CN220683799U - Optical fiber machine room storage battery transfer device - Google Patents

Abstract

The application discloses optic fibre computer lab battery transfer device. The optical fiber machine room storage battery transfer device comprises: lifting unit, first storage subassembly and electromagnetic component, lifting unit include stand, lifting belt and baffle, and the stand sets up perpendicularly on ground, and the lifting belt sets up inside the stand, and the baffle is connected the stand and is provided with the motor, and the motor is connected with the lifting belt. The first storage component comprises a lifting plate and a roller, wherein the lifting plate is connected with the lifting belt, and the roller is arranged in the lifting plate. The electromagnetic assembly comprises electromagnetic rods which are symmetrically arranged. Install optic fibre computer lab battery transfer device to optic fibre computer lab battery storage battery mounting bracket department, the motor drives the lifter plate of connecting on the lifter strap and slides to the battery department that needs demolish, and the electromagnetic lever adsorbs corresponding division board, and the manual work is passed the battery to lifter plate roller department, and the battery slides to baffle department along with the rotation of roller, slides lifter plate to ground, reduces artifical transport, when improving work efficiency, reduces the probability of occurrence of potential safety hazard.

Description

Optical fiber machine room storage battery transfer device

Technical Field

The utility model belongs to the technical field of storage battery transportation, and particularly relates to a storage battery transportation device for an optical fiber machine room.

Background

With the rapid development of information technology and computer networks in recent years, the power of most UPS devices is gradually increased, which also results in an increase in the average stand-alone power density of the devices. The increase in power density of UPS systems places a burden on the cooling performance of the system and the power performance of the battery, and the increase in battery power is to accommodate the increasing power requirements of current UPS systems, so that high-power series batteries will become a necessary choice for future UPS system backup power sources.

The high-power storage batteries used in groups are required to be reliably placed in the use process due to the large number of storage batteries, high power and large discharge current. The high-power storage battery (for example, a 12V communication valve-controlled sealed lead-acid storage battery, the weight of which is 44kg when the rated capacity is 100Ah and the weight of which is 80kg when the rated capacity is the first storage component 200 Ah) used by the UPS is generally more than 44kg when the rated capacity is larger, and the storage battery mounting frame has a certain height. An adult can move 20 kg-40 kg of heavy objects placed in the mid-air, and in the process of installation, moving or dismantling, the high-power storage battery can be lifted by matching with more than 2 workers, and the risk of dropping and smashing injury easily occurs, so that the risk of manually installing, moving or dismantling the storage battery is high, and the working efficiency is low.

Disclosure of Invention

Based on the above, it is necessary to provide a fiber optic machine room storage battery transfer device for solving the problems of high risk and low working efficiency of manually installing, moving or removing the storage battery.

In order to achieve the above purpose, the present utility model adopts the following scheme:

optical fiber computer lab battery transfer device includes:

the lifting assembly comprises at least two upright posts, at least two lifting belts and a baffle, and the upright posts are arranged perpendicular to the ground; the lifting belt is arranged inside the upright post; the baffle is connected with the upright post, and a motor is arranged on the baffle; the motor is connected with the lifting belt; the first storage component comprises a lifting plate and rollers, the lifting plate is fixedly connected with the lifting belt, the lifting plate is connected with the upright post in a buckling manner, and a plurality of rollers are arranged in the lifting plate; the electromagnetic assembly comprises electromagnetic rods, wherein at least two electromagnetic rods are arranged and symmetrically arranged above the lifting plate and close to the lifting assembly.

Preferably, the electromagnetic rod is provided with a telescopic rod, and the telescopic rod stretches and contracts along the horizontal direction of the lifting plate.

Preferably, the electromagnetic assembly further comprises at least four fixing rods, wherein the fixing rods are arranged on the upper side and the lower side of the electromagnetic rod, and the length of the fixing rods is larger than that of the lifting plate.

Preferably, the lifting plate is arranged perpendicular to the upright, and the lifting plate slides on the upright along with the lifting belt.

Preferably, the lifting plate is provided with a vertical plate horizontal to the upright post, and the vertical plate is fixedly connected with the lifting plate and is provided with a boss.

Preferably, the stand column and the lifting plate are connected with each other by a clamping groove, and the clamping grooves are connected with the T-shaped bosses on the stand plate in a clamping manner.

Preferably, the storage device further comprises a second storage plate and a third storage plate arranged below the second storage plate, wherein the second storage plate is fixedly connected with the upright post and is arranged far away from the first storage plate.

Preferably, the third storage plate is fixedly connected with the upright post, the setting direction is the same as that of the second storage plate, and a plurality of rollers are arranged on the second storage plate and the third storage plate.

Preferably, the lifting assembly further comprises a support column, the support column is connected with the second storage plate, the upright column and the third storage plate, and the support column is provided with a first angle.

Preferably, a bearing, wheels and a motor are arranged below the third storage plate, the motor is connected with the bearing, a sensor is arranged on the motor, and the sensor controls the motor to run positively and negatively.

The technical scheme that this application adopted can reach following beneficial effect:

install optic fibre computer lab battery transfer device to optic fibre computer lab battery mounting bracket department, open the motor of installing on the baffle, the motor drives the lifter plate of connecting on the lifter strap and slides to the battery department that needs demolish, the electromagnetism pole is circular telegram, inhale corresponding division board on the electromagnetism pole, pass battery to lifter plate roller department by the staff, the rotation of roller is followed to the battery, slide to baffle department stop, the mechanized battery of moving is realized to ground to the slip lifter plate, reduce artifical transport, when improving work efficiency, reduce the probability of occurrence of potential safety hazard.

Drawings

Fig. 1 is a schematic diagram of a storage battery transferring device of an optical fiber machine room disclosed in an embodiment of the present application;

fig. 2 is a schematic connection diagram of a first storage component and an electromagnetic component of the optical fiber machine room storage battery transferring device disclosed in the embodiment of the present application;

fig. 3 is a schematic diagram of a lifting assembly of a storage battery transferring device in an optical fiber machine room according to an embodiment of the present application;

fig. 4 is a schematic connection diagram of a lifting assembly and a first storage assembly of a storage battery transferring device in an optical fiber machine room according to an embodiment of the present disclosure;

wherein: lifting assembly 100, upright 110, baffle 130, motor 131, support column 140, lifting belt 150, first storage assembly 200, lifting plate 210, roller 220, upright 230, boss 231, clamping groove 232, electromagnetic assembly 300, electromagnetic rod 310, telescoping rod 320, fixed rod 330, second storage plate 400, third storage plate 500, bearing 600, wheel 610, brake motor 620.

Description of the embodiments

In order to facilitate an understanding of the present application, a more complete description of the present application will now be provided with reference to the relevant figures. Preferred embodiments of the present application are shown in the accompanying drawings. This application may, however, be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It should be noted that when one device is considered to be "connected" to another device, it may be directly connected to the other device or there may be an intervening device present at the same time. The terms "inner," "top," "upper," "lower," and the like are used herein for descriptive purposes only and not to represent the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 and 4, in one embodiment, a fiber optic equipment room storage battery transfer device is provided, including: the lifting assembly 100, the first storage assembly 200 and the electromagnetic assembly 300, wherein the lifting assembly 100 comprises at least two upright posts 110, at least two lifting belts 150 and a baffle 130, the upright posts 110 are arranged vertically on the ground, the lifting belts 150 are arranged inside the upright posts 110, the baffle 130 is connected with the upright posts 110, a motor 131 is arranged on the baffle 130, and the motor 131 is connected with the lifting belts 150; the first storage assembly 200 includes a lifting plate 210 and rollers 220, the lifting plate 210 is fixedly connected with the lifting belt 150, the lifting plate 210 is in snap connection with the upright post 110, and a plurality of rollers 220 are arranged in the lifting plate 210; the electromagnetic assembly 300 includes electromagnetic rods 310, where at least two electromagnetic rods 310 are symmetrically disposed above the lifting plate 210 near the lifting assembly 100. For example, two stand columns 110 are arranged, a storage battery is arranged between the stand columns 110, the lifting belt 150 is arranged inside the stand columns 110, the motor 131 is connected with the lifting belt 150, the lifting plate 210 is welded and connected in a clamping groove 232 of the lifting belt 150, a plurality of rollers 220 are arranged inside the lifting plate 210, the optical fiber storage battery transferring device is arranged at the optical fiber storage battery installing frame, the motor 131 arranged on the baffle 130 is started, the motor 131 drives the lifting plate 210 connected on the lifting belt to slide to a storage battery position needing to be removed, the electromagnetic rod 310 is electrified, the corresponding separation plate is absorbed on the electromagnetic rod 310, the storage battery is pushed to the roller 220 of the lifting plate 210 by a worker, the storage battery is rotated along with the rollers 220 and slides to the baffle 130 to stop, the storage battery is mechanically moved by sliding the lifting plate 210 to the ground, manual transportation is reduced, the working efficiency is improved, and the occurrence probability of potential safety hazards is reduced.

Further, the electromagnetic rod 310 is provided with a telescopic rod 320, and the telescopic rod 320 is telescopic along the horizontal direction of the lifting plate 210. For example, two electromagnetic rods 310 are arranged, the positions of the electromagnetic rods 310 are the same as the distance between magnets on the partition plates in the installation frame of the storage battery pack of the optical fiber machine room, the electromagnetic rods 310 are provided with telescopic rods 320, the telescopic rods 320 extend out of the lifting plates 210 and coincide with the magnets on the partition plates in the installation frame of the storage battery pack of the optical fiber machine room, the partition plates are removed after the electromagnetic rods 310 are electrified, the telescopic rods 320 retract, when the partition plates are installed, the telescopic rods 320 extend out, the partition plates are installed in situ, a power supply is turned off, the telescopic rods 320 do not have magnetic force, after the installation is completed, the telescopic rods 320 retract, the process of manually removing the partition plates is reduced, and therefore the improvement of the working efficiency is achieved.

Specifically, the electromagnetic assembly 300 further includes at least four fixing rods 330, and the fixing rods 330 are disposed on the upper and lower sides of the electromagnetic rod 310 and have a length greater than that of the lifting plate 210. For example, when the partition plates are removed by electrifying the telescopic rod 320, the partition plates are connected by buckling and can drive the displacement of the upper and lower adjacent partition plates when sliding out, so that the partition plates cannot be installed when being installed back to the original position, in order to solve the phenomenon, the upper and lower sides of the electromagnetic rod 310 are respectively provided with one fixing rod 330, the length of each fixing rod 330 is greater than that of the lifting plate 210, the distance between the two fixing rods 330 is greater than that of a single partition plate, when the electromagnetic rod 310 removes the partition plates, the fixing rods 330 respectively prop against the upper and lower adjacent partition plates, when the partition plates are still kept at the original position after being removed, the fixing rods 330 play a positioning role when the partition plates are installed, so that the installation of the partition plates on the telescopic rod 320 is more convenient, the manual reset of the partition plates is reduced, and the working efficiency is improved.

In one embodiment, the lifting plate 210 is disposed perpendicular to the upright 110 in order to allow for easy operation, and the lifting plate 210 slides on the upright 110 following the lifting belt 150. For example, the upright post 110 is perpendicular to the ground and is disposed at a position close to the optical fiber machine room storage battery mounting frame, the lifting plate 210 is perpendicular to the upright post 110, and one side of the lifting plate 210, which is far away from the upright post 110, is just on one side of the optical fiber machine room storage battery mounting frame, the lifting plate 210 is welded with the clamping groove 232 of the lifting belt 150, the lifting belt 150 drives the lifting plate 210 to slide up and down, and a worker moves the storage battery onto the lifting plate 210, and the lifting belt 150 drives the lifting plate 210 to slide down to the ground, so that mechanical moving is realized, the manual moving process from a high position to the ground is reduced, the working efficiency is improved, and the occurrence probability of potential safety hazards is reduced.

Further, the lifting plate 210 is provided with a vertical plate 230 horizontal to the upright post 110, and the vertical plate 230 is fixedly connected to the lifting plate 210 and is provided with a T-shaped boss 231. For example, the lifting plate 210 and the lifting belt 150 have a smaller connection contact area and limited load bearing capacity, in order to ensure that the expected load bearing capacity is increased, a vertical plate 230 is arranged on one side of the lifting plate 210, which is close to the upright post 110, the vertical plate 230 and the lifting plate 210 are integrally arranged, a T-shaped boss 231 is arranged on the vertical plate 230, the vertical plate 230 is connected with the lifting belt 150, and the connection contact area is increased, so that the expected load bearing capacity is increased, the service life is prolonged, and the safety performance of the storage battery transferring device of the optical fiber machine room is enhanced.

Specifically, a clamping groove 232 is disposed on the connection side of the upright post 110 and the lifting plate 210, and the clamping groove 232 is in snap connection with a T-shaped boss 231 on the upright plate 230. For example, the lifting plate 210 is connected to the lifting belt 150, when the lifting plate 210 slides up and down, the lifting belt 150 drives the lifting plate 210 to shake back and forth, so that the storage battery placed on the lifting plate 210 slides or falls, in order to consider lifting safety, a clamping groove 232 is formed on one side of the upright post 110, which is close to the upright plate 230, and the clamping groove 232 is in snap connection with a T-shaped boss 231 formed on the upright plate 230, and a limiter is arranged at the top of the upright post 110, and in the process of sliding up and down, the clamping groove 232 and the T-shaped boss 231 perform front and back limiting and up and down limiting, so that the problem of shaking back and forth of the lifting plate 210 is solved, and the safety of the storage battery transferring device of the optical fiber machine room is improved.

In a specific embodiment, to allow for convenience of storage, the storage device further includes a second storage plate 400 and a third storage plate 500 disposed below the second storage plate 400, where the second storage plate 400 is fixedly connected to the upright 110 and is disposed away from the first storage plate. For example, the second storage plate 400 and the third storage plate 500 are disposed at the lower portion of the upright post 110, the distance between the second storage plate 400 and the third storage plate 500 is greater than the height of a single storage battery, the direction in which the second storage plate 400 is disposed is opposite to the direction in which the first storage plate is disposed relative to the upright post 110, when the lifting plate 210 carries the storage battery to slide down to the position of the second storage plate 400, an operator pushes the storage battery to move the storage battery to the position of the second storage plate 400, the lifting plate 210 repeats the above operation again, carries the second storage battery to slide down to the position of the third storage plate 500, the operator pushes the storage battery to move the storage battery to the position of the third storage plate 500, and then the removed storage battery is transported to a designated position at one time by using a trolley, so that the single time for transporting the storage battery is reduced, and the working efficiency is improved.

Further, the third storage plate 500 is fixedly connected to the upright post 110, the setting direction is the same as that of the second storage plate 400, and the plurality of rollers 220 are disposed on the third storage plate 500 and the third storage plate 40. For example, the third storage plate 500 is disposed in the same direction as the second storage plate 400, and a plurality of rollers 220 are disposed in the second storage plate 400 and the third storage plate 500, when the lifting plate 210 slides down to the second storage plate 400, an operator pushes the storage battery, and the storage battery rotates on the rollers 220 and slides to the inner side of the second storage plate 400, so that the same work is repeated, the time for the operator to push the storage battery is reduced, and the working efficiency is improved.

Specifically, the lifting assembly 100 further includes a support column 140, the support column 140 connects the second storage plate 400, the upright 110 and the third storage plate 500, and the support column 140 is provided with a first angle. For example, the lifting plate 210, the second storage plate 400 and the third storage plate 500 are all connected with the vertical rod, the stability of the vertical rod is difficult to ensure, the stability and the safety of the optical fiber storage battery transferring device are not considered, the lifting assembly 100 further comprises the supporting columns 140, the supporting columns 140 are connected with the vertical rod and the second storage plate 400, and are provided with an inclination angle of 60 degrees, the second storage plate 400 is vertically supported and connected with the third storage plate 500, the stability of the optical fiber storage battery transferring device is enhanced, the safety performance of the optical fiber storage battery transferring device is improved, and the service life of the optical fiber storage battery transferring device is prolonged.

More specifically, a bearing 600, wheels 610 and a brake motor 620 are disposed below the third storage plate 500, the brake motor 131 is connected with the bearing 600, and a sensor is disposed on the motor 620, and the sensor controls the brake motor 620 to operate positively and negatively. For example, two bearings 600 are disposed below the third storage plate 500, wheels 610 are disposed on two sides of the bearings 600, a brake motor 620 is disposed at one side of the bearings 600, a sensor is disposed on the brake motor 620, storage batteries are stored on the lifting plate 210, the second storage plate 400 and the third storage plate 500, the brake motor 620 is controlled by a remote controller to perform forward and reverse operations, the optical fiber machine room storage battery transfer device is moved to a designated position, and the process of transferring the optical fiber machine room storage battery transfer device to a trolley is reduced, so that the working efficiency is improved, and the occurrence probability of potential safety hazards is reduced.

The above-described embodiments only represent ways of arranging the apparatus of the present application, which are described more specifically and in detail, but are not to be construed as limiting the scope of the claims; it should be noted that it is possible for those skilled in the art to make several adjustments and improvements without departing from the concept of the present application, which all fall within the protection scope of the present application; accordingly, the scope of protection of the present application is to be determined by the claims appended hereto.

Claims (10)

1. Optical fiber computer lab battery transfer device, its characterized in that includes:

the lifting assembly comprises at least two upright posts, at least two lifting belts and a baffle, and the upright posts are arranged perpendicular to the ground; the lifting belt is arranged inside the upright post; the baffle is connected with the upright post, and a motor is arranged on the baffle; the motor is connected with the lifting belt;

the first storage component comprises a lifting plate and rollers, the lifting plate is fixedly connected with the lifting belt, the lifting plate is in buckling connection with the upright post, and a plurality of rollers are arranged in the lifting plate; and

the electromagnetic assembly comprises electromagnetic rods, wherein at least two electromagnetic rods are arranged and symmetrically arranged above the lifting plate and close to the lifting assembly.

2. The optical fiber machine room storage battery transferring device according to claim 1, wherein the electromagnetic rod is provided with a telescopic rod, and the telescopic rod stretches and contracts along the horizontal direction of the lifting plate.

3. The optical fiber machine room storage battery transferring apparatus as claimed in claim 2, wherein the electromagnetic assembly further comprises at least four fixing rods, the fixing rods are arranged on the upper side and the lower side of the electromagnetic rod, and the length of the fixing rods is greater than that of the lifting plate.

4. A fiber optic enclosure battery transfer apparatus as recited in claim 1, wherein the lifter plate is disposed perpendicular to the upright and the lifter plate slides on the upright following the lifter belt.

5. The optical fiber unit room storage battery transferring apparatus as claimed in claim 4, wherein the lifting plate is provided with a vertical plate horizontal to the upright post, and the vertical plate is fixedly connected with the lifting plate and is provided with a boss.

6. The battery transfer device of claim 5, wherein the side of the upright post connected with the lifting plate is provided with a clamping groove, and the clamping groove is in clamping connection with a boss on the upright plate.

7. The fiber optic enclosure battery transfer arrangement of claim 1, further comprising a second storage plate and a third storage plate disposed below the second storage plate, the second storage plate being fixedly connected to the post and disposed in a direction away from the first storage assembly.

8. The storage battery transferring device of the optical fiber machine room according to claim 7, wherein the third storage plate is fixedly connected with the upright post, the setting direction is the same as that of the second storage plate, and a plurality of rollers are arranged on the second storage plate and the third storage plate.

9. The fiber optic enclosure battery transfer apparatus of claim 7, wherein the lift assembly further comprises a support column connecting the second storage plate, the column, and the third storage plate, and wherein the support column is provided with a first angle.

10. The optical fiber machine room storage battery transfer device according to claim 9, wherein a bearing, wheels and a motor are arranged below the third storage plate, the motor is connected with the bearing, a sensor is arranged on the motor, and the sensor controls the motor to run positively and negatively.