom longitudinal beam 132 and the first longitudinal beam 151. The door 114 may be a single door or a double door. Illustratively, when the door 114 is a double door, a vertical door frame beam 115 is preferably disposed between the first cross member 152 and the bottom end beam 131, and two ends of the vertical door frame beam 115 are movably connected to the bottom end beam 131 and the first longitudinal beam 151.

In addition, a door opening device (not shown), such as a hydraulic device or an air spring, may be provided at both the opening/closing door 117 and the door 114 of the top plate 118. The bottom of the door 114 is also preferably provided with a threshold 121 to enhance the ability to prevent ingress of external liquids. For example, as shown in fig. 1, when the door 114 is disposed between the bottom end beam 131 and the first cross beam 152, the threshold 121 is connected to the bottom end beam 131 and disposed in the lateral direction.

Please continue with fig. 2. The second aspect of the present invention also provides an energy storage device 200. It comprises at least two energy storage containers 100, at least two energy storage containers 100 being connected to each other. Alternatively, the energy storage device 200 is a modular energy storage device. A plurality of energy storage containers 100 can be freely spliced as modules, and the power and the size can be adjusted at will. And, a plurality of energy storage containers 100 can be combined into an energy storage device 200 of an international standard container size for transportation. That is, the length of the energy storage device 200 preferably conforms to the length of an international standard container. For example, the length of the energy storage device 200 is the same as the length of a 20 foot standard container or the length of a 40 foot standard container. In other words, the energy storage device 200 itself may be approximately 20 or 40 dry goods containers that meet international standards for transportation.

Preferably, the energy storage device 200 further comprises a connection frame 210 connected between two energy storage containers 100 or at an end of either energy storage container 100. Illustratively, two energy storage containers 100 shown in fig. 2 are connected via a connecting frame 210, and the length of the energy storage device 200 is equivalent to the length of a 20 foot or 40 foot iso container. Specifically, corner pieces 112 are provided at the top corners of the connection frame 210. When the energy storage container 100 and the connecting frame 210 are butted, the corner fittings 112 of the two are butted, and the two are fixed together by using a corner fitting locking tool or a corner fitting 112 locking device.

In an embodiment not shown, when a plurality of energy storage containers 100 are arranged in series, the connection frame 210 may also be arranged at the end of the energy storage device 200 so as not to be less than a standard size portion.

According to the energy storage device 200 disclosed by the utility model, the technical effects similar to those of the energy storage container 100 can be achieved, and the technical effects of convenience in transportation, rapidness in combination, convenience in power adjustment and the like can be achieved.

Unless defined otherwise, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. Features described herein in one embodiment may be applied to another embodiment, either alone or in combination with other features, unless the feature is not applicable or otherwise stated in the other embodiment.

The present invention has been illustrated by the above embodiments, but it should be understood that the above embodiments are for illustrative and descriptive purposes only and are not intended to limit the utility model to the scope of the described embodiments. Furthermore, it will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that many variations and modifications may be made in accordance with the teachings of the present invention, which variations and modifications are within the scope of the present invention as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (12)

1. An energy storage container, comprising:

a box body;

the battery bin is positioned in the box body, at least one group of battery racks is arranged in the battery bin, and each group of battery racks is provided with at least two mounting positions for mounting at least two battery units;

the heat exchange bin is positioned in the box body and above the battery bin;

the equipment bin is positioned in the box body and above the heat exchange bin; and

a top cover movably coupled to a top of the cabinet between an open position and a closed position to open or close the equipment compartment.

2. The energy storage container of claim 1, wherein the enclosure comprises:

the bottom frame comprises two bottom longitudinal beams arranged along the longitudinal direction and two bottom end beams arranged along the transverse direction;

the top frame comprises two top longitudinal beams arranged longitudinally, and the top cover is arranged on the top frame and is positioned between the two top longitudinal beams;

the corner columns are vertically arranged and connected among the end parts of the bottom longitudinal beam, the bottom end beam and the top longitudinal beam; and

the first middle frame is positioned between the bottom frame and the top frame and connected with the corner posts, and a space between the first middle frame and the bottom frame forms the battery compartment;

the second intermediate frame is positioned between the first intermediate frame and the top frame, the second intermediate frame is connected with the corner post, the space between the second intermediate frame and the top frame forms the equipment bin, and the space between the first intermediate frame and the second intermediate frame forms the heat exchange bin.

3. The energy storage container of claim 2, wherein the first intermediate shelf comprises:

the two first longitudinal beams are longitudinally arranged, the end parts of the first longitudinal beams are connected with the corner posts, and the first longitudinal beams are positioned above the bottom longitudinal beams;

the first cross beams are transversely arranged, the end parts of the first cross beams are connected with the corner posts, and the first cross beams are positioned above the bottom end beams.

4. The energy storage container of claim 3, wherein the set of battery racks comprises two mounting racks, the mounting racks comprising:

the two mounting vertical beams are vertically arranged and connected between the first longitudinal beam and the bottom longitudinal beam;

the mounting cross beams are transversely arranged and connected between the two mounting vertical beams, and the at least two mounting vertical beams are vertically arranged at intervals;

wherein two mounting beams of a group of the battery racks located at the same height are configured as one mounting position.

5. The energy storage container of claim 3, wherein the second intermediate shelf comprises:

the two second longitudinal beams are longitudinally arranged, the end parts of the second longitudinal beams are connected with the corner posts, and the second longitudinal beams are positioned above the first longitudinal beams;

the second cross beams are arranged along the transverse direction, the end parts of the second cross beams are connected with the corner posts, and the second cross beams are located above the first cross beams.

6. Energy storage container according to claim 5,

the top frame further comprises a top cross beam which is arranged transversely and connected between the two top longitudinal beams;

the box body further comprises a partition plate, the partition plate is arranged in the equipment bin, and the partition plate is connected to the bottom of the top cross beam, so that the equipment bin is divided into two bin bodies.

7. The energy storage container of claim 6, wherein the top cover comprises two openable doors, the openable doors comprising:

one end of the top plate is arranged close to the top cross beam and is pivotally connected between the two top longitudinal beams, or one end of the top plate is pivotally connected with the top cross beam;

the vertical plate is arranged at the end part, far away from the top cross beam, of the top plate, and extends downwards to the first middle frame;

wherein the risers of each of the two opening and closing doors are distant from each other.

8. Energy storage container according to claim 7,

the vertical plate is provided with a vent hole; and/or

The first middle frame further comprises a first shroud plate, the first shroud plate is connected between the first cross beam and the first longitudinal beam, and vent holes are formed in the first shroud plate.

9. The energy storage container of claim 3, wherein the enclosure further comprises at least one door,

the box door is arranged between the bottom end beam and the first cross beam, the box body further comprises a door frame vertical beam, the door frame vertical beam is connected between the first cross beam and the bottom end beam, and/or the box door is arranged between the bottom longitudinal beam and the first longitudinal beam.

10. Energy storage device, characterized in that it comprises at least two energy storage containers according to any of claims 1-9, at least two of said energy storage containers being connected to each other.

11. The energy storage device of claim 10, further comprising a connecting frame connected between two of the energy storage containers or at one end of either of the energy storage containers.

12. The energy storage device of claim 10 or 11, wherein the size of the energy storage device is the size of a 20 foot or 40 foot international standard dry goods container.

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