A vortex pool water pump motor cable support
By designing a cable support bracket for the vortex pool water pump motor and utilizing components such as a main board, connecting groove, and screw, the height of the cable can be adjusted, solving the problems of inconvenient maintenance and grounding short circuits caused by burying the cable underground, and improving the safety and convenience of the system.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 新余钢铁股份有限公司
- Filing Date
- 2025-08-04
- Publication Date
- 2026-07-07
AI Technical Summary
The existing cyclone pool pump motor cable is buried underground, which makes replacement and maintenance inconvenient, causes poor heat dissipation, and is prone to electrical faults such as grounding short circuits, affecting system safety.
A cable support for a vortex pool water pump motor is designed, which uses components such as a main board, connecting groove, screw, moving plate, connecting plate, bottom support plate and top cover plate. The height of the cable can be adjusted and fixed by rotating the screw, which avoids burying the cable underground, enhances heat dissipation and prevents grounding short circuit.
This allows for convenient height adjustment of the cable, improving system safety and maintenance convenience, preventing grounding short circuits caused by water accumulation on the ground, and ensuring stable operation of the water pump.
Smart Images

Figure CN224473003U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of vortex pool water pump technology, and more specifically, it relates to a vortex pool water pump motor cable bracket. Background Technology
[0002] As a key facility in water treatment systems in industries such as metallurgy and chemical engineering, cyclone separators play a crucial role in wastewater sedimentation and recycling. The stable operation of the pump motor directly affects the continuity of the production process and environmental compliance. However, traditionally, cyclone separator pump motor cables are mostly laid in underground cable conduits. With the increasing standards of industrial automation and safety production, the shortcomings of this method in terms of maintenance convenience, safety, and environmental adaptability have become increasingly apparent. In existing technologies, the cyclone separator pump motor cables are buried underground for extended periods, leading to inconvenience in replacement and maintenance, poor heat dissipation, and the connection points are prone to electrical faults such as grounding short circuits caused by water accumulation at ground contact points. In the event of a power outage or other emergency, if the water level rises and overflows the ground-level cable, the pump will immediately stop working, causing the cyclone separator water level to become uncontrollable, which in turn can lead to equipment damage and production safety accidents.
[0003] Existing technology includes a designation titled "A Motor Bracket for an Ultra-High-Speed Water Pump," with publication number CN113809880B. This technology relates to a motor bracket for an ultra-high-speed water pump. The motor bracket has a centrally located main shaft bearing housing and is cylindrical. Pump housing mounting flanges and motor mounting flanges are located at the top and bottom of the motor bracket, respectively. A rectangular reinforcing base plate is located on the outer center of the motor bracket. A bearing housing mounting platform is located on the inner side of the motor bracket at the location of the reinforcing base plate. The cavity between the motor mounting flange and the bearing housing mounting platform is an assembly cavity, and the cavity between the pump housing mounting flange and the bearing housing mounting platform is a vibration damping cavity. Four rectangular assembly openings are circumferentially located on the outer wall of the assembly cavity. Bearing housing fixing holes are located at both ends of the side of the reinforcing base plate. The main objective of this invention is to fix the main shaft bearing and prevent displacement of the main shaft bearing housing due to high-speed pump shaft rotation. The reinforcing base plate enhances the torsional resistance of the overall motor bracket, and the spring damping device within the vibration damping cavity reduces the Z-axis vibration of the pump shaft. However, this technology does not address the technical problems and solutions of this application. Utility Model Content
[0004] The technical problem to be solved by this utility model is to provide a simple structure for the vortex pool pump motor cable bracket, which is convenient for staff to adjust the height of the cable according to changes in water level, avoids the problems of inconvenience in replacement and maintenance and poor heat dissipation caused by burying the cable underground, and avoids electrical faults such as grounding short circuits caused by water accumulation at the connection point, thereby improving the safety of the system.
[0005] To solve the above-mentioned technical problems, the technical solution adopted by this utility model is as follows:
[0006] This utility model is a cable bracket for a vortex pool water pump motor. The main board is provided with a connecting groove that runs through the main board. A screw is installed in the connecting groove. A movable plate is screwed onto the screw. The movable plate is connected to a connecting plate. The connecting plate is connected to a bottom support plate. The bottom support plate is connected to a top cover plate.
[0007] The motherboard is connected to the bracket mounting components via a mounting bracket.
[0008] Each side of the base plate is provided with an outwardly extending arc-shaped groove, and both the top cover plate and the base plate are provided with arc-shaped grooves.
[0009] The bottom support plate has an inverted T-shaped limiting groove on the top of each side, and the bottom of each side of the top cover plate has an I-shaped connecting block that can be movably connected to the limiting groove.
[0010] The top of the screw is fixed with a rotating disk, which has a polygonal structure.
[0011] A micro motor is fixed to the top of the screw, and the micro motor is fixedly connected to the main board.
[0012] A reinforcing plate is provided between the connecting plate and the bottom support plate, and the connecting plate has a Z-shaped structure.
[0013] The bottom of the base plate has a groove, inside which a guide rod is installed. A rotating plate connected to an arc-shaped groove plate is movably sleeved on the outside of the guide rod. A torsion spring sleeved on the outside of the guide rod is installed between the side of the rotating plate and the inner wall of the groove.
[0014] The motherboard has a side inclined plate on its side, and a roller is movably disposed on one side of the arc-shaped groove plate to contact the inclined surface of the side inclined plate.
[0015] The connecting plate has multiple ball bearings movably embedded on its side.
[0016] The working principle and beneficial effects of this utility model are as follows:
[0017] The cyclone pool water pump motor cable bracket described in this utility model Attached Figure Description
[0018] The following is a brief explanation of the contents depicted in the accompanying drawings and the markings therein:
[0019] Figure 1 This is a schematic diagram of the overall structure of the vortex pool water pump motor cable bracket;
[0020] Figure 2 This is a structural schematic diagram of the main board, the lifting self-adjusting component, and the upper cover plate of this utility model;
[0021] Figure 3 This is a schematic diagram of the lifting self-adjusting component and the main board of this utility model;
[0022] Figure 4 This is an exploded structural diagram of the top cover plate, I-beam plate, and bottom support plate of this utility model;
[0023] Figure 5 This is a schematic diagram of the structure of the arc-shaped groove plate, torsion spring, roller and side inclined plate of this utility model;
[0024] Figure 6 This is a schematic diagram of the connecting plate and ball bearings of this utility model;
[0025] The labels in the attached diagram are as follows: 1. Main board; 2. Arc-shaped groove plate; 3. Base plate; 4. Top cover plate; 5. Lifting self-adjusting assembly; 51. Rotary disk; 52. Screw; 53. Slide groove; 54. Connecting plate; 55. Connecting groove; 56. Reinforcing plate; 57. Groove; 58. Side inclined plate; 59. Rotating plate; 510. Torsion spring; 511. Guide rod; 512. Slider; 513. Moving plate; 514. Roller; 6. Mounting bracket; 7. Connecting block; 8. Limiting groove; 9. Ball bearing. Detailed Implementation
[0026] The following description, with reference to the accompanying drawings, provides a more detailed explanation of the specific embodiments of this utility model, including the shape and structure of each component, the relative positions and connections between the parts, the functions and working principles of each part:
[0027] As attached Figure 1 -Appendix Figure 6As shown, this utility model is a cable bracket for a vortex pool water pump motor. The main board 1 has a connecting groove 55 passing through it. A screw 52 is installed in the connecting groove 55, and a movable plate 513 is screwed onto the screw 52. The movable plate 513 is connected to a connecting plate 54, which in turn is connected to a base plate 3. The base plate 3 is connected to an upper cover plate 4. This structure addresses the shortcomings of existing technologies by proposing an improved technical solution. In this structural design, the main board 1 and the bracket mounting components are connected to fix the bracket. This fixed bracket is the basis for the operation of the lifting self-adjusting component 5. The lifting self-adjusting component 5 includes a screw 52, a movable plate 513, a connecting plate 54, a base plate 3, and an upper cover plate 4. The connecting groove 55 is vertically arranged. By rotating the screw, the movable plate 513 can be raised and lowered, which in turn drives the base plate 3 to rise and fall. The upper cover plate 4 is connected to the base plate 3, so the upper cover plate 4 rises and falls synchronously with the base plate 3. The base plate 3 is connected to the top cover plate 4, and the two are used to clamp the cable, so that the cable is located on the ground. When the water level changes, the staff can adjust the height of the base plate 3 and the top cover plate 4 according to the water level change. The vortex pool water pump motor cable bracket of this utility model has a simple structure, which makes it easy for the staff to adjust the height of the cable according to the water level change. It avoids the problems of inconvenience in replacement and maintenance and poor heat dissipation that exist when the cable is buried underground. It also avoids electrical faults such as grounding short circuits caused by water accumulation at the joint, thereby improving the safety of the system.
[0028] The motherboard 1 is connected to the bracket mounting component via the mounting bracket 6. In this structure, the bracket mounting component is fixedly installed, the motherboard is fixedly installed, and the base plate 3 can be height adjusted.
[0029] Each side of the bottom support plate 3 is provided with an outwardly extending arc-shaped groove plate 2, and both the top cover plate 4 and the bottom support plate 3 are provided with arc-shaped grooves. In this structure, the arc-shaped grooves of the top cover plate 4 and the bottom support plate 3 form a cable receiving cavity, which can better fit the outer surface of the cable, effectively restraining the cable and preventing cable movement. The arc-shaped groove plates 2 support the cable from both sides, preventing excessive bending angles when the cable rises, reducing the bending angle of the cable, and thus preventing damage to the cable after prolonged bending, which could lead to water ingress.
[0030] The bottom support plate 3 has an inverted T-shaped limiting groove 8 on the top of each side, and the top cover plate 4 has an I-shaped connecting block 7 on the bottom of each side that can be movably connected to the limiting groove 8. With this structure, the connecting block 7 can be engaged with the limiting groove 8, facilitating the connection between the bottom support plate 3 and the top cover plate 4 and ensuring reliable cable restraint. Pushing the top cover plate 4 to one side relative to the bottom support plate 3 allows for separation of the top cover plate 4 and the bottom support plate 3.
[0031] A rotating disk 51 is fixed to the top of the screw 52. The rotating disk 51 has a polygonal structure. In the above structure, as embodiment 1, the rotating disk 52 can be rotated using a wrench. The rotation of the rotating disk 52 drives the screw 52 to rotate synchronously, which in turn drives the moving plate 513 on the outer surface of the screw 52 to rise or fall. The movement of the moving plate 513 drives the bottom support plate 3 to rise or fall.
[0032] A micro motor is fixed to the top of the screw 52, and the micro motor is fixedly connected to the main board 1. In embodiment 2, the rotating disk 52 is replaced with a micro motor, and the rotation of the screw is controlled electronically, which is more convenient and allows for flexible control and adjustment of the speed.
[0033] A reinforcing plate 56 is provided between the connecting plate 54 and the base plate 3. The connecting plate 54 has a U-shaped structure. In this structure, the moving plate 513 is controlled from both the front and rear sides by the connecting groove 55. When the screw rotates, it can only move up and down relative to the main plate, and will not rotate. The special shape of the connecting plate 54 allows it to slide on the outer surface of the main plate 1 and drives the base plate 3 to move. The reinforcing plate 56 can increase the connection strength between the base plate 3 and the U-shaped plate 54.
[0034] The bottom of the base plate 3 has a groove 57, inside which a guide rod 511 is installed. A rotating plate 59, connected to the arc-shaped groove plate 2, is movably sleeved on the outside of the guide rod 511. A torsion spring 510, sleeved on the outside of the guide rod 511, is installed between the side of the rotating plate 59 and the inner wall of the groove 57. The side of the main plate 1 has a side inclined plate 58, and a roller 514, which contacts the inclined surface of the side inclined plate 58, is movably installed on one side of the arc-shaped groove plate 2. The above structure allows the curved trough plate 2 to move by raising the bottom support plate 3. Both the bottom support plate 3 and the curved trough plate 2 move the cable when they rise. The bottom support plate 3 at this point and the next or previous one have the bending angle of the cable, which increases especially when rising. By sliding the roller 514 on the inclined surface of the side plate 58, the curved trough plate 2 can be forced to self-adjust its angle, thereby raising the curved trough plate 2 and reducing the bending angle of the cable, thus reducing the risk of water ingress. Moreover, the side plate 58 can be installed according to different situations. By using the opposite inclined surface, the opposite angle reduction can be achieved. Users can replace different side plates 58 according to the usage situation. When using the device of this utility model, firstly, the upper cover plate 4 and the bottom support plate 3 are lifted. First, rotate the rotating disk 51. The rotating disk 51 will drive the screw 52 at the end to rotate. The screw 52 will drive the moving plate 513 to slide up and down inside the connecting groove 55. The moving plate 513 drives the slider 512 connected to the moving plate 513 to slide inside the sliding groove 53 that is connected to the connecting groove 55. The movement of the moving plate 513 can drive the Z-shaped connecting plate 54 connected to the end of the slider 512 to move. The connecting plate 54 will drive the bottom support plate 3 and the upper cover plate 4 to move, raising the cable and preventing water from contacting it. At this time, the arc-shaped groove plate 2 will also rise synchronously with the bottom support plate 3, and drive the roller 514 to contact the inclined surface of the side inclined plate 58. Since the arc-shaped groove plate 2 drives the roller 514 to rise forcibly, and the side inclined plate 58 has a longer horizontal length, it will drive the arc-shaped groove plate 2 to rotate, thereby reducing the bending angle of the cable and effectively protecting the cable.
[0035] The connecting plate 54 has multiple balls 9 movably embedded in its side. With this structure, when the connecting plate 54 is raised or lowered, the balls 9 act on the inclined surface of the main plate 1, thereby reducing friction.
[0036] The vortex pool water pump motor cable bracket of this utility model is structurally designed such that the main board 1 and the bracket mounting components are connected to fix the bracket. This fixed bracket is the basis for the operation of the lifting self-adjusting component 5. The lifting self-adjusting component 5 includes a screw 52, a moving plate 513, a connecting plate 54, a bottom support plate 3, and an upper cover plate 4. The connecting groove 55 is vertically arranged. By rotating the screw, the moving plate 513 can be raised and lowered, which in turn drives the bottom support plate 3 to rise and fall. The upper cover plate 4 is connected to the bottom support plate 3, so the upper cover plate 4 rises and falls synchronously with the bottom support plate 3. The bottom support plate 3 and the upper cover plate 4 are connected together to clamp the cable, keeping the cable above ground. When the water level changes, the operator can adjust the height of the connection between the bottom support plate 3 and the upper cover plate 4 accordingly.
[0037] The present invention has been described above with reference to the accompanying drawings. Obviously, the specific implementation of the present invention is not limited to the above-described manner. Any improvements made using the inventive concept and technical solution of the present invention, or the direct application of the inventive concept and technical solution to other situations without modification, are all within the protection scope of the present invention.
Claims
1. A raceway pump motor cable support characterized by: The main plate (1) is provided with a connecting groove (55) penetrating the main plate (1), a screw rod (52) is arranged in the connecting groove (55), a moving plate (513) is screwed on the screw rod (52), the moving plate (513) is connected with a connecting plate (54), the connecting plate (54) is connected with a bottom supporting plate (3), and the bottom supporting plate (3) is connected with an upper cover plate (4).
2. The raceway pump motor cable support of claim 1, wherein: The main plate (1) is connected with the support mounting component through the mounting frame (6).
3. The raceway pump motor cable support of claim 1 or 2, wherein: The bottom supporting plate (3) is provided with an arc-shaped groove plate (2) extending outward on each side, and the upper cover plate (4) and the bottom supporting plate (3) are both provided with an arc-shaped groove.
4. The raceway pump motor cable support of claim 1 or 2, wherein: The top of each side of the bottom supporting plate (3) is provided with a reverse T-shaped limiting groove (8), and the bottom of each side of the upper cover plate (4) is provided with a I-shaped connecting block (7) movably connected with the limiting groove (8).
5. The raceway pump motor cable support of claim 1 or 2, wherein: The top of the screw rod (52) is fixed with a rotating disc (51), and the rotating disc (51) is a polygonal structure.
6. The raceway pump motor cable support of claims 1 or 2, wherein: The top of the screw rod (52) is fixed with a micro motor, and the micro motor is fixedly connected with the main plate (1).
7. The raceway pump motor cable support of claim 1, wherein: The connecting plate (54) and the bottom supporting plate (3) are provided with a reinforcing plate (56), and the connecting plate (54) is a Chinese character-shaped structure.
8. The raceway pump motor cable support of claims 1 or 2, wherein: The bottom of the bottom supporting plate (3) is provided with a groove (57), the inside of the groove (57) is provided with a guide rod (511), the outside of the guide rod (511) is movably sleeved with a rotating plate (59) connected with the arc-shaped groove plate (2), and the side of the rotating plate (59) and the inner wall of the groove (57) are provided with a torsional spring (510) sleeved on the outside of the guide rod (511).
9. The raceway pump motor cable support of claim 8, wherein: The side of the main plate (1) is provided with a side inclined plate (58), and one side of the arc-shaped groove plate (2) is movably provided with a roller (514) in contact with the inclined surface of the side inclined plate (58).
10. The raceway pump motor cable support of claims 1 or 2, wherein: The side of the connecting plate (54) is movably embedded with a plurality of rolling balls (9).