CN214744708U - Multifunctional portable energy storage structure - Google Patents

Abstract

The utility model relates to the technical field of energy storage structures, in particular to a multifunctional portable energy storage structure, which comprises a multifunctional energy storage box, supporting legs, a battery, a telescopic unit, a placing groove and a handle; four corners of the bottom end of the multifunctional energy storage box are fixedly connected with supporting legs; a battery is arranged at the bottom end inside the multifunctional energy storage box; the bottom of the supporting leg is provided with a telescopic unit; the top end of the multifunctional energy storage box is provided with a placing groove; a handle is hinged inside the placing groove; the telescopic unit comprises a moving assembly and a contraction fixing assembly; the bottom of the supporting leg is provided with a moving assembly; the outer side of the bottom of the supporting leg is provided with a contraction fixing component; and then this multi-functional energy storage box can drag through handle and walking wheel and carry to can fix this multi-functional energy storage box through the fixed subassembly of shrink when using, avoid the walking wheel to take place to remove when using, and then cause to use inconveniently.

Description

Multifunctional portable energy storage structure

Technical Field

The utility model relates to an energy storage technical field specifically is a multi-functional portable type energy storage structure.

Background

Because the energy required by people has strong timeliness and spatiality, in order to reasonably utilize the energy and improve the utilization rate of the energy, a device is needed to be used, the redundant energy which is temporarily not used in a period of time is collected and stored in a certain mode, and is extracted and used at the peak time of use or is transported to a place where the energy is in short supply for reuse, the method is just energy storage, and the energy storage box can store redundant heat energy, kinetic energy, electric energy, potential energy, chemical energy and the like, so that the output capacity, the output place and the output time of the energy are changed, and in recent years, along with the development of an energy system, a portable energy storage box appears.

In the prior art, when a traditional energy storage box is carried, the traditional energy storage box needs to be carried by means of carrying equipment and a carrying bag, however, the weight of a general energy storage box is heavier, the carrying equipment further increases the carrying weight, the carrying of the energy storage box is very inconvenient, and the use of the energy storage box also needs to be manually righted, so that the use of the energy storage box is very troublesome; therefore, a multifunctional portable energy storage structure is proposed to solve the above problems.

SUMMERY OF THE UTILITY MODEL

In order to remedy prior art's not enough, solved traditional energy storage box when carrying, need carry with the help of carrying equipment and carrying the sack, however general energy storage box weight is heavier to with carrying equipment can further aggravate the weight of carrying, and then can be very inconvenient carrying the energy storage box, and still need use the people to right in the use, use very trouble problem, the utility model provides a multi-functional portable formula energy storage structure.

A multifunctional portable energy storage structure comprises a multifunctional energy storage box, supporting legs, a battery, a telescopic unit, a placing groove and a handle; four corners of the bottom end of the multifunctional energy storage box are fixedly connected with supporting legs; a battery is arranged at the bottom end inside the multifunctional energy storage box; the bottom of the supporting leg is provided with a telescopic unit; the top end of the multifunctional energy storage box is provided with a placing groove; a handle is hinged inside the placing groove;

the telescopic unit comprises a moving assembly and a contraction fixing assembly; the bottom of the supporting leg is provided with a moving assembly; and the outer side of the bottom of the supporting leg is provided with a contraction fixing assembly.

Preferably, the moving assembly comprises a contraction groove, a telescopic sliding block, a first insertion hole, a lifting 21274, a shape connecting frame, a walking wheel and a contraction fixing assembly; the bottom ends of the supporting legs are provided with shrinkage grooves; a telescopic sliding block is arranged in the contraction groove; first inserting holes are formed in the two sides of the surface of the telescopic sliding block; the bottom end of the telescopic sliding block is fixedly connected with a v-shaped 21274; the walking wheels are rotatably connected between the bottom ends inside the v-shaped connecting frames; and a contraction fixing component is arranged outside the bottom end of the supporting leg.

Preferably, the contraction fixing component comprises a compression cavity, a first compression spring, a limiting slide block, a movable rod, a connecting block, a second inserting hole and a fixing rod; compression cavities are formed in the two ends of the front side of each supporting leg; a plurality of first compression springs which are uniformly distributed at intervals are fixedly connected to one side, close to the telescopic sliding block, in the compression cavity; a limiting sliding block is fixedly connected between the other ends of the first compression springs; one end of the limiting sliding block, which is far away from the first compression spring, is fixedly connected with a movable rod; one end of the movable rod, which is far away from the limiting slide block, penetrates through the side wall of the supporting leg and is in sliding connection with the supporting leg; one ends of the movable rods, which are far away from the supporting legs, are fixedly connected with a connecting rod together; two sides of the v-shaped connecting frame are fixedly connected with connecting blocks; the surfaces of the connecting blocks are provided with second inserting holes; the parts of the connecting rods corresponding to the first inserting holes are fixedly connected with fixing rods; one end of the fixing rod close to the multifunctional energy storage box penetrates through the supporting leg and extends into the first inserting hole, and the fixing rod is connected with the side wall of the supporting leg in a sliding mode.

Preferably, the bottom of the battery is provided with a damping component; the damping assembly comprises a damping plate, a fixed seat, an inverted V-shaped hinge rod, a roller, a sliding rail and a first damping spring; the bottom of the battery is provided with a damping plate, and the inside of the damping plate is hollow; the top end and the lower end of the damping plate are fixedly connected with the corresponding battery and the multifunctional energy storage box respectively; a fixed seat is fixedly connected to the top end of the center inside the damping plate; the bottom end of the fixed seat is hinged with an inverted V-shaped hinge rod; the two ends of the bottom of the inverted V-shaped hinge rod are provided with rollers; a sliding rail is arranged at the bottom end of the interior of the damping plate corresponding to the part of the roller, and the roller is positioned in the sliding rail and is connected with the sliding rail in a sliding manner; a first damping spring is fixedly connected between two sides of the inner portion of the bottom end of the inverted V-shaped hinge rod.

Preferably, both sides of the contraction groove are provided with limiting sliding grooves; the both sides of flexible slider all the rigid coupling have spacing pulley, and, spacing pulley is located spacing spout and with spacing spout sliding connection.

Preferably, the two sides of the top end of the damping plate are fixedly connected with second damping springs, and the bottom ends of the second damping springs are fixedly connected with the bottom ends of the corresponding damping plates.

The utility model discloses an useful part lies in:

1. the utility model discloses a removal subassembly, shrink groove, flexible slider, first insert and establish the hole, 21274, the structural design of shape link, walking wheel, compression chamber, first compression spring, spacing slider, movable rod, connecting block, second insert and establish hole and dead lever, make this multi-functional energy storage case drag and carry through handle and walking wheel, and can fix this multi-functional energy storage case through contracting fixed subassembly when using, avoid the walking wheel to take place to remove when using, and then cause and use inconveniently;

2. the utility model discloses a shock attenuation board, a fixed base, the hinge bar that falls V, the gyro wheel, slide rail and first damping spring's structural design, great vibrations appear because of external environment in multi-functional energy storage box, multi-functional energy storage box can extrude the shock attenuation board, the shock attenuation board can extrude the fixing base, and then under the effect of fixing base, the hinge bar that falls V can open to both sides in the slide rail through the gyro wheel, and first damping spring can be stimulateeed to both sides simultaneously this moment, then the hinge bar bottom that falls V is close to each other, first damping spring shrink, with this reciprocating, and then realize absorbing effect, avoid appearing great vibrations, lead to multi-functional energy storage box internals to appear damaging.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be 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 drawings without inventive exercise.

Fig. 1 is a schematic perspective view of the present invention;

FIG. 2 is a front view of the cross-sectional structure of the present invention;

FIG. 3 is a schematic cross-sectional front view A-A of FIG. 2;

FIG. 4 is a schematic top view of section A-A of FIG. 2;

FIG. 5 is an enlarged view of a portion of FIG. 2 at B;

fig. 6 is a partially enlarged schematic view of C in fig. 2.

In the figure: 1. a multifunctional energy storage box; 2. supporting legs; 3. a battery; 4. a telescopic unit; 41. a moving assembly; 411. a contraction groove; 412. a telescopic slide block; 413. a first insertion hole; 414. v 21274; a connecting frame; 415. a traveling wheel; 42. a shrink fitting assembly; 421. a compression chamber; 422. a first compression spring; 423. a limiting slide block; 424. a movable rod; 425. a connecting rod; 426. connecting blocks; 427. a second insertion hole; 428. fixing the rod; 5. a shock absorbing assembly; 501. a damper plate; 502. a fixed seat; 503. an inverted V hinge rod; 504. a roller; 505. a slide rail; 506. a first damping spring; 6. a second damping spring; 7. a limiting chute; 8. a limiting pulley; 9. a placement groove; 10. and (4) a handle.

Detailed Description

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

Referring to fig. 1-6, a portable multifunctional energy storage structure includes a multifunctional energy storage box 1, support legs 2, a battery 3, a telescopic unit 4, a placement groove 9 and a handle 10; four corners of the bottom end of the multifunctional energy storage box 1 are fixedly connected with supporting legs 2; a battery 3 is arranged at the bottom end inside the multifunctional energy storage box 1; the bottom of the supporting leg 2 is provided with a telescopic unit 4; the top end of the multifunctional energy storage box 1 is provided with a placing groove 9; a handle 10 is hinged inside the placing groove 9;

the telescopic unit 4 comprises a moving assembly 41 and a contraction fixing assembly 42; the bottom of the supporting leg 2 is provided with a moving assembly 41; the outer side of the bottom of the supporting leg 2 is provided with a contraction fixing component 42; at the during operation, this multi-functional energy storage box 1 is pulled through handle 10, and then under the effect of removal subassembly 41, remove to this multi-functional energy storage box 1 and carry, when this multi-functional energy storage box 1 is used to needs, fix this multi-functional energy storage box 1 through the fixed subassembly 42 of shrink, and then this multi-functional energy storage box 1 can drag through handle 10 and walking wheel 415 and carry, and can fix this multi-functional energy storage box 1 through the fixed subassembly 42 of shrink when using, it takes place to remove to avoid walking wheel 415 when using, and then it is inconvenient to cause the use.

As an embodiment of the present invention, the moving component 41 includes a shrinking slot 411, a shrinking slider 412, a first inserting hole 413, a shape connecting frame 414, a walking wheel 415 and a shrinking fixing component 42; the bottom ends of the supporting legs 2 are provided with shrinkage grooves 411; a telescopic sliding block 412 is arranged in the contraction groove 411; the two sides of the surface of the telescopic sliding block 412 are both provided with first inserting holes 413; the bottom end of the telescopic sliding block 412 is fixedly connected with a v-shaped 21274connecting frame 414; a walking wheel 415 is rotatably connected between the bottom ends of the inner parts of the v-shaped connecting frames 414; the outside of the bottom end of the supporting leg 2 is provided with a contraction fixing component 42; both sides of the contraction groove 411 are provided with limiting sliding grooves 7; the two sides of the telescopic sliding block 412 are fixedly connected with limiting pulleys 8, and the limiting pulleys 8 are positioned in the limiting sliding grooves 7 and are in sliding connection with the limiting sliding grooves 7; the contraction fixing component 42 comprises a compression cavity 421, a first compression spring 422, a limit slide block 423, a movable rod 424, a connecting rod 425, a connecting block 426, a second inserting hole 427 and a fixing rod 428; compression cavities 421 are formed in the two ends of the front side of the supporting leg 2; a plurality of first compression springs 422 which are uniformly distributed at intervals are fixedly connected to one side of the interior of the compression cavity 421, which is close to the telescopic sliding block 412; a limiting slide block 423 is fixedly connected between the other ends of the first compression springs 422; one end of the limiting sliding block 423 away from the first compression spring 422 is fixedly connected with a movable rod 424; one end of the movable rod 424, which is far away from the limit slide block 423, penetrates through the side wall of the supporting leg 2 and is in sliding connection with the supporting leg 2; one ends of the movable rods 424, far away from the supporting legs 2, are fixedly connected with a connecting rod 425; two sides of the v-shaped connecting frame 414 are fixedly connected with connecting blocks 426; the surface of each connecting block 426 is provided with a second inserting hole 427; a fixed rod 428 is fixedly connected to the connecting rod 425 corresponding to the first inserting hole 413; one end of the fixing rod 428 close to the multifunctional energy storage box 1 penetrates through the supporting leg 2 and extends into the first inserting hole 413, and the fixing rod 428 is connected with the side wall of the supporting leg 2 in a sliding manner; when the multifunctional energy storage box 1 needs to be carried, the multifunctional energy storage box 1 is pulled upwards through the handle 10, the multifunctional energy storage box 1 is lifted, the connecting rods 425 on the two sides are pulled outwards, the connecting rods 425 drive the movable rods 424 to move outwards at the moment, the connecting rods 425 drive the fixed rods 428 to move outwards, when the fixed rods 428 are completely separated from the second inserting holes 427, the telescopic sliding blocks 412 slide downwards until the travelling wheels 415 are in contact with the ground, then the connecting rods 425 are loosened, the fixed rods 428 are driven to be inserted into the first inserting holes 413 under the action of the resilience force of the first compression springs 422, the travelling wheels 415 are fixed at the moment, and the multifunctional energy storage box 1 can be pulled to be carried; when the use is required, the operation is the same as above.

As an embodiment of the present invention, the bottom of the battery 3 is provided with a damping component 5; the damping assembly 5 comprises a damping plate 501, a fixed seat 502, an inverted-V hinge rod 503, a roller 504, a sliding rail 505 and a first damping spring 506; the bottom of the battery 3 is provided with a damping plate 501, and the damping plate 501 is hollow; the top end and the lower end of the damping plate 501 are respectively fixedly connected with the corresponding battery 3 and the multifunctional energy storage box 1; a fixed seat 502 is fixedly connected to the top end of the center inside the damping plate 501; the bottom end of the fixed seat 502 is hinged with an inverted V-shaped hinge rod 503; the two ends of the bottom of the inverted V-shaped hinge rod 503 are provided with rollers 504; a sliding rail 505 is arranged at the bottom end of the interior of the damping plate 501 corresponding to the roller 504, and the roller 504 is positioned in the sliding rail 505 and is connected with the sliding rail 505 in a sliding manner; a first damping spring 506 is fixedly connected between the two sides of the inner part of the bottom end of the inverted V-shaped hinged rod 503; two sides of the top end of each damping plate 501 are fixedly connected with a second damping spring 6, and the bottom end of each second damping spring 6 is fixedly connected with the bottom end of the corresponding damping plate 501; at the during operation, great vibrations appear because of external environment in multi-functional energy storage box 1, multi-functional energy storage box 1 can extrude shock attenuation board 501, shock attenuation board 501 can extrude fixing base 502, and then under fixing base 502's effect, the articulated rod 503 that falls V can open to both sides in slide rail 505 through gyro wheel 504, and first damping spring 506 can be pulled to both sides simultaneously this moment, then the articulated rod 503 bottom that falls V is close to each other, first damping spring 506 shrink, with this is reciprocal, and then realize absorbing effect, avoid appearing great vibrations, lead to damage to the appearance of multi-functional energy storage box 1 internals.

The working principle is that when the multifunctional energy storage box 1 needs to be carried, the multifunctional energy storage box 1 is lifted up through the handle 10, then the connecting rods 425 on two sides are pulled outwards, at the moment, the connecting rods 425 drive the movable rods 424 to move outwards, the connecting rods 425 drive the fixed rods 428 to move outwards, when the fixed rods 428 are completely separated from the second inserting holes 427, the telescopic sliding blocks 412 slide downwards until the walking wheels 415 are in contact with the ground, then the connecting rods 425 are loosened, under the action of the resilience force of the first compression springs 422, the fixed rods 428 are driven to be inserted into the first inserting holes 413, at the moment, the walking wheels 415 are fixed, and then the multifunctional energy storage box 1 can be pulled and carried; when the multifunctional energy storage box 1 needs to be used, the fixing operation is the same as the above operation; the multifunctional energy storage box 1 generates large vibration due to the external environment, the multifunctional energy storage box 1 can extrude the damping plate 501, the damping plate 501 can extrude the fixing seat 502, the inverted V-shaped hinged rod 503 can be opened towards two sides in the sliding rail 505 through the roller 504 under the action of the fixing seat 502, the first damping spring 506 can be pulled towards two sides at the same time, the bottom ends of the inverted V-shaped hinged rods 503 are close to each other, and the first damping spring 506 contracts to reciprocate, so that the damping effect is realized, large vibration is avoided, and the damage to internal parts of the multifunctional energy storage box 1 is avoided; and then this multi-functional energy storage box 1 can drag through handle 10 and walking wheel 415 and carry to can fix this multi-functional energy storage box 1 through the fixed subassembly 42 of shrink when using, avoid walking wheel 415 to take place to remove when using, and then cause to use inconveniently.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention.

Claims (6)

1. A multi-functional portable formula energy storage structure which characterized in that: comprises a multifunctional energy storage box (1), supporting legs (2), a battery (3), a telescopic unit (4), a placing groove (9) and a handle (10); four corners of the bottom end of the multifunctional energy storage box (1) are fixedly connected with supporting legs (2); a battery (3) is arranged at the bottom end inside the multifunctional energy storage box (1); the bottom of the supporting leg (2) is provided with a telescopic unit (4); a placing groove (9) is formed in the top end of the multifunctional energy storage box (1); a handle (10) is hinged inside the placing groove (9);

the telescopic unit (4) comprises a moving assembly (41) and a contraction fixing assembly (42); the bottom of the supporting leg (2) is provided with a moving assembly (41); the outside of supporting leg (2) bottom is equipped with shrink fixed subassembly (42).

2. The multifunctional portable energy storage structure of claim 1, wherein: the moving component (41) comprises a contraction groove (411), a telescopic sliding block (412), a first inserting hole (413), a Y-shaped connecting frame (414), a walking wheel (415) and a contraction fixing component (42); the bottom ends of the supporting legs (2) are provided with shrinkage grooves (411); a telescopic sliding block (412) is arranged in the contraction groove (411); two sides of the surface of the telescopic sliding block (412) are provided with first inserting holes (413); the bottom end of the telescopic sliding block (412) is fixedly connected with a V-shaped connecting frame (414); a travelling wheel (415) is rotatably connected between the bottom ends of the inner parts of the v-shaped connecting frames (414); and a contraction fixing component (42) is arranged outside the bottom end of the supporting leg (2).

3. The multifunctional portable energy storage structure of claim 2, wherein: the contraction fixing component (42) comprises a compression cavity (421), a first compression spring (422), a limiting sliding block (423), a movable rod (424), a connecting rod (425), a connecting block (426), a second inserting hole (427) and a fixing rod (428); compression cavities (421) are formed in the two ends of the front side of the supporting leg (2); a plurality of first compression springs (422) which are uniformly distributed at intervals are fixedly connected to one side, close to the telescopic sliding block (412), in the compression cavity (421); a limiting sliding block (423) is fixedly connected between the other ends of the first compression springs (422) together; one end of the limiting sliding block (423) far away from the first compression spring (422) is fixedly connected with a movable rod (424); one end of the movable rod (424), which is far away from the limiting slide block (423), penetrates through the side wall of the supporting leg (2) and is in sliding connection with the supporting leg (2); one end of the movable rod (424) far away from the supporting leg (2) is fixedly connected with a connecting rod (425); two sides of the v-shaped connecting frame (414) are fixedly connected with connecting blocks (426); the surfaces of the connecting blocks (426) are provided with second inserting holes (427); the parts of the connecting rods (425) corresponding to the first inserting holes (413) are fixedly connected with fixing rods (428); one end of the fixing rod (428) close to the multifunctional energy storage box (1) penetrates through the supporting leg (2) and extends into the first inserting hole (413), and the fixing rod (428) is connected with the side wall of the supporting leg (2) in a sliding mode.

4. A multifunctional portable energy storage structure as recited in claim 3, wherein: the bottom of the battery (3) is provided with a damping component (5); the damping assembly (5) comprises a damping plate (501), a fixed seat (502), an inverted V-shaped hinge rod (503), a roller (504), a sliding rail (505) and a first damping spring (506); the bottom of the battery (3) is provided with a damping plate (501), and the damping plate (501) is hollow; the top end and the lower end of the damping plate (501) are fixedly connected with the corresponding battery (3) and the multifunctional energy storage box (1) respectively; a fixed seat (502) is fixedly connected to the top end of the center inside the damping plate (501); the bottom end of the fixed seat (502) is hinged with an inverted V-shaped hinge rod (503); both ends of the bottom of the inverted V-shaped hinge rod (503) are provided with rollers (504); a sliding rail (505) is arranged at the bottom end of the interior of the damping plate (501) and corresponds to the part of the roller (504), and the roller (504) is positioned in the sliding rail (505) and is connected with the sliding rail (505) in a sliding manner; a first damping spring (506) is fixedly connected between two sides of the inner portion of the bottom end of the inverted V-shaped hinge rod (503).

5. The multifunctional portable energy storage structure of claim 4, wherein: two sides of the contraction groove (411) are both provided with limiting sliding grooves (7); both sides of the telescopic sliding block (412) are fixedly connected with limiting pulleys (8), and the limiting pulleys (8) are positioned in the limiting sliding grooves (7) and are in sliding connection with the limiting sliding grooves (7).

6. The multifunctional portable energy storage structure of claim 5, wherein: the both sides on shock attenuation board (501) top all the rigid coupling have second damping spring (6), and the bottom of second damping spring (6) and the shock attenuation board (501) bottom rigid coupling that corresponds.

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