CN219504661U - Auxiliary equipment for installing energy storage equipment - Google Patents

Abstract

The utility model relates to the technical field of installation equipment, in particular to auxiliary equipment for installing energy storage equipment. An auxiliary device for mounting an energy storage device comprises a carrier, an adjusting device and an extension carrier. The bearing device is provided with a bearing table, a plurality of first rolling bodies are arranged on the bearing table, and the bearing table can move in the direction of three coordinate axes. The adjusting device comprises an adjusting piece which can move along the direction of the first coordinate axis. The extension bearing device is connected with the bearing table in a relatively telescopic manner and comprises a second rolling body. An auxiliary device for installing an energy storage device has the advantage that the position of the energy storage device can be adjusted in all directions, and the position of the energy storage device in the direction of the first coordinate axis can be accurately adjusted. The convenient energy storage equipment is moved, is convenient for be sent into the battery compartment after the energy storage equipment breaks away from the bearing device, convenient operation has reduced the manpower, has saved occupation space, avoids energy storage equipment to damage, reduces the emergence of casualties accident.

Description

Auxiliary equipment for installing energy storage equipment

Technical Field

The utility model relates to the technical field of installation equipment, in particular to auxiliary equipment for installing energy storage equipment.

Background

The new energy source greatly improves the air quality and is widely applied to various industries, but the new energy storage equipment has a complex structure, and the battery has a large volume, so that the trouble is brought to the installation of the battery. For example, battery racks are commonly provided in container-type energy storage devices, the battery rack having a plurality of battery compartments, one battery being disposed in each battery compartment. In order to accommodate a sufficient amount of batteries, the battery rack is high in height and long in length, a plurality of operators are required for manually installing the batteries, and at least two or more operators must cooperatively install one battery when installing the batteries at a high place. In the operation process, the battery is easy to fall off, so that the battery is broken, and meanwhile, casualties are caused. When hanging a wall-mounted energy storage device, more than two operators are also required to lift the device at the same time, align the hanging mechanism on the wall, and hang the energy storage device. The operation is troublesome, the hanging mechanism is not easy to align, the equipment is easy to fall off, the battery is also damaged, and meanwhile, the casualties are caused.

In order to solve the above problems, various tooling devices are now employed. For example, chinese patent publication No. CN107585547a discloses a bracket-free high-voltage battery mounting fixture, which comprises a conveying module, wherein the conveying module comprises a handle, a left support frame, a nut, a spring pad, a roller, a right support frame and a connecting rod, and the conveying module is used for conveying and mounting the high-voltage battery; the battery compartment is sleeved outside the conveying module, the battery compartment is of a hollow structure with an opening at the top, the conveying module is placed on the inner wall of the bottom of the battery compartment, a buffer module installed in the battery compartment is arranged on one side of the conveying module, and the buffer module is used for avoiding damage to the high-voltage battery due to rigid collision in the conveying process. This patent can't height-adjusting, and the direction only can be adjusted through conveying module's removal, can't realize accurate regulation, and equipment structure is complicated, and during the battery was sent into the battery compartment, the frock need get into in the battery compartment simultaneously, needs the battery compartment to have enough big space, has taken more space. After the battery enters the battery compartment, the battery cannot be completely separated from the tool, and the tool is difficult to withdraw from the battery compartment.

Disclosure of Invention

In view of the above, the present utility model aims to provide an auxiliary device for installing an energy storage device, which adopts a liftable and movable bearing device, wherein balls are arranged on a bearing table, two opposite adjusting devices are arranged on two sides of the bearing table, one end of an adjusting piece of each adjusting device is provided with an adjusting plate, the bearing table is of a hollow structure, an extension bearing device is arranged in the hollow structure, the extension bearing device can move in a telescopic manner relative to the bearing table, and the extension bearing device is provided with rolling shafts arranged side by side. The problems that the position can not be adjusted in each direction, the position adjustment is inaccurate, the operation is inconvenient, the occupied space of a battery compartment is large, the battery is difficult to send into the battery compartment, the manpower is wasted, the battery is easy to damage, the casualties are caused, and the like are solved.

To solve the above problems, the present utility model provides an auxiliary device for installing an energy storage device, comprising:

the bearing device is provided with a bearing table, a plurality of first rolling bodies are arranged on the bearing table, and the bearing table can move in the direction of three coordinate axes;

the adjusting device comprises an adjusting piece which can move along the direction of a first coordinate axis;

and the extension bearing device is connected with the bearing table in a relatively telescopic manner and comprises a second rolling body.

Further, the adjusting device further includes:

the fixing piece is fixed on the bearing table, and the adjusting piece is connected with the fixing piece in a telescopic mode.

Further, the adjusting piece comprises a screw rod and an adjusting plate, wherein the screw rod is in threaded connection with the fixing piece, and the screw rod penetrates through the fixing piece to be fixedly connected with the adjusting plate.

Further, two guide shafts are fixed on the adjusting plate, and two guide holes matched with the guide shafts are formed in the fixing piece.

Further, the two adjusting devices are oppositely arranged at the edge part of the bearing table in the first coordinate axis direction.

Further, the first rolling bodies are balls protruding out of the surface of the bearing table, and a plurality of the first rolling bodies are uniformly distributed on the bearing table.

Further, the interior of the bearing table is of a hollow structure, and an opening is formed in the side wall of the bearing table;

the extension bearing device is arranged in the hollow structure and can move in a telescopic way relative to the bearing table through the opening;

the extension bearing device comprises two sliding rods which are arranged in parallel, and the two sliding rods can slide in the hollow structure;

and the two sliding rods are connected through a plurality of second rolling bodies.

Further, the second rolling element is a rolling shaft, and a plurality of rolling shafts are arranged side by side.

Further, the carrying device further comprises:

the bottom plate is connected with the bearing table through a telescopic frame, and at least three universal wheels are fixed on the surface of the bottom plate, which is far away from the bearing table;

the driving mechanism is arranged between the bottom plate and the bearing table and drives the bearing table to move relative to the bottom plate.

Further, the telescopic frame comprises two telescopic mechanisms which are oppositely arranged;

the telescopic mechanism comprises n cross rod assemblies which are sequentially connected in a relatively rotatable manner, wherein n is an integer greater than 1;

each cross rod assembly comprises two rod pieces rotatably connected at the middle part, and the opposite end parts of each cross rod assembly are connected through a rotating shaft;

the first cross rod assembly comprises a first fixed end and a first sliding end, and the nth cross rod assembly comprises a second fixed end and a second sliding end;

two bottom plate sliding rails are oppositely arranged on the surface of the bottom plate, which is opposite to the bearing table, and two bearing table sliding rails are oppositely arranged on the surface of the bearing table, which is opposite to the bottom plate;

the first fixed end is fixed at one end of the bottom plate sliding rail, and the first sliding end slides along the bottom plate sliding rail;

the second fixed end is fixed to one end of the bearing table sliding rail, and the second sliding end slides along the bearing table sliding rail.

Compared with the prior art, the auxiliary equipment for installing the energy storage equipment has the following advantages:

this technical scheme advantage lies in through mobilizable to but height-adjusting's loading attachment is convenient for adjust the position of energy storage equipment in each direction, through setting up two relative adjusting device on the plummer, through the accurate position of adjusting device at first coordinate axis direction of adjusting energy storage equipment. Set up a plurality of balls on the plummer, make things convenient for the removal of energy storage equipment, the plummer sets up hollow structure, is equipped with extension bearing device in hollow structure's inside, extension bearing device can be flexible for the plummer, two slide bars are connected through the roll axis of arranging side by side and constitute, be convenient for the energy storage equipment to be sent into the battery compartment after breaking away from bearing device, convenient operation has reduced the manpower, has saved occupation space, avoids energy storage equipment to damage, reduces the emergence of casualties accident.

Drawings

Fig. 1 is a perspective view of an auxiliary device carrying energy storage device according to an embodiment of the present utility model;

fig. 2 is a perspective view of an auxiliary device according to an embodiment of the present utility model;

FIG. 3 is a perspective view of a carrying device according to an embodiment of the present utility model;

FIG. 4 is an exploded view of a carrier according to an embodiment of the present utility model;

fig. 5 is a perspective view of a telescopic bracket according to an embodiment of the present utility model.

Reference numerals illustrate:

100-bearing device, 110-bottom plate, 120-bearing table, 121-bearing table body, 1211-pit, 1212-hollow structure, 122-pressing plate, 1221-round hole, 123-first rolling element, 130-expansion bracket, 131-bottom plate slide rail, 132-bearing table slide rail, 133-expansion mechanism, 1331-rod piece, 1332-first sliding end, 1333-first fixed end, 1334-second sliding end, 1335-second fixed end, 134-rotating shaft, 140-driving mechanism, 150-universal wheel, 200-adjusting device, 210-fixing piece, 220-adjusting piece, 221-screw, 222-adjusting plate, 2221-guide bar, 223-crank, 300-extension bearing device, 310-slide bar, 320-second rolling element, 400-energy storage equipment.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

The description of "first," "second," "upper," "lower," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or the number of technical features indicated. Thus, a feature defining "first", "second", "upper", "lower" may include at least one such feature, either explicitly or implicitly. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to be based on the fact that those skilled in the art can implement the combination between the embodiments, and all the technical solutions are within the scope of protection claimed by the present utility model.

The utility model will be described in detail below with reference to the drawings in connection with embodiments.

As shown in fig. 1, an auxiliary device for installing an energy storage device, comprising: the carrying device 100, the adjusting device 200 and the extension carrying device 300. As shown in fig. 2 to 4, the carrying device 100 is provided with a carrying table 120, a plurality of first rolling bodies 123 are provided on the carrying table 120, and the carrying table 120 is movable in three coordinate axis directions. As shown in fig. 1 and 2, the adjusting device 200 includes an adjusting member 220, and the adjusting member 220 is movable along a first coordinate axis direction. An extension carriage 300 is relatively telescopically connected to the carriage 120, the extension carriage 300 comprising second rolling elements 320.

Specifically, the first rolling elements 123 may be rollers, balls, or the like, and as an example, it is preferable that the first rolling elements 123 be balls. The plummer includes plummer body, is equipped with a plurality of pits 1211 at the upper surface of plummer body, and the diameter of pit 1211 is slightly greater than the diameter of first rolling element 123, and the degree of depth is slightly greater than the radius of first rolling element 123. The pit 1211 has an overall shape of a cylinder and a hemispherical cylinder, which are connected tangentially to the hemispherical surface in this order from the upper surface of the stage body 121. After the balls are put into the recesses 1211, the upper surface of the table body 121 is positioned on the upper hemispherical surface of the balls. The bearing table further comprises a pressing plate 122, a plurality of round holes 1221 matched with the pits 1211 are formed in the pressing plate, and after the balls are placed in the pits 1211, the pressing plate 122 is fixed on the upper surface of the bearing table body 121. The above-structured loading table 120 can reduce friction when the energy storage device 400 placed thereon moves in various directions.

As an embodiment, when the energy storage device is a battery, the battery is placed in the battery compartment through the auxiliary device of the embodiment. Firstly, a battery is placed on the bearing table 120, the bearing device 100 is moved to the position of the bin opening of the battery bin, and the height of the bearing table 120 is adjusted, so that the condition that the upper surface of the bearing table 120 is slightly higher than the bottom plate of the battery bin to be flush is met, and the condition that the extension bearing device 130 can extend into the battery bin close to the bottom plate of the battery bin is met. The battery is moved on the stage 120 according to the installation position of the battery, the position of the battery is roughly adjusted, and then the position of the battery in the first coordinate axis direction, which is the X-axis direction, i.e., the left-right direction with respect to the battery compartment is adjusted by the adjusting device 200. After the adjustment, the extension bearing device 300 is pulled out and stretches into the battery compartment to push the battery, the battery is sent into the battery compartment, and when the front end of the battery falls onto the bottom plate of the battery compartment, the extension bearing device 300 is retracted, so that the battery falls onto the bottom plate of the battery compartment completely. Before the front end of the battery falls on the battery compartment bottom plate, in order to lighten the impact between the battery and the battery compartment bottom plate, external force can be manually applied to the battery to enable the battery to slowly fall on the battery compartment bottom plate. Similarly, when the extension carriage 300 is retracted, external force is applied to the battery so that the whole battery slowly falls on the battery compartment bottom plate.

Through the auxiliary assembly of above-mentioned structure, through mobilizable to but height-adjusting's loading attachment 100, be convenient for adjust the position of energy storage device 400 in each direction, through setting up two relative adjusting device 200 on plummer 120, accurately adjust the position of energy storage device 400 in first coordinate axis direction through adjusting device 200. The plurality of balls 123 are arranged on the bearing table 120, so that the movement of the energy storage device 400 is facilitated, the bearing table 120 is arranged into a hollow structure, the extension bearing device 300 is arranged in the hollow structure, the extension bearing device 300 can stretch and retract relative to the bearing table 120, two sliding rods 310 are connected through the rolling shafts which are arranged side by side, the energy storage device 400 is conveniently separated from the bearing device 100 and then is sent into a battery compartment, the operation is convenient, the labor is reduced, the occupied space is saved, the damage of the energy storage device 400 is avoided, and the occurrence of casualties is reduced.

Further, as shown in fig. 2, the adjusting device 200 further includes: the fixing member 210 is fixed on the carrying platform 120, and the adjusting member 220 is telescopically connected with the fixing member 210.

The position of the energy storage device is adjusted by the extension and retraction of the adjustment member 220. As an embodiment, when the energy storage device 400 is a wall-mounted energy storage device, after the wall is provided with a wall-mounted structure, the energy storage device 400 is placed on the carrying platform 120, the carrying device 100 is moved to the position of the wall-mounted structure, after the hanging piece of the energy storage device 400 is adjusted to be approximately positioned at the position of the wall-mounted structure, the hanging piece of the energy storage device 400 is finely adjusted by the expansion and contraction of the adjusting piece 220, after the position is adjusted, the energy storage device 400 is pushed, and when the hanging piece of the energy storage device 400 stretches into the wall-mounted structure, the carrying platform 120 is lowered, so that the hanging operation of the wall-mounted energy storage device 400 is completed. The operation can be completed by one operator, and the manpower is reduced. Before hanging wall-hanging energy storage equipment, bear device 100 bears energy storage equipment, prevents that energy storage equipment from droing, causes equipment damage, avoids casualties. When in suspension, due to the arrangement of the first rolling bodies 123, the friction force is reduced, and the energy storage device can be manually and easily pushed to realize suspension operation.

Further, the adjusting member 220 includes a screw 221 and an adjusting plate 222, the screw 221 is screwed with the fixing member 210, and the screw 221 is fixedly connected with the adjusting plate 222 through the fixing member 210.

The adjusting plate 222 is driven to move by the rotating screw 221, and the angle of the energy storage device 400 can be adjusted by the adjusting plate 222 so as to be parallel to the edge of the bearing table 120, so that the energy storage device 400 is prevented from deflecting in the moving process.

In order to facilitate the adjustment, a crank 223 is provided at the opposite end of the adjustment plate 222 of the screw 221.

Further, two guide shafts 2221 are fixed to the adjustment plate 222, and two guide holes that mate with the guide shafts 2221 are provided in the fixing member 210.

By providing two guide bars 2221, the movement direction of the adjustment plate 222 is ensured not to be deviated, thereby ensuring that the movement direction of the energy storage device 400 is unchanged.

Further, the adjusting devices 200 are disposed at two opposite edge portions of the stage 120 in the first coordinate axis direction.

By bi-directionally adjusting and limiting the position and direction of movement of the energy storage device 400, the energy storage device 400 can be precisely moved to the installation position.

Further, the first rolling bodies 123 are balls protruding from the surface of the bearing table 120, and a plurality of the first rolling bodies 123 are uniformly distributed on the bearing table 120.

The shape and arrangement of the first rolling elements 123 are as described above. The uniform distribution arrangement ensures that the energy storage device 400 is uniformly stressed in each part in the moving process.

Further, as shown in fig. 2 and 4, the interior of the carrying platform 120 is a hollow structure 1212, and an opening is provided on a sidewall of the carrying platform 120. The elongate carrier 300 is disposed within the hollow structure 1212 and is telescopically movable relative to the carrier 120 through the opening. The elongate carrier 300 comprises two slide bars 310 arranged in parallel, both slide bars 310 being slidable within the hollow structure 1212. Between the two slide bars 310 are connected a plurality of second rolling bodies 320.

The extension bearing 300 is disposed in a drawer structure inside the bearing 120, and when not in use, the extension bearing 300 is hidden inside the bearing 120. When the energy storage device 400 is pushed into the battery compartment, in order to avoid damage to the energy storage device and the battery compartment caused by friction between the energy storage device 400 and the bottom plate of the battery compartment, the extension carrier 300 is pulled out from the carrier 120, and friction between the extension carrier 300 and the energy storage device 400 is reduced by the second rolling bodies 320, so that the energy storage device 400 can be easily pushed into the battery compartment. In a specific manner, as described above.

Further, the second rolling element 320 is a rolling shaft, and a plurality of rolling shafts are arranged side by side.

After the position of the energy storage device 400 is adjusted on the carrying platform 120, the energy storage device is moved to the inside of the battery compartment along one direction, that is, the Y-axis direction perpendicular to the first coordinate axis (X-axis) direction, on the extension carrying device 300 by the rolling axis. Therefore, the second rolling element 320 preferably employs a plurality of rolling shafts arranged side by side.

Further, as shown in fig. 3, the carrying device 100 further includes: a base plate 110 and a drive mechanism 140. The base plate 110 is connected with the bearing table 120 through a telescopic frame 130, and at least three universal wheels 150 are fixed on the surface of the base plate 110 far away from the bearing table 120. The driving mechanism 140 is disposed between the base plate 110 and the carrying platform 120, and drives the carrying platform 120 to move relative to the base plate 110.

The height of the loading table 120 is adjusted by telescopic adjustment of the telescopic frame 130. The driving mechanism 140 is preferably an oil hydraulic device, which may be directly disposed between the base plate 110 and the carrying table 120, or may be disposed on the expansion bracket 130, and the height of the carrying table 120 is adjusted by expansion and contraction of the piston.

Further, the telescopic frame 130 includes two telescopic mechanisms 133 disposed opposite to each other. The telescoping mechanism 133 includes n sequentially relatively rotatably coupled cross bar assemblies, where n is an integer greater than 1. Each crossbar assembly includes two bars 1331 rotatably connected at a central location, with opposite ends of each crossbar assembly being connected by a rotation shaft 134. The first of the crossbar assemblies includes a first fixed end 1333 and a first sliding end 1332, and the nth of the crossbar assemblies includes a second fixed end 1335 and a second sliding end 1334. Two floor slide rails 131 are provided opposite to the surface of the floor 110 opposite to the pedestal 120, and two pedestal slide rails 132 are provided opposite to the surface of the pedestal 120 opposite to the floor 110. The first fixed end 1333 is fixed to one end of the bottom plate sliding rail 131, and the first sliding end 1332 slides along the bottom plate sliding rail 131. The second fixed end 1335 is fixed to one end of the bearing platform rail 132, and the second sliding end 1334 slides along the bearing platform rail 132.

The telescopic frame 130 with the structure supports the carrying platform 120 and adjusts the height change of the carrying platform 120.

Although the present utility model is disclosed above, the present utility model is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the utility model, and the scope of the utility model should be assessed accordingly to that of the appended claims.

Claims (10)

1. An auxiliary device for mounting an energy storage device, comprising:

the bearing device (100) is provided with a bearing table (120), a plurality of first rolling bodies (123) are arranged on the bearing table (120), and the bearing table (120) can move in the direction of three coordinate axes;

-an adjusting device (200), the adjusting device (200) comprising an adjusting member (220), the adjusting member (220) being movable in a first coordinate axis direction;

-an elongated carrier (300) being relatively telescopically connected to said carrier (120), said elongated carrier (300) comprising second rolling elements (320).

2. Auxiliary device for mounting an energy storage device according to claim 1, characterized in that the adjusting means (200) further comprises:

and the fixing piece (210) is fixed on the bearing table (120), and the adjusting piece (220) is connected with the fixing piece (210) in a telescopic way.

3. The auxiliary device for installing an energy storage device of claim 2, wherein,

the adjusting piece (220) comprises a screw rod (221) and an adjusting plate (222), the screw rod (221) is in threaded connection with the fixing piece (210), and the screw rod (221) penetrates through the fixing piece (210) to be fixedly connected with the adjusting plate (222).

4. An auxiliary device for mounting an energy storage device as defined in claim 3, wherein,

two guide shafts (2221) are fixed on the adjusting plate (222), and two guide holes matched with the guide shafts (2221) are formed in the fixing piece (210).

5. The auxiliary device for installing an energy storage device of claim 4, wherein the auxiliary device comprises a housing,

the two adjusting devices (200) are oppositely arranged at the edge part of the bearing table (120) in the first coordinate axis direction.

6. The auxiliary device for installing an energy storage device of claim 1, wherein,

the first rolling bodies (123) are balls protruding out of the surface of the bearing table (120), and the plurality of first rolling bodies (123) are uniformly distributed on the bearing table (120).

7. The auxiliary device for installing an energy storage device of claim 1, wherein,

the bearing table (120) is internally provided with a hollow structure (1212), and the side wall of the bearing table (120) is provided with an opening;

the extension bearing device (300) is arranged inside the hollow structure (1212) and can move telescopically relative to the bearing table (120) through the opening;

the extension bearing device (300) comprises two sliding bars (310) arranged in parallel, and the two sliding bars (310) can slide in the hollow structure (1212);

and the two sliding rods (310) are connected through a plurality of second rolling bodies (320).

8. The auxiliary device for mounting an energy storage device according to claim 7, wherein the second rolling element (320) is a rolling shaft, a plurality of rolling shafts being arranged side by side.

9. Auxiliary device for mounting energy storage devices according to claim 1, characterized in that the carrying means (100) further comprises:

the base plate (110) is connected with the bearing table (120) through a telescopic frame (130), and at least three universal wheels (150) are fixed on the surface of the base plate (110) far away from the bearing table (120);

and a driving mechanism (140) provided between the base plate (110) and the carrying table (120) and driving the carrying table (120) to move relative to the base plate (110).

10. Auxiliary device for mounting energy storage devices according to claim 9, characterized in that the telescopic frame (130) comprises two telescopic mechanisms (133) arranged opposite each other;

the telescopic mechanism (133) comprises n cross rod assemblies which are sequentially connected in a relatively rotatable manner, wherein n is an integer greater than 1;

each cross rod assembly comprises two rod pieces (1331) rotatably connected at the middle part, and opposite ends of each cross rod assembly are connected through a rotating shaft (134);

a first one of the crossbar assemblies comprises a first fixed end (1333) and a first sliding end (1332), and an nth one of the crossbar assemblies comprises a second fixed end (1335) and a second sliding end (1334);

two base plate slide rails (131) are oppositely arranged on the surface of the base plate (110) opposite to the bearing table (120), and two bearing table slide rails (132) are oppositely arranged on the surface of the bearing table (120) opposite to the base plate (110);

the first fixed end (1333) is fixed at one end of the bottom plate sliding rail (131), and the first sliding end (1332) slides along the bottom plate sliding rail (131);

the second fixed end (1335) is fixed at one end of the bearing table sliding rail (132), and the second sliding end (1334) slides along the bearing table sliding rail (132).