CN118281996B - Energy storage unit multilayer concatenation formula portable power source - Google Patents

Abstract

The invention belongs to the technical field of mobile power supplies, and particularly relates to an energy storage unit multi-layer spliced mobile power supply, which comprises a shell assembly, an isolation assembly, a first energy storage assembly and a second energy storage assembly; the shell assembly is of an open structure, the top of the shell assembly is movably clamped with a shell cover plate, the shell cover plate is rotationally connected to the central axis of the shell assembly through the isolation assembly, the shell cover plate is used for isolating the first energy storage assembly and the second energy storage assembly, and when the first energy storage assembly and the second energy storage assembly move back or the first energy storage assembly and the second energy storage assembly move in the same direction, the isolation assembly is rotationally connected to the central axis center of the shell assembly, so that the isolation assembly can simultaneously radiate heat and cool the first energy storage assembly and the second energy storage assembly to increase the flow speed of gas in the shell assembly, and the safety and stability of the first energy storage assembly and the second energy storage assembly in the discharging or charging process are improved.

Description

Energy storage unit multilayer concatenation formula portable power source

Technical Field

The invention belongs to the technical field of mobile power supplies, and particularly relates to an energy storage unit multi-layer spliced mobile power supply.

Background

The portable power source is also called a charger, a travel charger and the like, is a portable charger integrating the functions of power supply and charging, can charge digital equipment such as mobile phones, tablet computers and the like at any time and any place, and is convenient and quick to use because a lithium battery (or a dry battery, less frequently) is used as a power storage unit; at present, the existing mobile power supply is generally directly placed in a pocket to charge electronic equipment such as a mobile phone and the like when in use.

Through searching, in the prior art, chinese patent publication No. CN217607521U discloses date: 2022-10-18 discloses a multifunctional mobile power supply, including mobile power supply, mobile power supply's upper surface fixed mounting has the button, mobile power supply's upper surface has seted up the USB interface, mobile power supply's front is equipped with the dust screen, this multifunctional mobile power supply of cross port of airing exhaust has all been seted up to mobile power supply's left and right sides face, filter the operation through porous filter, the filtration plectane, the cooperation of filter plate, fan-shaped filter and multilayer filter to the dust in the air, have better filtration adsorption operation to the dust in the air, be convenient for better to mobile power supply carries out ventilation heat dissipation operation, the effectual inside thermal equilibrium of assurance mobile power supply avoids long-time in comparatively confined environment appearance the overheated circumstances of electric core, avoid the electric core to appear the dangerous condition of spontaneous combustion, be favorable to safer to use mobile power supply.

The device still has the following drawbacks: although the dangerous situation that the battery core is overheated and spontaneous combustion occurs can be avoided, the battery core is favorable for safer use of the mobile power supply, the battery core is unfavorable for switching use in a state that multiple groups of energy storage are discharged simultaneously or are discharged independently, and the problem that the effect of local cooling is not ideal and comprehensive is solved.

Disclosure of Invention

In order to solve the problems, the invention provides an energy storage unit multi-layer spliced mobile power supply, which comprises a shell assembly, an isolation assembly, a first energy storage assembly and a second energy storage assembly; the shell assembly is of an open structure, a shell cover plate is movably clamped at the top of the shell assembly, the central axis of the isolation assembly coincides with the central axis of the shell assembly, the isolation assembly is rotationally connected to the inner wall of the shell assembly, the first energy storage assembly and the second energy storage assembly are both in sliding connection with the inner wall of the shell assembly, the first energy storage assembly is movably attached to the top end of the inner wall of the isolation assembly, and the second energy storage assembly is movably attached to the bottom end of the inner wall of the isolation assembly;

The isolation assembly is rotationally connected to the central axis center of the shell assembly, so that the isolation assembly can simultaneously radiate heat and cool the first energy storage assembly and the second energy storage assembly to increase the flow speed of gas in the shell assembly, and the safety and stability of the first energy storage assembly and the second energy storage assembly in the discharging or charging process are improved.

Further, the housing assembly includes a first housing; two sets of handle assembly holes are formed in the outer wall of one side of the first shell, the two sets of handle assembly holes are symmetrically arranged with the central axis of the first shell as the center, one side of the shell assembly is fixedly connected with a handle, the two sets of handle assembly holes are movably sleeved at the end part of the handle, a first slot, a second slot and two sets of first guide sliding grooves are formed in the outer wall of the first shell, the first slot, the second slot and the two sets of first guide sliding grooves are located above the same horizontal line of the two sets of handle assembly holes, the first slot and the second slot are symmetrically arranged with the central axis of the first shell as the center, and the two sets of first guide sliding grooves are symmetrically arranged with the central axis of the first shell as the center.

Further, the outer wall of the first shell is provided with a third slot, a fourth slot and two groups of second guide sliding grooves, the third slot, the fourth slot and the two groups of second guide sliding grooves are located below the same horizontal line of the two groups of handle assembly holes, the third slot and the fourth slot are symmetrically arranged with the central axis of the first shell as the center, and the two groups of second guide sliding grooves are symmetrically arranged with the central axis of the first shell as the center.

Further, the isolation assembly comprises an isolation plate; the outer wall of one side of division board is embedded to install first motor, just the output of first motor and the inner wall fixed connection of first casing, the outer wall of division board and one side of keeping away from first motor are rotated with the inner wall of first casing and are connected, the magnetic adsorption piece is all embedded to the outer wall both ends of division board, and two sets of magnetic adsorption piece respectively swing adsorption connects on the casing apron.

Further, laminating groove has all been seted up to the top and the bottom of division board, a set of laminating groove's inner wall is provided with first guiding mechanism, and another set of laminating groove's inner wall is provided with second guiding mechanism, first guiding mechanism all coincides with the axis of first motor with second guiding mechanism, just first guiding mechanism all is the same with second guiding mechanism's structure, shape.

Further, the first diversion mechanism comprises a diversion plate; the surface of guide plate has seted up the fan, two sets of magnetism adsorption columns are installed in the outer wall embedding of guide plate, and two sets of magnetism adsorption columns distribute in the top corner that is close to the guide plate, the bottom of guide plate is provided with the radian base.

Further, the second motor is installed in the outer wall of guide plate and one side embedding near the radian base, the output of second motor and the inner wall fixed connection in laminating groove, the axis coincidence of second motor and first motor, the outer wall of guide plate just is close to the opposite side in radian base and the inside rotation in laminating groove are connected.

Further, the first energy storage assembly includes a second housing; the second shell is of an open structure, two groups of guide sliding blocks are fixedly connected to the outer wall of the second shell, the two groups of guide sliding blocks are connected to the inner wall of the first guide sliding groove in a sliding fit mode, the two groups of guide sliding blocks are fixedly connected with stirring blocks, and the stirring blocks extend to the outer portion of the first guide sliding groove.

Further, the inner wall fixedly connected with power electricity core of second casing, one side outer wall of second casing is provided with first interface, just the opposite side outer wall of second casing is provided with the second interface, a plurality of groups of drainage through-holes have been seted up to the outer wall of second casing and one side that is close to the second interface.

Further, a power output mechanism is arranged on one side, close to the first interface, of the outer wall of the power supply battery cell, a charging circuit mechanism is arranged on one side, close to the second interface, of the outer wall of the power supply battery cell, the power supply battery cell is electrically connected with the first interface through the power output mechanism, and the power supply battery cell is electrically connected with the second interface through the charging circuit mechanism.

The beneficial effects of the invention are as follows:

1. The isolation assembly is rotationally connected to the central axis of the shell assembly and used for isolating the first energy storage assembly and the second energy storage assembly, and when the first energy storage assembly and the second energy storage assembly move back, or the first energy storage assembly and the second energy storage assembly move in the same direction, the isolation assembly is rotationally connected to the central axis center of the shell assembly, so that the isolation assembly can simultaneously radiate heat and cool the first energy storage assembly and the second energy storage assembly to increase the flow speed of gas in the shell assembly, and the safety stability of the first energy storage assembly and the second energy storage assembly in the discharging or charging process is improved.

2. Make second casing horizontal migration to arbitrary one end of first direction spout through stirring the piece through manual regulation, when first interface removes to in the first slot, make the power supply cell supply to the consumer of first interface internal connection, and second interface and second slot are in the state of separation to be the state of intercommunication through a plurality of sets of drainage through-holes and fan, carry out the effect of continuously cooling to power supply cell, power output mechanism and the charging circuit mechanism in the second casing under the state that the fan continuously worked, improved the inside heat dispersion's of casing efficiency.

3. The second motor rotates, the guide plate rotates by taking the second motor as the center, and the magnetic adsorption column is utilized to magnetically adsorb on the outer wall of the first energy storage component or the second energy storage component, so that the stability of the fan during working is improved, and the fan is utilized to continuously work, and the end part of the first energy storage component or the second energy storage component is subjected to the effects of heat adsorption and guide, so that the stability among the components in the self-switching process is improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 shows a schematic structural diagram of a multi-layer spliced mobile power supply with an energy storage unit according to an embodiment of the invention;

FIG. 2 shows a schematic structural view of a housing assembly according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a first embodiment of an isolation assembly;

FIG. 4 is a schematic diagram illustrating a second configuration of an isolation assembly according to an embodiment of the present invention;

FIG. 5 is a schematic structural view of a first diversion mechanism according to an embodiment of the present invention;

Fig. 6 is a schematic structural diagram of a first energy storage assembly according to an embodiment of the present invention;

FIG. 7 illustrates a schematic exploded view of a first energy storage assembly in accordance with an embodiment of the present invention;

FIG. 8 illustrates a schematic discharge of a second energy storage assembly in accordance with an embodiment of the present invention;

FIG. 9 illustrates a schematic discharge of a first energy storage assembly in accordance with an embodiment of the present invention;

fig. 10 shows a schematic discharge diagram of a first energy storage assembly and a second energy storage assembly according to an embodiment of the present invention.

In the figure: 1. a housing assembly; 11. a first housing; 12. a handle assembly hole; 13. a first slot; 14. a second slot; 15. a first guide chute; 16. a third slot; 17. a fourth slot; 18. the second guide chute; 2. an isolation assembly; 21. a partition plate; 22. a first motor; 23. a magnetic adsorption block; 24. a bonding groove; 25. a first flow guiding mechanism; 251. a deflector; 252. a fan; 253. a magnetic adsorption column; 254. a bottom edge of the radian; 255. a second motor; 26. a second flow guiding mechanism; 3. a housing cover plate; 4. a handle; 5. a first energy storage assembly; 51. a second housing; 52. a guide slide block; 53. a poking block; 54. a power supply cell; 55. a first interface; 56. a second interface; 57. a drainage through hole; 58. a power output mechanism; 59. a charging circuit mechanism; 6. and a second energy storage assembly.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The embodiment of the invention provides an energy storage unit multilayer spliced mobile power supply, which comprises a shell component 1, an isolation component 2, a first energy storage component 5 and a second energy storage component 6; as illustrated by way of example in fig. 1.

The utility model discloses a novel energy storage device for the solar energy, including casing subassembly 1, second energy storage subassembly 6, first energy storage subassembly 5, second energy storage subassembly 6, first energy storage subassembly 5 and second energy storage subassembly 6, first energy storage subassembly 5 movable joint is on the inner wall top of isolating subassembly 2, second energy storage subassembly 6 movable joint is on the inner wall bottom of isolating subassembly 2, first energy storage subassembly 5 and second energy storage subassembly 6's structure, size are the same, casing subassembly 1 is an open structure, just the top movable joint of casing subassembly 1 has casing apron 3, the axis of isolating subassembly 2 coincides with the axis of casing subassembly 1, just isolating subassembly 2 rotates to be connected at the inner wall of casing subassembly 1, one side outer wall fixedly connected with handle 4 of casing subassembly 1.

Specifically, the isolation component 2 is rotationally connected to the central axis of the shell component 1, and is used for isolating the first energy storage component 5 and the second energy storage component 6, and when the first energy storage component 5 and the second energy storage component 6 move back, or when the first energy storage component 5 and the second energy storage component 6 move in the same direction, the isolation component 2 is rotationally connected to the central axis center of the shell component 1, so that the isolation component 2 can simultaneously radiate heat and cool the first energy storage component 5 and the second energy storage component 6, and the flow speed of gas in the shell component 1 is increased, and the safety and stability of the first energy storage component 5 and the second energy storage component 6 in the discharging or charging process are improved.

The housing assembly 1 comprises a first housing 11; as illustrated by way of example in fig. 2.

Two groups of handle assembly holes 12 are formed in the outer wall of one side of the first shell 11, the two groups of handle assembly holes 12 are symmetrically arranged with the central axis of the first shell 11 as the center, the two groups of handle assembly holes 12 are movably sleeved at the end part of the handle 4, a first slot 13, a second slot 14 and two groups of first guide sliding grooves 15 are formed in the outer wall of the first shell 11, the first slot 13, the second slot 14 and the two groups of first guide sliding grooves 15 are positioned above the same horizontal line of the two groups of handle assembly holes 12, the first slot 13 and the second slot 14 are symmetrically arranged with the central axis of the first shell 11 as the center, and the two groups of first guide sliding grooves 15 are symmetrically arranged with the central axis of the first shell 11 as the center;

The outer wall of the first housing 11 is provided with a third slot 16, a fourth slot 17 and two groups of second guiding sliding grooves 18, the third slot 16, the fourth slot 17 and the two groups of second guiding sliding grooves 18 are located below the same horizontal line of the two groups of handle assembly holes 12, the third slot 16 and the fourth slot 17 are symmetrically arranged with the central axis of the first housing 11 as the center, and the two groups of second guiding sliding grooves 18 are symmetrically arranged with the central axis of the first housing 11 as the center.

Specifically, the two sets of first guiding sliding grooves 15 are used for performing a function of horizontally guiding movement on the first energy storage component 5, and when the first energy storage component 5 moves to approach the first slot 13, a discharging end of the first energy storage component 5 is inserted into the first slot 13, so that the discharging end of the first energy storage component 5 is connected with electric equipment, when the first energy storage component 5 moves to approach the second slot 14, a charging end of the first energy storage component 5 is inserted into the second slot 14, so that the charging end of the first energy storage component 5 is connected with a charger, and when the second energy storage component 6 is slidably connected in the two sets of second guiding sliding grooves 18, the discharging end or the charging end of the second energy storage component 6 is respectively inserted into the third slot 16 or the fourth slot 17, so as to discharge and charge the second energy storage component 6.

The isolation assembly 2 comprises an isolation plate 21; as illustrated by way of example in fig. 3 and 4.

The first motor 22 is embedded and installed on the outer wall of one side of the isolation plate 21, the output end of the first motor 22 is fixedly connected with the inner wall of the first shell 11, one side, far away from the first motor 22, of the outer wall of the isolation plate 21 is rotationally connected with the inner wall of the first shell 11, the magnetic absorption blocks 23 are embedded and installed at the two ends of the outer wall of the isolation plate 21, the two groups of the magnetic absorption blocks 23 are respectively and movably absorbed and connected on the shell cover plate 3, laminating groove 24 has all been seted up to the top and the bottom of division board 21, a set of laminating groove 24's inner wall is provided with first guiding mechanism 25, another set of laminating groove 24's inner wall is provided with second guiding mechanism 26, first guiding mechanism 25 and second guiding mechanism 26 all coincide with first motor 22's axis, just first guiding mechanism 25 is the same with second guiding mechanism 26's structure, shape.

The first diversion mechanism 25 comprises a diversion plate 251; as illustrated by way of example in fig. 5.

The fan 252 has been seted up on the surface of guide plate 251, two sets of magnetism adsorption columns 253 are installed in the outer wall embedding of guide plate 251, and two sets of magnetism adsorption columns 253 distribute in the top corner that is close to guide plate 251, the bottom of guide plate 251 is provided with radian base 254, the outer wall of guide plate 251 and the one side embedding that is close to radian base 254 install second motor 255, the output and the inner wall fixed connection of laminating groove 24 of second motor 255, second motor 255 and the axis coincidence of first motor 22, the outer wall of guide plate 251 just is close to the opposite side of radian base 254 and the inside rotation of laminating groove 24 are connected.

Specifically, the output end of the first motor 22 rotates to one side, and simultaneously, the isolation plate 21 rotates around the first motor 22, so that the magnetic adsorption block 23 at one end of the isolation plate 21 is adsorbed and connected to the bottom of the cover plate 3 of the housing, so that the isolation plate 21 is magnetically fixed to one side in an inclined angle, and then the isolation plate 21 is magnetically fixed to the other side in an inclined angle by rotating the output end of the first motor 22 to the other side;

the second motor 255 rotates, and simultaneously, the deflector 251 rotates around the second motor 255, and is magnetically adsorbed on the outer wall of the first energy storage component 5 or the second energy storage component 6 by using the magnetic adsorption column 253, so as to improve the stability of the fan 252 during operation, and perform the heat adsorption and the flow guiding functions on the end of the first energy storage component 5 or the second energy storage component 6 while continuously operating by using the fan 252.

The first energy storage assembly 5 comprises a second housing 51; as illustrated in fig. 6 and 7.

The second casing 51 is of an open structure, two groups of guide sliding blocks 52 are fixedly connected to the outer wall of the second casing 51, two groups of guide sliding blocks 52 are connected to the inner wall of the first guide sliding groove 15 in a sliding fit mode, two groups of guide sliding blocks 52 are fixedly connected with a stirring block 53, the stirring block 53 extends to the outer portion of the first guide sliding groove 15, a power supply electric core 54 is fixedly connected to the inner wall of the second casing 51, a first interface 55 is arranged on the outer wall of one side of the second casing 51, a second interface 56 is arranged on the outer wall of the other side of the second casing 51, a plurality of groups of drainage through holes 57 are formed in the outer wall of the second casing 51 and in the side close to the second interface 56, a power supply output mechanism 58 is arranged on the outer wall of the power supply electric core 54 and in the side close to the first interface 55, the power supply electric core 54 is electrically connected with the first interface 55 through the power supply output mechanism 58, and the power supply electric core 54 is electrically connected with the second interface 56 through the power supply output mechanism 59.

Specifically, the toggle block 53 is manually adjusted to enable the second housing 51 to horizontally move to any end of the first guide chute 15, when the first interface 55 moves into the first slot 13, the power supply battery core 54 supplies power to the electric equipment connected in the first interface 55, the second interface 56 and the second slot 14 are in a separated state and are in a state of being communicated with the fan 252 through the plurality of sets of drainage through holes 57, and the continuous cooling effect is performed on the power supply battery core 54, the power supply output mechanism 58 and the charging circuit mechanism 59 in the second housing 51 under the state that the fan 252 continuously works.

The working principle of the multilayer spliced mobile power supply with the energy storage unit provided by the embodiment of the invention is as follows:

The second shell 51 is horizontally moved to any end of the first guide chute 15 through manual adjustment by the toggle block 53, when the first interface 55 moves into the first slot 13, the power supply cell 54 supplies power to electric equipment connected in the first interface 55, the second interface 56 and the second slot 14 are in a separated state and are communicated with the fan 252 through a plurality of groups of drainage through holes 57, and the continuous cooling effect is carried out on the power supply cell 54, the power supply output mechanism 58 and the charging circuit mechanism 59 in the second shell 51 under the continuous working state of the fan 252;

The output end of the first motor 22 rotates to one side, the isolation plate 21 rotates around the first motor 22, the magnetic adsorption block 23 at one end of the isolation plate 21 is used for adsorbing and connecting the bottom of the shell cover plate 3, the isolation plate 21 is magnetically fixed to one side in an inclined angle, and the output end of the first motor 22 rotates to the other side, so that the isolation plate 21 is magnetically fixed to the other side in an inclined angle;

The deflector 251 rotates by taking the second motor 255 as the center while rotating, and is magnetically adsorbed on the outer wall of the first energy storage component 5 or the second energy storage component 6 by utilizing the magnetic adsorption column 253, so as to improve the stability of the fan 252 during working, and the end of the first energy storage component 5 or the second energy storage component 6 is adsorbed and guided by utilizing the continuous working of the fan 252.

Although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (3)

1. An energy storage unit multilayer concatenation formula portable power source, its characterized in that: comprises a shell component (1), an isolation component (2), a first energy storage component (5) and a second energy storage component (6); the shell assembly (1) is of an open structure, a shell cover plate (3) is movably clamped at the top of the shell assembly (1), the central axis of the isolation assembly (2) coincides with the central axis of the shell assembly (1), the isolation assembly (2) is rotationally connected to the inner wall of the shell assembly (1), the first energy storage assembly (5) and the second energy storage assembly (6) are both in sliding connection to the inner wall of the shell assembly (1), the first energy storage assembly (5) is movably and fixedly connected to the top end of the inner wall of the isolation assembly (2), and the second energy storage assembly (6) is movably and fixedly connected to the bottom end of the inner wall of the isolation assembly (2);

The isolation assembly (2) comprises an isolation plate (21); the top and bottom ends of the isolation plate (21) are provided with attaching grooves (24), the inner wall of one group of attaching grooves (24) is provided with a first flow guiding mechanism (25), and the first flow guiding mechanism (25) comprises a flow guiding plate (251); a fan (252) is arranged on the surface of the guide plate (251);

The housing assembly (1) comprises a first housing (11); two groups of handle assembly holes (12) are formed in the outer wall of one side of the first shell (11), the two groups of handle assembly holes (12) are symmetrically arranged with the central axis of the first shell (11) as the center, a handle (4) is fixedly connected to the outer wall of one side of the shell assembly (1), the two groups of handle assembly holes (12) are movably sleeved at the end part of the handle (4), a first slot (13), a second slot (14) and two groups of first guide sliding grooves (15) are formed in the outer wall of the first shell (11), the first slot (13), the second slot (14) and the two groups of first guide sliding grooves (15) are located above the same horizontal line of the two groups of handle assembly holes (12), the first slot (13) and the second slot (14) are symmetrically arranged with the central axis of the first shell (11) as the center, and the two groups of first guide sliding grooves (15) are symmetrically arranged with the central axis of the first shell (11) as the center;

A third slot (16), a fourth slot (17) and two groups of second guide sliding grooves (18) are formed in the outer wall of the first shell (11), the third slot (16), the fourth slot (17) and the two groups of second guide sliding grooves (18) are positioned below the same horizontal line of the two groups of handle assembly holes (12), the third slot (16) and the fourth slot (17) are symmetrically arranged by taking the central axis of the first shell (11) as the center, and the two groups of second guide sliding grooves (18) are symmetrically arranged by taking the central axis of the first shell (11) as the center;

The outer wall of one side of the isolation plate (21) is embedded and provided with a first motor (22), the output end of the first motor (22) is fixedly connected with the inner wall of the first shell (11), one side, far away from the first motor (22), of the outer wall of the isolation plate (21) is rotationally connected with the inner wall of the shell assembly (1), two ends of the outer wall of the isolation plate (21) are embedded and provided with magnetic adsorption blocks (23), and the two groups of the magnetic adsorption blocks (23) are respectively and movably adsorbed and connected on the shell cover plate (3);

The inner wall of the other group of the attaching groove (24) is provided with a second flow guiding mechanism (26), the first flow guiding mechanism (25) and the second flow guiding mechanism (26) are overlapped with the central axis of the first motor (22), and the structures and the shapes of the first flow guiding mechanism (25) and the second flow guiding mechanism (26) are the same;

Two groups of magnetic adsorption columns (253) are embedded and mounted on the outer wall of the guide plate (251), the two groups of magnetic adsorption columns (253) are distributed at the corner near the top of the guide plate (251), and the bottom of the guide plate (251) is provided with a radian bottom edge (254);

A second motor (255) is embedded and installed on one side, close to the bottom edge (254), of the outer wall of the guide plate (251), the output end of the second motor (255) is fixedly connected with the inner wall of the laminating groove (24), the second motor (255) coincides with the central axis of the first motor (22), and the other side, close to the bottom edge (254), of the outer wall of the guide plate (251) is rotationally connected with the inner part of the laminating groove (24);

The first energy storage assembly (5) comprises a second housing (51); the second shell (51) is of an open structure, two groups of guide sliding blocks (52) are fixedly connected to the outer wall of the second shell (51), the two groups of guide sliding blocks (52) are connected to the inner wall of the first guide sliding groove (15) in a sliding fit mode, stirring blocks (53) are fixedly connected to the outer wall of the guide sliding blocks (52), and the stirring blocks (53) extend to the outer portion of the first guide sliding groove (15).

2. The energy storage unit multi-layer spliced mobile power supply of claim 1, wherein: the inner wall fixedly connected with power electricity core (54) of second casing (51), the one side outer wall of second casing (51) is provided with first interface (55), just the opposite side outer wall of second casing (51) is provided with second interface (56), a plurality of drainage through-holes (57) of group have been seted up to the outer wall of second casing (51) and one side that is close to second interface (56).

3. The energy storage unit multi-layer spliced mobile power supply according to claim 2, wherein: the power supply battery cell (54) is characterized in that a power supply output mechanism (58) is arranged on the outer wall of the power supply battery cell (54) and close to one side of the first interface (55), a charging circuit mechanism (59) is arranged on the outer wall of the power supply battery cell (54) and close to one side of the second interface (56), the power supply battery cell (54) is electrically connected with the first interface (55) through the power supply output mechanism (58), and the power supply battery cell (54) is electrically connected with the second interface (56) through the charging circuit mechanism (59).