CN114361491A - Multi-mode output zinc-silver reserve battery pack structure - Google Patents

Abstract

A multi-mode output zinc-silver reserve battery pack structure, comprising: the liquid distribution device comprises a shell, a liquid distribution groove is formed in the shell, a plurality of single battery grooves are formed in the shell, and each single battery groove corresponds to a distribution channel and is communicated with the liquid distribution groove; each distribution channel is provided with a liquid inlet which is arranged on the bottom of the liquid separation tank; arranging a single battery in each single battery groove; the liquid storage device is arranged on the shell and is communicated with the liquid separation groove; a gas generator disposed on the reservoir; all the single batteries in the shell are connected in series and then tapped to form a plurality of power supply modules for supplying power independently; or all the single batteries in the shell are divided into a plurality of groups, and each group of single batteries are connected in series to form an independent power supply module for supplying power to the outside independently. The invention adopts the same cell stack, the same activation system and different liquid inlet systems, can realize the uniform distribution of the electrolyte and simultaneously output arrays of electric energy with different powers.

Description

Multi-mode output zinc-silver reserve battery pack structure

Technical Field

The invention relates to the technical field of zinc-silver reserve batteries, in particular to a multi-mode output zinc-silver reserve battery pack structure.

Background

The zinc-silver reserve battery pack is a power supply in the aerospace field, is special in the application field, and directly requires that the battery has the characteristics of high output voltage precision, small volume, various working modes and the like.

Most of the existing traditional zinc-silver reserve battery packs are in one-to-one output mode, and cannot provide electric energy in different output modes through one group of batteries, the mode batteries are single in use mode and relatively large in occupied space volume, if multiple groups of equipment are powered simultaneously, application guarantees provided inside a system are relatively more, for example, the system provides multiple groups of activation voltages and heating voltages; a plurality of cell stacks, liquid reservoirs and the like are required to be designed in the cell.

Disclosure of Invention

The invention mainly aims to provide a multi-mode output zinc-silver reserve battery pack structure, and aims to solve the technical problem.

In order to achieve the above object, the present invention provides a multi-mode output zinc-silver reserve battery pack structure, which includes:

the liquid distribution device comprises a shell, a liquid distribution groove is formed in the shell, a plurality of single battery grooves are formed in the shell, and each single battery groove corresponds to a distribution channel and is communicated with the liquid distribution groove; each distribution channel is provided with a liquid inlet which is arranged on the bottom of the liquid separation tank; arranging a single battery in each single battery groove;

a liquid reservoir, which is arranged on the shell and is communicated with the liquid separating groove;

a gas generator disposed on the reservoir;

all the single batteries in the shell are connected in series and then tapped to form a plurality of power supply modules for supplying power independently;

or all the single batteries in the shell are divided into a plurality of groups, and each group of single batteries are connected in series to form an independent power supply module for supplying power to the outside independently.

Preferably, the width of each single battery jar on the shell is the same, and the diameter of each corresponding liquid inlet is the same. Specifically, the width of each single battery jar on the shell is 6mm, and the diameter of the liquid inlet corresponding to each single battery jar is phi 1.2 mm.

Optionally, the single battery jar on the casing has different width specifications, and the liquid inlet holes corresponding to the single battery jars of different width specifications have different diameters. Specifically, the single battery jar on the shell has two width specifications, namely 12mm and 8.3mm respectively; the diameter of a liquid inlet hole corresponding to the monomer battery jar with the width of 12mm is phi 2 mm; the diameter of the liquid inlet hole corresponding to the monomer battery jar with the width of 8.3mm is phi 1.4 mm. Or the single battery jar has two width specifications of 16mm and 12 mm; the diameter of a liquid inlet hole corresponding to the monomer battery jar with the width of 16mm is phi 2 mm; the diameter of the liquid inlet hole corresponding to the monomer battery jar with the width of 12mm is phi 1.2 mm.

Preferably, an air exhaust device is arranged on the shell and is communicated with the liquid separating groove. When the zinc-silver reserve battery pack is activated, the redundant gas in the shell is exhausted out of the battery stack through the exhaust device.

Preferably, a first sealing joint is arranged between the liquid storage device and the liquid separation groove, and a second sealing joint is arranged between the gas generator and the liquid storage device; sealing films are respectively arranged in the first sealing joint and the second sealing joint; when the zinc-silver reserve battery pack is not activated, the electrolyte is stored in the liquid reservoir in a sealing mode through the first sealing joint and the second sealing joint; when the zinc-silver reserve battery pack is activated, high-pressure gas bursts the sealing film.

Preferably, all the single batteries in the shell are connected in series and then tapped to form two power supply modules for independently supplying power to the outside.

Optionally, all the single batteries in the shell are divided into two groups, and each group of single batteries are connected in series to form an independent power supply module for supplying power to the outside independently.

Due to the adoption of the technical scheme, the invention has the following beneficial effects:

(1) the zinc-silver reserve battery pack provided by the invention adopts the same battery stack, the same activating system and different liquid inlet systems, can realize uniform distribution of electrolyte and simultaneous output of a plurality of groups of electric energy with different powers, realizes simultaneous output of one battery with different power consumption and different working time of a plurality of groups of electric equipment, and meets the requirement of small battery size.

(2) In the invention, the width of the single battery groove and the distribution channel are specially designed according to the capacity and the voltage characteristics, and a plurality of power supply modules are formed to independently supply power to the outside. The battery pack has simple structure, high volumetric specific energy and convenient use, and can be stored for a long time.

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 the structures shown in the drawings without creative efforts.

Fig. 1 is a front view of a multi-mode output zinc-silver reserve battery pack structure provided by the invention;

FIG. 2 is a left side view of a multi-mode output zinc-silver reserve battery pack structure provided by the invention;

FIG. 3 is a schematic diagram of the connection of a single cell battery according to one embodiment of the present invention;

FIG. 4 is a schematic diagram of a grouping of single cells according to a first embodiment of the present invention;

FIG. 5 is a schematic diagram of the connection of a single cell battery according to a second embodiment of the present invention;

FIG. 6 is a schematic diagram illustrating the grouping of the unit cells according to the second embodiment of the present invention;

FIG. 7 is a schematic diagram of the connection of a single cell battery according to a third embodiment of the present invention;

fig. 8 is a schematic diagram of two power supply modules formed by tapping single batteries after the single batteries are connected in series according to a third embodiment of the present invention;

description of the figures: 1-a shell; 101-a liquid separating tank; 102-a liquid inlet hole; 2-the first sealing joint; 3-a gas generator; 4-the second sealing joint; 5-an exhaust device; 6-a liquid reservoir; 7-a distribution channel; 8-a single cell battery jar; 9-single battery.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The first embodiment is as follows:

as shown in fig. 1 and fig. 2, a multi-mode output zinc-silver reserve battery pack structure includes:

the device comprises a shell 1, wherein a liquid separation tank 101 is arranged on the shell 1, 32 single battery tanks 8 are arranged in the shell 1, and each single battery tank 8 corresponds to a distribution channel 7 and is communicated with the liquid separation tank 101; each distribution channel 7 is provided with a liquid inlet 102, and the liquid inlet 102 is arranged on the bottom of the liquid separation tank 101; arranging a single battery 9 in each single battery jar 8, wherein the width of each single battery 9 is matched with that of each single battery jar 8;

a liquid reservoir 6, wherein the liquid reservoir 6 is arranged on the shell 1, and the liquid reservoir 6 is communicated with the liquid separation tank 101;

a gas generator 3, said gas generator 3 being arranged on a liquid reservoir 6.

An exhaust device 5 is provided on the housing 1, and the exhaust device 5 is communicated with the liquid separation tank 101. When the zinc-silver reserve battery pack is activated, the excess gas inside the casing 1 is discharged to the outside of the cell stack through the exhaust device 5.

A first sealing joint 2 is arranged between the liquid storage device 6 and the liquid separation groove 101, and a second sealing joint 4 is arranged between the gas generator 3 and the liquid storage device 6; sealing films are respectively arranged in the first sealing joint 2 and the second sealing joint 4; when the zinc-silver reserve battery pack is not activated, the electrolyte is stored in the liquid storage device 6 in a sealing mode through the first sealing joint 2 and the second sealing joint 4; upon activation of the zinc-silver reserve battery, the gas generator 3 breaks the seal membrane. The gas generator 3 is used as a battery pack activation power device, a low-voltage direct-current power supply is adopted to ignite the gas generator 3 to generate high-pressure gas, sealing films in the first sealing joint 2 and the second sealing joint 4 are broken, electrolyte in the liquid reservoir 6 firstly enters the liquid separating groove 101, then enters the corresponding distribution channel 7 through each liquid inlet hole 102 and then enters the monomer battery jar 8 communicated with the distribution channel 7, electrolyte injection is completed, and the battery pack can supply power to the outside.

Referring to fig. 3 and 4, 32 single battery jars 8 in the housing 1 are arranged in 16 rows and 2 columns, and the single battery jars 8 have two different width specifications, namely 12mm and 8.3 mm; the diameter of a liquid inlet hole 102 corresponding to the monomer battery jar 8 with the width of 12mm is phi 2 mm; the diameter of the liquid inlet hole 102 corresponding to the single battery jar 8 with the width of 8.3mm is phi 1.4 mm. All the unit cells 9 inside the case 1 are divided into two groups, i.e., group i and group ii shown in fig. 4.

The power supply module formed by the group I is formed by combining 14 single batteries 9 arranged in the first seven rows of single battery grooves 8 in series, and the positive pole and the negative pole of the power supply module are A + and A-shown in figure 3. The width of the monomer battery jar 8 corresponding to the group I is 12mm, and the diameter of the corresponding liquid inlet hole 102 is phi 2 mm. The power supply module in the group I provides 20V voltage, working current is 10A to 15A, and discharge capacity is 6.0 Ah.

The power supply module formed by the group II is formed by combining 18 single batteries 9 arranged in the back nine rows of single battery grooves 8 in series, and the positive pole and the negative pole of the power supply module are B + and B-shown in figure 3. The width of the monomer battery jar 8 corresponding to the group II is 8.3mm, and the diameter of the corresponding liquid inlet hole 102 is phi 1.4 mm. The power supply module in the group II provides 25V voltage, working current is 3A to 5A, and discharge capacity is 4.0 Ah.

Example two:

as shown in fig. 1 and fig. 2, a multi-mode output zinc-silver reserve battery pack structure includes:

the device comprises a shell 1, wherein a liquid separation tank 101 is arranged on the shell 1, 40 single battery tanks 8 are arranged in the shell 1, and each single battery tank 8 corresponds to a distribution channel 7 and is communicated with the liquid separation tank 101; each distribution channel 7 is provided with a liquid inlet 102, and the liquid inlet 102 is arranged on the bottom of the liquid separation tank 101; arranging a single battery 9 in each single battery jar 8, wherein the width of each single battery 9 is matched with that of each single battery jar 8;

a liquid reservoir 6, wherein the liquid reservoir 6 is arranged on the shell 1, and the liquid reservoir 6 is communicated with the liquid separation tank 101;

a gas generator 3, said gas generator 3 being arranged on a liquid reservoir 6.

An exhaust device 5 is provided on the housing 1, and the exhaust device 5 is communicated with the liquid separation tank 101. When the zinc-silver reserve battery pack is activated, the excess gas inside the casing 1 is discharged to the outside of the cell stack through the exhaust device 5.

A first sealing joint 2 is arranged between the liquid storage device 6 and the liquid separation groove 101, and a second sealing joint 4 is arranged between the gas generator 3 and the liquid storage device 6; sealing films are respectively arranged in the first sealing joint 2 and the second sealing joint 4; when the zinc-silver reserve battery pack is not activated, the electrolyte is stored in the liquid storage device 6 in a sealing mode through the first sealing joint 2 and the second sealing joint 4; upon activation of the zinc-silver reserve battery, the gas generator 3 breaks the seal membrane. The gas generator 3 is used as a battery pack activation power device, a low-voltage direct-current power supply is adopted to ignite the gas generator 3 to generate high-pressure gas, sealing films in the first sealing joint 2 and the second sealing joint 4 are broken, electrolyte in the liquid reservoir 6 firstly enters the liquid separating groove 101, then enters the corresponding distribution channel 7 through each liquid inlet hole 102 and then enters the monomer battery jar 8 communicated with the distribution channel 7, electrolyte injection is completed, and the battery pack can supply power to the outside.

Referring to fig. 5 and 6, 40 single battery jars 8 in the housing 1 are arranged in 20 rows and 2 columns, the width of each single battery jar 8 on the housing 1 is the same, and the diameter of each corresponding liquid inlet 102 is the same. Specifically, the width of each single battery jar 8 on the housing 1 is 6mm, and the diameter of the liquid inlet 102 corresponding to each single battery jar 8 is phi 1.2 mm. All the unit batteries 9 inside the case 1 are divided into two groups, such as a G1 group and a G2 group shown in fig. 6.

The G1 group forms a power supply module consisting of a total of 21 cells 9 arranged in series in the first cell well 8 of the first row and all the cell wells 8 of the second row, the positive and negative poles of which are shown as E + and E-in fig. 5. The power supply modules in the group G1 provide 29.5V voltage, working current 2A to 21A and discharge capacity 2.2 Ah.

The G2 group forms a power supply module consisting of a total of 19 cells 9 arranged in series in the first column and the nineteen rows of cell wells 8, the positive and negative poles of which are shown as F + and F-in fig. 5. The power supply module in the group II provides 28.0V voltage, working current 1A to 14A and discharge capacity 2.1 Ah.

Example three:

as shown in fig. 1 and fig. 2, a multi-mode output zinc-silver reserve battery pack structure includes:

the device comprises a shell 1, wherein a liquid separation tank 101 is arranged on the shell 1, 14 single battery tanks 8 are arranged in the shell 1, and each single battery tank 8 corresponds to a distribution channel 7 and is communicated with the liquid separation tank 101; each distribution channel 7 is provided with a liquid inlet 102, and the liquid inlet 102 is arranged on the bottom of the liquid separation tank 101; arranging a single battery 9 in each single battery jar 8, wherein the width of each single battery 9 is matched with that of each single battery jar 8;

a liquid reservoir 6, wherein the liquid reservoir 6 is arranged on the shell 1, and the liquid reservoir 6 is communicated with the liquid separation tank 101;

a gas generator 3, said gas generator 3 being arranged on a liquid reservoir 6.

An exhaust device 5 is provided on the housing 1, and the exhaust device 5 is communicated with the liquid separation tank 101. When the zinc-silver reserve battery pack is activated, the excess gas inside the casing 1 is discharged to the outside of the cell stack through the exhaust device 5.

A first sealing joint 2 is arranged between the liquid storage device 6 and the liquid separation groove 101, and a second sealing joint 4 is arranged between the gas generator 3 and the liquid storage device 6; sealing films are respectively arranged in the first sealing joint 2 and the second sealing joint 4; when the zinc-silver reserve battery pack is not activated, the electrolyte is stored in the liquid storage device 6 in a sealing mode through the first sealing joint 2 and the second sealing joint 4; upon activation of the zinc-silver reserve battery, the gas generator 3 breaks the seal membrane. The gas generator 3 is used as a battery pack activation power device, a low-voltage direct-current power supply is adopted to ignite the gas generator 3 to generate high-pressure gas, sealing films in the first sealing joint 2 and the second sealing joint 4 are broken, electrolyte in the liquid reservoir 6 firstly enters the liquid separating groove 101, then enters the corresponding distribution channel 7 through each liquid inlet hole 102 and then enters the monomer battery jar 8 communicated with the distribution channel 7, electrolyte injection is completed, and the battery pack can supply power to the outside.

Referring to fig. 7 and 8, 14 single battery jars 8 in the housing 1 are arranged in 7 rows and 2 columns, and the single battery jars 8 have two different width specifications, namely 16mm and 12 mm; the width of the single battery jar 8 in the first row and the second row is 16mm, and the diameter of the corresponding liquid inlet hole 102 is phi 2 mm. The width of the single battery jar 8 in the second to seventh rows is 12mm, and the diameter of the corresponding liquid inlet hole 102 is phi 1.2 mm.

All the single batteries 9 in the shell 1 are connected in series and then tapped to form two power supply modules for independently supplying power to the outside. Such as power supply module B1 and power supply module B2 shown in fig. 8.

The power supply module B1 is formed by connecting all the single batteries 9 in the housing 1 in series and then tapping 4 single batteries 9 connected in series in the first row and the second row of single battery slots 8, the width of the single battery slot 8 corresponding to the power supply module is 16mm, and the diameter of the corresponding liquid inlet hole 102 is phi 2 mm. The power supply module B1 provides 5.5V voltage, working current 6A to 10A and discharge capacity 5.0 Ah.

The power supply module B2 is formed by connecting 14 single batteries 9 in total in the shell 1 in series, and the power supply module B2 provides 20V voltage, working current 3A to 6A and discharge capacity 3.2 Ah.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents made by the contents of the present specification and drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A multi-mode output zinc-silver reserve battery pack structure is characterized by comprising:

the liquid distribution device comprises a shell (1), wherein a liquid distribution groove (101) is formed in the shell (1), a plurality of single battery grooves (8) are formed in the shell (1), and each single battery groove (8) corresponds to a distribution channel (7) and is communicated with the liquid distribution groove (101); each distribution channel (7) is provided with a liquid inlet (102), and the liquid inlet (102) is arranged on the bottom of the liquid distribution groove (101); arranging a single battery (9) in each single battery groove (8);

a liquid storage device (6), wherein the liquid storage device (6) is arranged on the shell (1), and the liquid storage device (6) is communicated with the liquid separation tank (101);

a gas generator (3), said gas generator (3) being arranged on the liquid reservoir (6);

all the single batteries (9) in the shell (1) are connected in series and then tapped to form a plurality of power supply modules for independently supplying power to the outside;

or all the single batteries (9) in the shell (1) are divided into a plurality of groups, and each group of single batteries are connected in series to form an independent power supply module for supplying power to the outside independently.

2. The multi-mode output zinc-silver reserve battery pack structure as claimed in claim 1, wherein: the width of each single battery jar (8) on the shell (1) is the same, and the diameter of each corresponding liquid inlet (102) is the same.

3. The multi-mode output zinc-silver reserve battery pack structure as claimed in claim 2, wherein: the width of each single battery jar (8) on the shell (1) is 6mm, and the diameter of the liquid inlet (102) corresponding to each single battery jar (8) is phi 1.2 mm.

4. The multi-mode output zinc-silver reserve battery pack structure as claimed in claim 1, wherein: monomer battery jar (8) possess different width specifications on casing (1), and the feed liquor hole (102) diameter that monomer battery jar (8) of different width specifications correspond is different.

5. The multi-mode output zinc-silver reserve battery pack structure of claim 4, characterized in that: the single battery jar (8) on the shell (1) has two width specifications which are respectively 12mm and 8.3 mm;

the diameter of a liquid inlet hole (102) corresponding to the single battery jar (8) with the width of 12mm is phi 2 mm;

the diameter of the liquid inlet hole (102) corresponding to the monomer battery jar (8) with the width of 8.3mm is phi 1.4 mm.

6. The multi-mode output zinc-silver reserve battery pack structure of claim 4, characterized in that: the single battery jar (8) on the shell (1) has two width specifications, namely 16mm and 12 mm;

the diameter of a liquid inlet hole (102) corresponding to the monomer battery jar (8) with the width of 16mm is phi 2 mm;

the diameter of the liquid inlet hole (102) corresponding to the single battery jar (8) with the width of 12mm is phi 1.2 mm.

7. The multi-mode output zinc-silver reserve battery pack structure as claimed in claim 1, wherein: an exhaust device (5) is arranged on the shell (1), and the exhaust device (5) is communicated with the liquid dividing tank (101).

8. The multi-mode output zinc-silver reserve battery pack structure as claimed in claim 1, wherein: a first sealing joint (2) is arranged between the liquid storage device (6) and the liquid separation groove (101), and a second sealing joint (4) is arranged between the gas generator (3) and the liquid storage device (6); sealing films are respectively arranged in the first sealing joint (2) and the second sealing joint (4); when the zinc-silver reserve battery pack is activated, high-pressure gas bursts the sealing film.

9. The multi-mode output zinc-silver reserve battery pack structure as claimed in claim 1, wherein: all the single batteries (9) in the shell (1) are connected in series and then tapped to form two power supply modules for independently supplying power to the outside.

10. The multi-mode output zinc-silver reserve battery pack structure as claimed in claim 1, wherein: all the single batteries (9) in the shell (1) are divided into two groups, and each group of single batteries are connected in series to form an independent power supply module for supplying power to the outside independently.

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