DE102017211534A1 - Stationary energy storage - Google Patents

Abstract

The invention relates to a stationary energy store comprising a plurality of battery units (2) which is arranged in a housing (3) of the stationary energy store (1) which is sealed off from an environment (4), wherein the plurality of battery units (2) are arranged in a longitudinal direction (FIG. 5) of the housing (3) is arranged side by side, and in the housing (3) further in the longitudinal direction (5) adjacent to the battery units (2), a cooling element (6) is arranged, wherein the plurality of battery units (2) and a Housing wall (7) of the housing (3) of the stationary energy storage (1) to a flow with tempering fluid formed first flow space (8) limit and on a first flow space (8) opposite side of the plurality of battery units (2) to a flow formed with tempering fluid second flow space (9) is formed, wherein the housing (3) further comprises a flow guide (10) eist, which is arranged to extend in the direction of the longitudinal direction (5) of the housing (3).

Description

State of the art

The invention is based on a stationary energy store according to the preamble of the independent claim.

Stationary energy storage devices are used, for example, by industrial companies as well as energy suppliers for temporary storage of electrical energy.
In particular, charging and discharging processes of battery units used in the stationary energy store lead to heat release, which is dissipated in order to maintain the performance of the battery units.

For this purpose, from the prior art air conditioners for influencing the air temperature and humidity within the stationary energy storage are known.

Disclosure of the invention

A stationary energy store with the characterizing features of the independent claim offers the advantage that a more uniform temperature control of a plurality of battery units of the stationary energy store can be formed by an improved distribution of the tempering fluid temperature and the tempering fluid flow.
Thus, it is possible to reduce the number of battery units at a temperature higher than the average temperature of the battery units, and thus to reduce the aging rate of the battery units as a whole, since a more homogeneous distribution of the temperature of the plurality of battery units can be formed.

For this purpose, a stationary energy storage is provided, which comprises a plurality of battery units.
In particular, the stationary energy store comprises a plurality of lithium-ion battery units.
The plurality of battery units is arranged in a housing of the stationary energy store, which is closed to an environment of the stationary energy store.
Furthermore, the plurality of battery units is arranged side by side in a longitudinal direction of the housing.
In addition, a cooling element is arranged in the housing in the longitudinal direction adjacent to the battery units.
In this case, the plurality of battery units and a housing wall of the housing of the stationary energy store limit a first flow space formed for a flow with tempering fluid.
Furthermore, on a side of the plurality of battery units opposite the first flow space, a second flow space designed to flow through with tempering fluid is formed.
In this case, the housing further comprises a flow guide, which is arranged extending in the direction of the longitudinal direction of the housing.

The measures listed in the dependent claims advantageous refinements and improvements of the independent claim device are possible.

In particular, the first flow space is designed to flow through with a tempering fluid that has already been heated by the plurality of battery units, and the second flow space is designed to flow through with a tempering fluid that has not yet been heated by the plurality of battery units.
Here, the first flow space may also be referred to as a so-called hot aisle and the second flow space may also be referred to as a so-called cold aisle.

Under a battery unit should be understood at this point in particular a battery cell, a battery module or a designated as battery bag battery cabinet.

The flow guide is designed in particular as a planar component. For example, the flow guide may be formed of a metal sheet.
In this case, the flow guide can be arranged for example on a ceiling of the housing of the stationary energy storage.
It is also possible that the flow guide is attached to an upper side of the plurality of battery units.
It should be noted at this point that no additional elements are arranged next to the flow guide. In particular, the flow guide should not be part of a separately formed inside the housing flow channel.
Such an embodiment has the advantage that there is sufficient space at the top of the plurality of battery units available to electrical line, such as cables, or electronic components, such as control units to arrange.

It is advantageous if the flow-guiding element is designed to separate the flow space of the first flow space and of the second flow space from one another.
This makes it possible that the tempering fluid flowing through the cold aisle and the tempering fluid flowing through the hot aisle do not mix with one another.
Thus, the available power of the cooling element can be used with a higher utilization efficiency and a more homogeneous distribution of the available power of the cooling element can be formed over the plurality of battery units.
Furthermore, it should be noted that heated by the arrangement of a flow, which is arranged extending in the direction of the longitudinal direction of the housing, the cold aisle and hot aisle, so not yet heated by the plurality of battery units, cooled tempering or already from the plurality of battery units , heated tempering fluid can be separated from each other.

It is expedient if the plurality of battery units is arranged in the manner and / or if the plurality of battery units is designed in such a way that tempering fluid can flow through the plurality of battery units from the second flow space into the first flow space. In particular, it is expedient here for tempering fluid to flow through the plurality of battery units in order to flow from the second flow space into the first flow space.
As a result, it is possible that in the second flow space, also referred to as a cold aisle, cooled, tempering fluid flows through the plurality of battery units into the first flow space, which is also referred to as hot aisle, taking up the heat released by the plurality of battery units.
It should be noted here that by the arrangement of a flow guide, which is arranged extending in the direction of the longitudinal direction of the housing, so-called thermal short circuits in which tempering fluid flows directly from the designated as cold a second flow space in the designated as hot aisle first flow space, without to flow through the plurality of battery units or to temper the plurality of battery units, can largely be avoided.

According to one aspect of the invention, the flow guide is arranged on one side of the plurality of battery units, which is arranged opposite a footprint of the plurality of battery units.
In this case, the footprint designates, for example, an underside of the plurality of battery units, which is arranged directly adjacent to a bottom surface of the housing.
In particular, the flow guide can also be attached to the bottom surface of the housing opposite ceiling surface of the housing. The arrangement of the flow guide on the opposite side of the footprint, which may for example also be referred to as the top of the plurality of battery units, it is possible to minimize flows of the cooled tempering above the plurality of battery units.
As a result, tempering fluid, in particular, does not flow above the plurality of battery units from the second flow space into the first flow space and vice versa from the first flow space into the second flow space.

Advantageously, the cooling element is designed to receive tempering fluid from the first flow space on a first side and to deliver tempering fluid into the second flow space on a second side.
In this case, the tempering fluid may preferably be air.
This has the advantage that the cooling element can receive the tempering fluid from the first flow space designated as hot aisle, which can cool the tempering fluid and can deliver the tempering fluid into the second flow space designated as the cold aisle.
Thus, it is possible to form a closed temperature control, wherein tempering fluid can flow, for example, from the second flow space with a heat absorption through the plurality of battery units into the first flow space and can flow from the first flow space with a heat transfer through the cooling element into the second flow space ,

At this point, it should be noted that under a closed housing of the stationary energy storage is to be understood in particular that the cooling element heat dissipated via another medium, such as a refrigerant, to the environment of the stationary energy storage and no further medium, such as For example, a refrigerant from the environment of the stationary energy storage receives. In this case, heated air can be discharged from the hot aisle, for example, to the environment of the housing.
Furthermore, while the cooling element supplied heat extracted heat and release this heat to the environment, the cooled air flows into the cold aisle.
It is in particular also possible that in a further operating mode cooled ambient air is supplied directly to the housing and in particular the cold aisle.
This makes it possible, at ambient temperatures, which are sufficiently cold to save cooling capacity.
In particular, such cooling elements do not require so-called outdoor units.

Expediently, the first side of the cooling element is arranged perpendicular to the housing wall delimiting the first flow space, and / or the second side of the cooling element is arranged parallel to the housing wall delimiting the first flow space.
By arranging the first side of the cooling element perpendicular to the housing wall delimiting the first flow space, it is possible for heated and thus ascending tempering fluid, for example, to flow into the cooling element at a top side of the cooling element for cooling.
By arranging the second side of the cooling element parallel to the housing wall delimiting the first flow space, it is possible for cooled tempering fluid to flow uniformly into the second flow space and thus also for a homogeneous temperature over a height of the housing of the stationary energy store.

According to one aspect of the invention, the stationary energy store comprises a first number of battery units arranged side by side to a first row in the longitudinal direction of the housing and a second number of battery units arranged side by side to a second row in the longitudinal direction of the housing.
In this case, a first cooling element is arranged in the longitudinal direction adjacent to the first number of battery units, and a second cooling element is arranged adjacent to the second number of battery units in the longitudinal direction.
In this case, the first row and the second row are arranged opposite one another in the longitudinal direction of the stationary energy store. This makes it possible to efficiently use the space available in the housing of the stationary energy store, for example in a container, in a storage room or in a server room, and to arrange a plurality of cooling elements.
Thus, the required or required cooling capacity can be distributed to a plurality of cooling elements and a better air distribution can be formed.

According to the idea of the invention, it is advantageous if the second flow space is formed between the first row of the first number of battery units and the second row of the second number of battery units.
As a result, a simple construction of the stationary energy store is possible, wherein only exactly one common cold passage designated second flow space is to be formed for the two rows of battery units, that is, the first row and the second row.

According to the idea of the invention, it is expedient for the first cooling element and the second cooling element to be arranged opposite one another in the longitudinal direction of the stationary energy store.
Thus, it can be prevented that one of the cooling elements Temperierfluid in the second flow space directly or directly towards a single battery unit, whereby an uneven temperature distribution of the plurality of battery units would be formed and also an inhomogeneous aging of the plurality of battery units would be accelerated.
In other words, this means that the first cooling element and the second cooling element to lead cooled tempering directly or directly in the direction of the respective other cooling element in the second flow space.

It is particularly expedient according to the idea of the invention if the stationary energy store has an even number of pairs of oppositely disposed cooling elements.
It should be noted that in particular the first row may have a plurality of first cooling elements and the second row may have a plurality of second cooling elements.

list of figures

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description.

• 1 in einer perspektivischen Ansicht eine erfindungsgemäße Ausführungsform eines stationären Energiespeichers,
• 2 in einer Ansicht von oben die erfindungsgemäße Ausführungsform des stationären Energiespeichers und
• 3 in einer Seitenansicht die erfindungsgemäße Ausführungsform stationären Energiespeichers.

It shows

• 1 3 shows a perspective view of an embodiment according to the invention of a stationary energy store,
• 2 in a top view of the inventive embodiment of the stationary energy storage and
• 3 in a side view of the embodiment of the invention stationary energy storage.

The 1 shows a perspective view of an embodiment of a stationary energy storage device according to the invention 1 ,

The stationary energy storage 1 includes a plurality of battery units 2 , which are designed in particular as lithium-ion battery units.

In this case, the stationary energy storage 1 a housing 3 on which to an environment 4 of the stationary energy storage 1 is completed trained.
It should be noted in this passage that in the 1 the housing 3 is shown open, was dispensed with the representation of the housing cover, so that in an interior of the housing 3 arranged elements are recognizable.

The majority of battery units 2 is doing in a longitudinal direction 5 of the housing 3 arranged side by side.

In other words, this means the plurality of battery units 2 are arranged to a later explained in more detail row.

Furthermore, in the longitudinal direction 5 adjacent to the battery units 2 a cooling element 6 arranged.

The majority of battery units 2 and a housing wall 7 of the stationary energy storage 1 limit a first flow space 8th , which is formed to a flow with tempering fluid.

On a first flow space 8th opposite side of the plurality of battery units 2 is a second flow space 9 formed, which is formed to a flow with tempering fluid.

Furthermore, the housing has 3 a flow guide 10 on, which is in the direction of the longitudinal direction 5 of the housing 3 is arranged running. This is to be understood in particular that the largest dimension of the flow guide 10 in the direction of the longitudinal direction 5 of the housing 3 is arranged extending or parallel to the longitudinal direction 5 of the housing 3 is arranged running.

The flow guide 10 is doing to a fluidic separation of the first flow space 8th and the second flow space 9 formed from each other. This is to be understood in particular that the first flow space 8th , the second flow space 9 and the flow guide 10 are arranged in the manner to each other that tempering fluid is not directly from the first flow space 8th in the second flow space 9 can flow or from the second flow space 9 in the first flow space 8th can flow.

Here is the majority of battery units 2 arranged in the manner or formed in the manner that tempering through the plurality of battery units 2 through from the second flow space 9 in the first flow space 8th can flow. Thus, the flow guide serves 10 among other things, that tempering fluid not directly from the second flow space 9 in the first flow space 8th can flow, but through the plurality of battery cells 2 through from the second flow space 9 in the first flow space 8th flows.

The battery units 2 are in the case 3 of the stationary energy storage 1 with a footprint 11 on a floor 12 of the housing 3 established. Here is the flow guide 10 at one of the footprint 11 opposite side 13 the majority of battery units 2 arranged. In particular, the flow guide 10 while also one the ground 12 of the housing 13 be arranged opposite lid surface.

Now will be more detailed on the design of the cooling element 6 be received.
The cooling element 6 is designed to be on a first page 141 Temperingfluid, in particular air, from the first flow space 8th take.
The cooling element 6 is further adapted to a second page 142 Temperingfluid, in particular air, in the second flow space 9 leave. The cooling element cools 6 that from the first flow space 8th recorded Temperierfluid before the tempering in the second flow space 9 is delivered.
In other words, this means that out of the first flow space 8th absorbed tempering fluid has a higher temperature than in the second flow space 9 discharged tempering fluid.

According to the in the 1 embodiment shown is the first page 141 perpendicular to the first flow space 8th limiting housing wall 7 arranged. In particular, the first page 141 at the side 13 arranged.
Furthermore, according to the in the 1 embodiment shown, the second page 142 parallel to the first flow space 8th limiting housing wall 7 arranged.

The in the 1 shown embodiment of the stationary energy storage device according to the invention 1 indicates a first number of battery units 2 on which in the longitudinal direction 5 of the housing 3 next to each other to a first row 15 is arranged, and has a second number of battery units 2 on which in the longitudinal direction 5 of the housing 3 next to each other to a second row 16 is arranged.

It is in the longitudinal direction 5 adjacent to the first number of battery units 2 a first cooling element 61 arranged.
It is in the longitudinal direction 5 adjacent to the second number of battery units 2 a second cooling element 62 arranged.
In other words, this means that the first row 15 furthermore a first cooling element 61 includes or that the second row 62 furthermore a second cooling element 62 includes.

The first row 15 and the second row 16 are doing in the longitudinal direction 5 of the housing 3 arranged opposite each other.

In particular, the first number of battery units forms 2 the first row 15 and a first housing wall 7 a first first flow space 81 out. In particular, the second number of battery units forms 2 the second row 16 and a second housing wall 72 a second first flow space 82 out.

The second flow space 9 is between the first row 15 the first number of battery units 2 and the second row 16 the second number of battery units 2 educated. In particular, in the 1 shown embodiment of the stationary energy storage device according to the invention 1 exactly two first flow spaces 8th . 81 . 82 and exactly a second flow space 9 on.

Furthermore, the first cooling element 61 the first row 15 and the second cooling element 62 the second row 16 arranged opposite each other.

Thus, it can be prevented on the second side 142 of the cooling element 61 the second flow space 9 to guided tempering directly in the direction of a battery unit 2 is supplied.

The in 1 shown inventive stationary energy storage 1 has an even number of cooling elements 6 on, which are arranged in pairs opposite each other.
In particular, the stationary energy store according to 1 also a third cooling element 63 on which one within the first row 15 is arranged, and has a fourth cooling element 64 on which within the second row 16 is arranged. Here are the third cooling element 63 and fourth cooling element 64 arranged opposite each other.

Based on 2 and 3 , which is a view of the stationary energy store 1 from above or a side view of the stationary energy storage 1 show, is now an example of the flow of a stationary energy storage 1 be shown flowing through tempering.

It shows the 2 in a top view of the embodiment of the stationary energy storage device according to the invention 1 according to 1 ,

It shows the 3 in a side view, the embodiment of the stationary energy storage device according to the invention 1 according to 1 ,

The cooling elements 6 lead the second flow space 9 , which is also referred to as cold aisle, on the second page 142 initially cooled tempering to.

The cooled tempering fluid then flows through the second flow space 9 what is indicated by the arrows with the reference numeral 17 should be indicated.

In particular, the second flow space 9 from the first cooling element 61 , the second cooling element 62 , the third cooling element 63 and the fourth cooling element 64 supplied cooled tempering, which evenly on the plurality of battery units 2 is distributed.

The flow guide 10 subsequently prevents the tempering fluid directly from the second flow space 9 in the first flow space 8th can flow, so that tempering fluid from the second flow space 9 through the plurality of battery units 2 through into the first flow space 8th flows. In this case, the tempering fluid is heated by a recording of heat, which of the plurality of battery units 2 which will give the majority of battery units 2 can be cooled.

The heated tempering fluid then flows through the first flow space 8th , which is also referred to as hot aisle, wherein the flow through the arrows by the reference numeral 18 should be indicated. In particular, the heated tempering fluid rises in the first flow space 8th in the direction of the page 13 up and over the first page 141 the cooling element 6 again to.
The tempering fluid can also be along the side 13 stream.
In this case prevents the flow guide 10 in that already heated tempering fluid from the first flow space 8th in the second flow space 9 can flow.
The cooling element 6 cools the tempering fluid again.

The 3 shows in a side view an example of a stationary energy storage with a view towards the first row 15 ,

This is the first number of battery units 2 to recognize the first row.

Furthermore, the cooling element 6 , in particular the first cooling element 61 and the third cooling element 63 , including the second page 142 to recognize, by means of which cooled tempering fluid in the second flow space 9 is admitted.

Furthermore, it can be seen that the cooled tempering fluid uniformly on the plurality of battery units 2 can be distributed.

In particular, tempering fluid from the first cooling element 61 and the third cooling element 63 evenly on the majority of battery units 2 be distributed.

That in the 3 to be recognized flow guide 10 prevents tempering fluid flow directly from the second flow space 9 in the first flow space 8th ,

Claims (10)

Stationary energy storage device comprising a plurality of battery units (2), in particular a plurality of lithium-ion battery units, which is arranged in a relative to an environment (4) closed housing (3) of the stationary energy store (1), wherein the plurality of battery units ( 2) in a longitudinal direction (5) of the housing (3) is arranged side by side, and in the housing (3) further in the longitudinal direction (5) adjacent to the battery units (2), a cooling element (6) is arranged, wherein the plurality of Battery units (2) and a housing wall (7) of the housing (3) of the stationary energy store (1) define a first flow space (8) designed for a flow of tempering fluid and on a side of the plurality of battery units opposite the first flow space (8). 2) is formed to a flow with tempering fluid formed second flow space (9), characterized in that the Housing (3) further comprises a flow guide (10) which is arranged to extend in the direction of the longitudinal direction (5) of the housing (3). Stationary energy storage after the previous one Claim 1 , characterized in that the flow-guiding element (10) is designed for a fluidic separation of the first flow space (8) and the second flow space (9) from each other. Stationary energy storage after one of the previous ones Claims 1 or 2 , characterized in that the plurality of battery units (2) is arranged in the manner and / or is formed in such a way that tempering through the plurality of battery units (2) from the second flow space (9) into the first flow space (8 ) can flow. Stationary energy storage after one of the previous ones Claims 1 to 3 , characterized in that the flow-guiding element (10) is arranged on a side (13) of the plurality of battery units (2) which is opposite a mounting surface (11) of the battery units (2). Stationary energy storage after one of the previous ones Claims 1 to 4 , characterized in that the cooling element (6) is adapted to receive at a first side (141) tempering, in particular air, from the first flow space (8) and at a second side (142) tempering, in particular air, in the second Dispensing flow space (9). Stationary energy storage after the previous one Claim 5 , characterized in that the first side (141) is arranged perpendicular to the housing wall (7) defining the first flow space (8) and / or the second side (142) is parallel to the housing wall (7) delimiting the first flow space (8). is arranged. Stationary energy storage after one of the previous ones Claims 1 to 6 , characterized in that a first number of battery units (2) in the longitudinal direction (5) of the housing (3) is arranged side by side to a first row (15) and that a second number of battery units (2) in the longitudinal direction (5) of the housing (3) is arranged side by side to a second row (16), further in the longitudinal direction (5) adjacent to the first number of battery units (2), a first cooling element (61) is arranged and in the longitudinal direction (5) adjacent to the second number of battery units (2), a second cooling element (62) is arranged, wherein the first row (15) and the second row (16) in the longitudinal direction (5) of the housing (3) are arranged opposite to each other. Stationary energy storage after the previous one Claim 7 , characterized in that the second flow space (9) is formed between the first row (15) of the first number of battery units (2) and the second row (16) of the second number of battery units (2). Stationary energy storage after one of the previous ones Claims 7 or 8th characterized in that the first cooling element (61) and the second cooling element (62) are in the longitudinal direction (5) of the stationary energy store (1) are arranged opposite to each other. Stationary energy storage after the previous one Claim 9 , characterized in that the stationary energy store (1) has an even number of each pairwise opposite to each other arranged cooling elements (6).

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