CN217720337U - A spring hydraulic silo with shock absorbing structure of power distribution cabinet - Google Patents

Abstract

The utility model relates to a switch board shock attenuation transportation technology field, and a switch board shock-absorbing structure's spring hydraulic pressure storehouse is disclosed, including damping device, damping device includes switch board and spring hydraulic pressure storehouse, the switch board is installed on spring hydraulic pressure storehouse top, the switch board includes magnetism and inhales the piece, magnetism is inhaled the piece and is installed in switch board inner wall bottom, spring hydraulic pressure storehouse includes the damping, hydraulic spring, the connecting plate, a bearing, the spring post, the cardboard, the buckle, the socle, the rotor plate, the wheel hub socle, the walking wheel, the fixed column, connecting rod and baffle, damping is installed in spring hydraulic pressure storehouse top, hydraulic spring installs in the damping top, the connecting plate is installed in the hydraulic spring top, the bearing is installed in the connecting plate inner wall, the spring post is installed in the bearing inner wall, the cardboard is installed in spring capital end, the buckle is installed in the cardboard bottom, the socle is installed in spring hydraulic pressure storehouse bottom. This switch board shock-absorbing structure's spring hydraulic pressure storehouse possesses shock attenuation and transportation and advantage such as convenient when placing.

Description

A spring hydraulic chamber with a shock absorbing structure for a power distribution cabinet

technical field

The utility model relates to the technical field of shock-absorbing transportation for power distribution cabinets, in particular to a spring hydraulic chamber with a shock-absorbing structure for power distribution cabinets.

Background technique

Power distribution cabinets are divided into power distribution cabinets, lighting distribution cabinets and metering cabinets, and are the final equipment of the power distribution system. The power distribution cabinet is a general term for the motor control center. The power distribution cabinet is used in the occasions where the load is relatively dispersed and there are few circuits; the motor control center is used in the occasions where the load is concentrated and there are many circuits. They distribute the electric energy of a certain circuit of the upper-level power distribution equipment to the nearest load. This level of equipment should provide protection, monitoring and control for the load, but the existing power distribution cabinets are rigidly connected to the ground or the wall, and some of the components will generate relative vibration during transportation or installation. In addition, the power distribution cabinet Vibration will occur under the condition of external interference, so that the internal components will become loose after a long time due to vibration, which requires frequent maintenance.

Utility model content

(1) Solved technical problems

Aiming at the deficiencies of the prior art, the utility model provides a spring hydraulic chamber with a shock-absorbing structure for a power distribution cabinet, which has the advantages of shock-absorbing and convenient transportation and placement, and solves the above-mentioned technical problems.

(2) Technical solution

In order to achieve the above purpose, the utility model provides the following technical solutions: a spring hydraulic chamber of a shock absorbing structure for a power distribution cabinet, including a shock absorbing device, and the shock absorbing device includes a power distribution cabinet and a spring hydraulic chamber, and the power distribution cabinet Installed on the top of the spring hydraulic chamber;

The power distribution cabinet includes a magnetic block, and the magnetic block is installed at the bottom of the inner wall of the power distribution cabinet;

The spring hydraulic chamber includes a damper, a hydraulic spring, a connecting plate, a bearing, a spring column, a clamping plate, a buckle, a foot column, a rotating plate, a wheel hub foot column, a walking wheel, a fixed column, a connecting rod and a baffle plate. Installed on the top of the spring hydraulic chamber, the hydraulic spring is installed on the top of the damping, the connecting plate is installed on the top of the hydraulic spring, the bearing is installed on the inner wall of the connecting plate, the spring column is installed on the inner wall of the bearing, and the clamping plate is installed on the The top of the spring column, the buckle is installed at the bottom of the clamping plate, the foot column is installed at the bottom of the spring hydraulic chamber, the rotating plate is installed at the side end of the foot column, and the wheel hub foot column is installed at the side end of the traveling wheel. The walking wheel is installed on the inner end of the rotating plate, the fixed column is installed on the side end of the walking wheel, the connecting rod is installed on the top of the fixed column, and the baffle plate is installed on the side end of the foot column.

Preferably, the dampers are arranged in multiple groups, and are uniformly and fixedly installed on the top of the spring hydraulic chamber, and the hydraulic spring is fixedly installed on the top of the damping.

Through the above technical solutions, the existing power distribution cabinets are rigidly connected to the ground or the wall, and some of the devices will generate relative vibrations during transportation or installation. In addition, the power distribution cabinets will If the vibration is not restricted, it will cause the electronic components inside to fall off. Therefore, a hydraulic spring is installed on the top of the spring hydraulic chamber, and damping is set at the same time. When the hydraulic spring is deformed, it can be slowly retracted to achieve the purpose of shock absorption. .

Preferably, the connecting plate is fixedly installed on the top of the hydraulic spring, the bearings are arranged in multiple groups, and are evenly clamped on the inner wall of the connecting plate, the spring column is fixedly connected to the inner wall of the bearing, and the clamping plate is fixedly installed on the top of the spring column , the buckles are arranged in multiple groups, and are uniformly and fixedly installed on the bottom of the clamping plate.

Through the above technical scheme, the clamping plate is first inserted into the through groove opened at the bottom of the power distribution cabinet, and then the clamping plate is rotated through the bearing, and locked with the buckle and the spring column, so that the gap between the power distribution cabinet and the spring hydraulic chamber Closely connected, when it vibrates, the first shock absorption is performed through the spring column, and the force is transmitted to the connecting plate, so that the hydraulic spring is compressed by force, so as to achieve a good shock absorption effect, and at the same time cooperate with the upper damping to make the power distribution cabinet Shaking does not occur by itself.

Preferably, the magnetic block is fixedly embedded in the bottom end of the inner wall of the power distribution cabinet.

Through the above technical solution, when the clamping plate rotates, when the buckle rotates to the top of the magnetic block, the magnetic block attracts the buckle and cooperates with the spring column to complete locking.

Preferably, multiple sets of the feet are arranged, and they are uniformly and fixedly installed on the bottom of the spring hydraulic chamber, the rotating plate is fixed on the side ends of the feet, the hub feet are fixed on the side ends of the traveling wheels, and the walking The wheel is fixedly connected to the inner end of the rotating plate.

Through the above technical solution, when transporting large power distribution cabinets, it would be time-consuming and labor-intensive to carry them manually. Therefore, the walking wheels are installed on the side ends of the feet. When transported to the installation site, the driving wheels are parallel to the ground by rotating the rotating plate , so that the hub foot column touches the ground, thus completing the transportation placement.

Preferably, the fixed column is fixedly installed on the side end of the traveling wheel, the connecting rod is plugged into the top end of the fixed column, and the baffle is fixedly installed on the side end of the foot column during transportation.

Through the above technical solution, the connecting rod is inserted into the slot hole at the side end of the fixed column, and at the same time, the upper end is against the baffle, so that the walking wheel is stable in the vertical direction when rolling, and when placed, the connecting rod is inserted into the top of the fixed column In the slot hole, make it perpendicular to the ground and keep the support stable.

Compared with the prior art, the utility model provides a spring hydraulic chamber with a shock-absorbing structure of the power distribution cabinet, which has the following beneficial effects:

1. The spring hydraulic chamber of the shock-absorbing structure of the power distribution cabinet is rigidly connected to the ground or wall in the existing power distribution cabinet. Some of the components will generate relative vibration during transportation or installation. Insert the clamping plate into the through slot opened at the bottom of the power distribution cabinet, and then rotate the clamping plate through the bearing. When the buckle turns to the top of the magnetic block, the magnetic block absorbs the buckle and cooperates with the spring column to complete the locking, so that The power distribution cabinet is closely connected with the spring hydraulic chamber. When it vibrates, the first shock absorption is performed through the spring column, and the force is transmitted to the connecting plate, so that the hydraulic spring is compressed by force, so as to achieve a good shock absorption effect. , and at the same time cooperate with the damping so that the power distribution cabinet itself does not shake.

2. The spring hydraulic chamber of the shock-absorbing structure of the power distribution cabinet is time-consuming and labor-intensive if it is transported manually in a large power distribution cabinet. Therefore, the walking wheels are installed on the side of the foot column, and the connecting rod is inserted It is connected to the slot hole at the side end of the fixed column, and at the same time, the upper end is against the baffle, so that the running wheel is stable in the vertical direction when rolling. It is plugged into the slot on the top of the fixed column, so that the hub foot column touches the ground, thus completing the transportation and placement.

Description of drawings

Fig. 1 is the schematic diagram of the structure damping device of the present utility model;

Fig. 2 is the schematic diagram of the front view of the structural damping device of the present invention;

Fig. 3 is a partially enlarged schematic diagram of A of the structural damping device of the present invention.

Among them: 1. Shock absorbing device; 2. Power distribution cabinet; 3. Magnetic block; 4. Spring hydraulic chamber; 5. Damping; 6. Hydraulic spring; 7. Connecting plate; 8. Bearing; 9. Spring column; 10 1, clamping plate; 11, buckle; 12, foot column; 13, rotating plate; 14, hub foot column; 15, walking wheel; 16, fixed column; 17, connecting rod; 18, baffle plate.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of them. example. Based on the embodiments of the present utility model, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the scope of protection of the present utility model.

Please refer to Figure 1-3, a spring hydraulic chamber with a shock-absorbing structure for a power distribution cabinet, including a shock-absorbing device 1, and the shock-absorbing device 1 includes a power distribution cabinet 2 and a spring hydraulic chamber 4, and the power distribution cabinet 2 is installed on the spring hydraulic chamber 4 top;

The power distribution cabinet 2 includes a magnetic block 3, and the magnetic block 3 is installed at the bottom of the inner wall of the power distribution cabinet 2;

The spring hydraulic chamber 4 includes a damper 5, a hydraulic spring 6, a connecting plate 7, a bearing 8, a spring column 9, a clamping plate 10, a buckle 11, a foot column 12, a rotating plate 13, a wheel hub foot column 14, a traveling wheel 15, and a fixed column 16. The connecting rod 17 and the baffle 18, the damping 5 is installed on the top of the spring hydraulic chamber 4, the hydraulic spring 6 is installed on the top of the damping 5, the connecting plate 7 is installed on the top of the hydraulic spring 6, the bearing 8 is installed on the inner wall of the connecting plate 7, and the spring column 9 is installed on the inner wall of the bearing 8, the clamping plate 10 is installed on the top of the spring column 9, the buckle 11 is installed on the bottom of the clamping plate 10, the foot column 12 is installed on the bottom end of the spring hydraulic chamber 4, and the rotating plate 13 is installed on the side end of the foot column 12 , the hub foot post 14 is installed on the side end of the walking wheel 15, the walking wheel 15 is installed on the inner end of the rotating plate 13, the fixed column 16 is installed on the side end of the walking wheel 15, the connecting rod 17 is installed on the top of the fixed column 16, and the baffle plate 18 is installed on the Foot column 12 side ends.

Specifically, the damping 5 is set in multiple groups, and is evenly and fixedly installed on the top of the spring hydraulic chamber 4, and the hydraulic spring 6 is fixed on the top of the damping 5. The advantage is that the existing power distribution cabinets are rigidly connected to the ground or the wall. Some of the devices will produce relative vibration during transportation or installation. In addition, the power distribution cabinet will vibrate when it is subject to external interference. If it is not restricted, it will cause the electronic components inside to fall off. Therefore, in its spring hydraulic pressure A hydraulic spring 6 is provided at the top of the warehouse 4, and a damper 5 is provided at the same time, so that the hydraulic spring 4 can be retracted slowly when it deforms, so as to achieve the purpose of shock absorption.

Specifically, the connecting plate 7 is fixedly installed on the top of the hydraulic spring 6, the bearings 8 are arranged in multiple groups, and are evenly clamped on the inner wall of the connecting plate 7, the spring column 9 is fixedly connected to the inner wall of the bearing 8, and the clamping plate 10 is fixedly installed on the top of the spring column 9 , multiple sets of buckles 11 are provided, and they are evenly and fixedly installed on the bottom of the clamping plate 10. The advantage is that the clamping plate 10 is first inserted into the through groove opened at the bottom of the power distribution cabinet 2, and then the clamping plate 10 is rotated through the bearing 8 , cooperate with the buckle 11 and the spring column 9 to lock, so that the power distribution cabinet 2 and the spring hydraulic chamber 4 are closely connected. When it vibrates, the first shock absorption is performed through the spring column 9 to transmit the force The connecting plate 7 compresses the hydraulic spring 6 to achieve a good shock absorption effect, and at the same time cooperates with the damper 5 so that the power distribution cabinet 2 itself does not shake.

Specifically, the magnetic block 3 is fixedly embedded in the bottom end of the inner wall of the power distribution cabinet 2. The advantage is that when the clamping plate 10 rotates, when the buckle 11 rotates above the magnetic block 3, the magnetic block 3 will hold the buckle 11 cooperates with spring column 9 to complete locking.

Specifically, the feet 12 are arranged in multiple groups, and are evenly and fixedly installed on the bottom of the spring hydraulic chamber 4, the rotating plate 13 is fixed on the side ends of the feet 12, the hub feet 14 are fixed on the side ends of the walking wheels 15, and the walking wheels 15 It is fixedly connected to the inner end of the rotating plate 13. The advantage is that when transporting a large power distribution cabinet, it is time-consuming and labor-intensive to carry it manually. Therefore, the walking wheel 15 is installed on the side end of the foot column 12. Rotating the rotating plate 13 makes the traveling wheels 15 parallel to the ground, so that the hub feet 14 contact the ground, thereby completing transportation and placement.

Specifically, the fixed column 16 is fixedly installed on the side end of the walking wheel 15, the connecting rod 17 is inserted into the top of the fixed column 16, and the baffle plate 18 is fixedly installed on the side end of the foot column 12. The advantage is that the connecting rod is inserted into the In the slotted hole of fixed column 16 side ends, upper end is against baffle plate 18 simultaneously, makes walking wheel 15 stable on the vertical direction when rolling, when placing, connecting rod 17 is plugged in the slotted hole of fixed column 16 tops, Make it perpendicular to the ground and keep the support stable.

When in use, first extend the card board 10 into the through groove provided at the bottom of the power distribution cabinet 2, and then make the card board 10 rotate through the bearing 8. When the buckle 11 turns to the top of the magnetic block 3, the magnetic block 3 Suction the buckle 11 and cooperate with the spring column 9 to complete the locking, so that the power distribution cabinet 2 and the spring hydraulic chamber 4 are tightly connected. When it vibrates, the first shock absorption is performed through the spring column 9 to transmit the force The connecting plate 7 compresses the hydraulic spring 6 to achieve a good shock absorption effect. At the same time, it cooperates with the damper 5 so that the power distribution cabinet 2 itself does not shake. When transporting a large power distribution cabinet, it is time-consuming to carry it manually force, so the walking wheels 15 are installed on the side ends of the foot posts 12, and the connecting rods are inserted into the slots at the side ends of the fixed posts 16 during transportation, and the upper end is against the baffle plate 18, so that the walking wheels 15 are vertical when rolling. The direction is stable. When transported to the installation site, the running wheel 15 is parallel to the ground by rotating the rotating plate 13, and the connecting rod 17 is inserted into the slot at the top of the fixed column 16, so that the hub foot column 14 contacts the ground, thereby Complete shipping placement.

Although the embodiments of the present invention have been shown and described, those skilled in the art can understand that various changes and modifications can be made to these embodiments without departing from the principle and spirit of the present invention , replacements and modifications, the scope of the present utility model is defined by the appended claims and their equivalents.

Claims (6)

1. A spring hydraulic chamber of a shock-absorbing structure of a power distribution cabinet, comprising a shock-absorbing device (1), characterized in that: the shock-absorbing device (1) includes a power distribution cabinet (2) and a spring hydraulic chamber (4), The distribution cabinet (2) is installed on the top of the spring hydraulic chamber (4); The power distribution cabinet (2) includes a magnetic block (3), and the magnetic block (3) is installed at the bottom end of the inner wall of the power distribution cabinet (2); The spring hydraulic chamber (4) includes a damper (5), a hydraulic spring (6), a connecting plate (7), a bearing (8), a spring column (9), a clamping plate (10), a buckle (11), a foot Column (12), rotating plate (13), wheel hub foot column (14), walking wheel (15), fixed column (16), connecting rod (17) and baffle plate (18), described damper (5) is installed on The top of the spring hydraulic chamber (4), the hydraulic spring (6) is installed on the top of the damper (5), the connecting plate (7) is installed on the top of the hydraulic spring (6), and the bearing (8) is installed on the connecting plate ( 7) Inner wall, the spring column (9) is installed on the inner wall of the bearing (8), the clamping plate (10) is installed on the top of the spring column (9), and the buckle (11) is installed on the bottom of the clamping plate (10) end, the foot column (12) is installed on the bottom end of the spring hydraulic chamber (4), the rotating plate (13) is installed on the side end of the foot column (12), and the hub foot column (14) is installed on the walking wheel ( 15) side end, the road wheel (15) is installed on the inner end of the rotating plate (13), the fixed column (16) is installed on the side end of the road wheel (15), and the connecting rod (17) is installed on the fixed column (16) top, and described baffle plate (18) is installed on foot post (12) side end. 2. The spring hydraulic chamber of the shock absorbing structure of the power distribution cabinet according to claim 1, characterized in that: the damping (5) is provided with multiple groups, and is evenly fixed and installed on the top of the spring hydraulic chamber (4), so that The hydraulic spring (6) is fixedly installed on the top of the damping (5). 3. The spring hydraulic chamber of the shock absorbing structure of the power distribution cabinet according to claim 1, characterized in that: the connecting plate (7) is fixedly installed on the top of the hydraulic spring (6), and the bearing (8) is set Multiple groups, and evenly clamped on the inner wall of the connecting plate (7), the spring column (9) is fixedly connected to the inner wall of the bearing (8), the clamping plate (10) is fixedly installed on the top of the spring column (9), the The buckles (11) are arranged in multiple groups, and are evenly and fixedly installed on the bottom of the clamping plate (10). 4. The spring hydraulic chamber of the shock-absorbing structure of the power distribution cabinet according to claim 1, characterized in that: the magnetic block (3) is fixedly embedded in the bottom end of the inner wall of the power distribution cabinet (2). 5. The spring hydraulic chamber of the shock-absorbing structure of the power distribution cabinet according to claim 1, characterized in that: the foot column (12) is provided with multiple groups, and is evenly fixed and installed on the bottom of the spring hydraulic chamber (4) , the rotating plate (13) is fixedly installed on the side end of the foot column (12), the hub foot column (14) is fixedly installed on the side end of the walking wheel (15), and the walking wheel (15) is fixedly connected to the rotating plate (13) Inner end. 6. The spring hydraulic chamber of the shock-absorbing structure of the power distribution cabinet according to claim 1, characterized in that: the fixed column (16) is fixedly installed on the side end of the traveling wheel (15), and the connecting rod (17 ) is plugged into the top of the fixed column (16), and the baffle plate (18) is fixedly installed on the side end of the foot column (12).

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