A bearing housing bracket

By coordinating the detection components and the remote control center, the height of the bearing housing is automatically adjusted, solving the alignment problem between the center hole of the bearing housing and the bearing during installation, thus achieving a highly efficient and intelligent installation process.

CN224433168UActive Publication Date: 2026-06-30HENAN JUNDING MACHINERY EQUIPMENT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HENAN JUNDING MACHINERY EQUIPMENT CO LTD
Filing Date
2025-07-02
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

In existing technologies, the center hole of the bearing housing cannot be accurately aligned with the bearing during installation, requiring continuous manual adjustment, which leads to low installation efficiency.

Method used

The system employs a detection component and a remote control center. The detection component collects data on the bearing offset direction, which is then transmitted to the remote control center for identification and judgment. The control center then adjusts the height of the bearing housing by controlling the support component to align the center hole with the center of the bearing body mounting end.

Benefits of technology

This enables intelligent installation of bearing housings, improving installation efficiency and reducing the need for manual adjustments.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224433168U_ABST
    Figure CN224433168U_ABST
Patent Text Reader

Abstract

This utility model relates to the field of bearing housing technology and discloses a bearing housing bracket, including a bearing housing body and a support assembly. The bearing housing body is installed on top of the support assembly, and a track is provided at the bottom of the support assembly. A placement frame is provided in the middle of the track, and a bearing body is placed on the placement frame. The bearing housing body is provided with a central circular hole for the bearing body to pass through, and detection components are evenly arranged on the circumference of the central circular hole. In this utility model, the data on the offset direction of the bearing body is collected by the detection components and transmitted to a remote control center. The remote control center identifies and judges the offset direction, and issues a command to the support assembly based on the judgment result, thereby driving the bearing housing to rise and fall, adjusting the center height of the central circular hole to align it with the center of the bearing body mounting end, thus improving installation efficiency.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of bearing housing technology, and in particular to a bearing housing bracket. Background Technology

[0002] Bearing housing supports are key components in mechanical systems used to support and fix bearing housings. Their design directly affects the operational stability, lifespan, and maintenance costs of the equipment. With the development of industry and intelligent manufacturing, supports will evolve towards lightweight, intelligent, and green designs, providing stronger support for the efficient and reliable operation of equipment.

[0003] Chinese utility model patent application number 202122693491.0 discloses a bearing housing bracket, including a base and a support plate. The support plate is embedded inside the base, and a double-threaded screw is rotatably connected inside the base. Threaded sleeves are threaded onto both ends of the double-threaded screw, and a support rod is movably connected to the top of the threaded sleeves. The other end of the support rod is hinged to the bottom of the support plate. Fixing blocks are fixedly installed on both the left and right ends of the top of the support plate. A sliding groove is opened on the upper end of the fixing block, and sliding columns are slidably connected to both the front and rear ends of the sliding groove. A fixing clamp is fixedly installed between the tops of two sliding columns on the same side. By using the handle, double-threaded screw, threaded sleeve, support rod, and support plate in combination, the height of the bearing housing can be adjusted, improving the efficiency of the assembly equipment and meeting different usage requirements, thus improving the performance of the equipment.

[0004] However, in this technical solution, during the process of aligning the central hole of the bearing housing with the bearing during installation, it is impossible to accurately align the two. The staff needs to continuously adjust the height of the bearing housing to align it with the center of the bearing installation end. The adjustment process is not intelligent and the installation efficiency is low.

[0005] Therefore, it is necessary to solve the above problems by using a bearing housing bracket. Utility Model Content

[0006] The purpose of this utility model is to provide a bearing housing bracket to solve the problems mentioned in the background art.

[0007] To achieve the above objectives, the present invention provides the following technical solution: a bearing housing bracket, comprising a bearing housing and a support assembly, wherein the bearing housing is mounted on the top of the support assembly, a track is provided at the bottom of the support assembly, a placement frame is provided in the middle of the track, a bearing body is placed on the placement frame, and a central circular hole is provided on the bearing housing for the bearing body to pass through, and detection components are evenly arranged on the circumference of the central circular hole.

[0008] It also includes a remote control center, which is electrically connected to the electronic components in the support assembly and the detection assembly, respectively.

[0009] Preferably, the detection assembly includes a telescopic column, a spring, and a detection plate, with the spring and the detection plate respectively disposed at both ends of the telescopic column, and one end of the spring fixedly connected to the bearing housing.

[0010] Preferably, a blind hole is provided on the outer side of the central circular hole of the bearing housing, and the spring and telescopic column are disposed in the blind hole. One end of the spring is fixedly connected to the inner end of the blind hole, and the other end is fixedly connected to the end of the telescopic column. One end of the telescopic column extends to the outside of the blind hole and is connected to the detection plate.

[0011] Preferably, the support assembly includes a movable plate, on which electric hydraulic cylinders are evenly arranged. The output end of each electric hydraulic cylinder is fixedly provided with a placement platform, and the placement platform is provided with a fixing buckle for fixing the bearing housing.

[0012] Preferably, the bottom surface of the movable plate is provided with an array of movable wheels, and a dual-output motor is provided at either end of the bottom surface of the movable plate. The dual-output motor is fixed to the bottom of the movable plate by a mounting bracket, and the output end of the dual-output motor is connected to the movable wheels.

[0013] Preferably, the movable wheel has an annular groove along its circumference, and the track has a protrusion that engages with the annular groove, allowing the movable wheel to travel along the track.

[0014] The technical effects and advantages of this utility model are as follows:

[0015] 1. In this utility model, after the data of the offset direction of the bearing body is collected by the detection component, it is transmitted to the remote control center. The remote control center identifies and judges the offset direction, and issues an instruction to the support component based on the judgment result, thereby driving the bearing box to rise and fall, adjusting the center height of the central hole so that it is aligned with the center of the bearing body mounting end, thereby improving the installation efficiency.

[0016] 2. In this utility model, by setting a spring, a telescopic column, and a detection plate, after the end of the bearing body abuts against the detection plate, the detection plate compresses the spring through the telescopic column. The amount of spring compression is transmitted to the remote control center through an electrical signal. The remote control center determines whether the bearing housing is too high or too low relative to the bearing body based on the amount of compression, and then controls the support assembly to adjust the height of the bearing housing, so that the center of the central hole of the bearing housing is aligned with the center of the bearing body's mounting end. The adjustment process is intelligent and the installation efficiency is high. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0018] Figure 2 This is a schematic diagram of the support component structure of this utility model;

[0019] Figure 3 This is a schematic diagram of the bottom structure of the support component of this utility model;

[0020] Figure 4 This is a schematic diagram of the detection component structure of this utility model.

[0021] In the diagram: 1. Bearing body; 2. Placement rack; 3. Bearing housing; 4. Testing assembly; 401. Telescopic column; 402. Spring; 403. Testing plate; 5. Support assembly; 501. Moving plate; 502. Electric hydraulic cylinder; 503. Placement platform; 504. Fixing buckle; 505. Moving wheel; 506. Dual output motor; 507. Mounting bracket; 6. Track. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the protection scope of the present utility model.

[0023] To address the issue that during the installation process of aligning the bearing housing 3 with the bearing, it is impossible to accurately align the two, requiring continuous adjustment of the height of the bearing housing 3 to achieve alignment with the bearing mounting end. This adjustment process is not intelligent and results in low installation efficiency. Therefore, the following implementation method is proposed.

[0024] This utility model provides, for example Figures 1 to 4 The bearing housing bracket shown includes a bearing housing 3 and a support assembly 5. The bearing housing 3 is mounted on top of the support assembly 5. A track 6 is provided at the bottom of the support assembly 5. A placement frame 2 is provided in the middle of the track 6. A power supply device is provided at the bottom of the placement frame 2. The power supply device provides power support for the electronic components in this utility model. The placement frame 2 holds the bearing body 1. The bearing housing 3 is provided with a central circular hole for the bearing body 1 to pass through. Detection components 4 are evenly arranged on the circumference of the central circular hole. The bracket also includes a remote control center, which is electrically connected to the electronic components in the support assembly 5 and the detection components 4. The remote control center is also electrically connected to a spring 402 and an electric hydraulic cylinder 502. The deformation of the spring 402 is transmitted to the remote control center through an electrical signal. After receiving the electrical signal, the remote control center issues instructions to the support assembly 5.

[0025] After the detection component 4 collects the data on the offset direction of the bearing body 1, it transmits the data to the remote control center. The remote control center identifies and judges the offset direction, and based on the judgment result, issues a command to the support component 5, thereby driving the bearing housing 3 to rise and fall, adjusting the center height of the central hole so that it is aligned with the center of the bearing body 1 at the mounting end, thus improving installation efficiency.

[0026] like Figure 1 and Figure 4 As shown, the detection component 4 includes a telescopic column 401, a spring 402, and a detection plate 403. The spring 402 and the detection plate 403 are respectively disposed at both ends of the telescopic column 401. The compression change of the spring 402 is transmitted to the remote control center via an electrical signal. The spring 402 can preferably be a spring sensor. One end of the spring 402 is fixedly connected to the bearing housing 3. A blind hole is provided on the outside of the central circular hole of the bearing housing 3. The spring 402 and the telescopic column 401 are disposed in the blind hole. One end of the spring 402 is fixedly connected to the inner end of the blind hole, and the other end is fixedly connected to the end of the telescopic column 401. One end of the telescopic column 401 extends to the outside of the blind hole and is connected to the detection plate 403.

[0027] In use, the remote control center first issues a command to the dual-output motor 506 to start the dual-output motor 506, which drives the moving wheel 505 to rotate, thereby driving the entire support assembly 5 and the bearing housing 3 to move along the track 6 towards the bearing body 1 until the end of the bearing body 1 abuts against the detection plate 403. At this time, the spring 402 generates compression. The remote control center determines the height of the center hole of the bearing housing 3 relative to the end of the bearing body 1 based on the compression of the spring 402.

[0028] Specifically: when the bottom spring 402 has no compression, but the top spring 402 has compression, or both the top and middle springs 402 have compression, it indicates that the bearing housing 3 is lower than the bearing body 1. Conversely, when the top spring 402 has no compression, but the bottom spring 402 has compression, or both the bottom and middle springs 402 have compression, it indicates that the bearing housing 3 is higher than the bearing body 1. In both cases, the end of the bearing body 1 presses against the detection plate 403, causing the detection plate 403 to move the telescopic column 401 towards the blind hole, thus compressing the spring 402.

[0029] The remote control center receives the electrical signal of the change in the compression of the spring 402, determines whether the current position of the bearing housing 3 is too high or too low, and then issues a command to the electric hydraulic cylinder 502 to drive the bearing housing 3 to adjust its height, so as to ensure that the center hole of the bearing housing 3 can be aligned with the bearing body 1 for installation.

[0030] like Figures 2-3 As shown, the support assembly 5 includes a movable plate 501, on which electric hydraulic cylinders 502 are evenly arranged. The output end of the electric hydraulic cylinders 502 is fixedly mounted on a placement platform 503. The placement platform 503 is provided with a fixing buckle 504 for fixing the bearing housing 3. Movable wheels 505 are arranged in an array on the bottom surface of the movable plate 501. A dual-output motor 506 is provided at any end of the bottom surface of the movable plate 501. The dual-output motor 506 is fixed to the bottom of the movable plate 501 by a mounting bracket 507. The output end of the dual-output motor 506 is connected to the movable wheel 505. The movable wheel 505 has an annular groove along its circumference. A convex strip is provided on the track 6. The convex strip is engaged with the annular groove. The movable wheel 505 moves along the track 6.

[0031] When in use, after the remote control center issues a lifting command to the electric hydraulic cylinder 502, the output end of the electric hydraulic cylinder 502 extends and retracts according to the lifting command, and drives the bearing housing 3 to rise and fall through the placement platform 503 until all the springs 402 have no compression, which means that the center hole of the bearing housing 3 and the end of the bearing body 1 are aligned. The two are aligned and the extension and retraction of the output end of the electric hydraulic cylinder 502 stops.

[0032] By setting up a spring 402, a telescopic column 401, and a detection plate 403, after the end of the bearing body 1 abuts against the detection plate 403, the detection plate 403 compresses the spring 402 through the telescopic column 401. The compression amount of the spring 402 is transmitted to the remote control center through an electrical signal. The remote control center determines whether the bearing housing 3 is too high or too low relative to the bearing body 1 based on the compression amount, and then controls the support assembly 5 to adjust the height of the bearing housing 3, so that the center of the central hole of the bearing housing 3 is aligned with the center of the installation end of the bearing body 1. The adjustment process is intelligent and the installation efficiency is high.

[0033] The working principle of this utility model is as follows: First, the bearing housing 3 is moved. The remote control center first issues an instruction to the dual-output motor 506 to start the dual-output motor 506, which drives the moving wheel 505 to rotate, thereby driving the entire support assembly 5 and the bearing housing 3 to move along the track 6 towards the bearing body 1 until the end of the bearing body 1 touches the detection plate 403. At this time, the remote control center stops the rotation of the dual-output motor 506.

[0034] Secondly, the height of the bearing housing 3 is determined. When the bottom spring 402 has no compression, but the top spring 402 has compression, or both the top and middle springs 402 have compression, it indicates that the bearing housing 3 is lower than the bearing body 1. Conversely, when the top spring 402 has no compression, but the bottom spring 402 has compression, or both the bottom and middle springs 402 have compression, it indicates that the bearing housing 3 is higher than the bearing body 1. Both of these situations cause the end of the bearing body 1 to press against the detection plate 403, which in turn causes the detection plate 403 to move the telescopic column 401 towards the blind hole, thus compressing the springs 402. The remote control center receives the electrical signal indicating the change in the compression of the springs 402, determines whether the bearing housing 3 is too high or too low, and then issues a lifting command to the electric hydraulic cylinder 502.

[0035] Then, adjust the height of the bearing housing 3. After the remote control center issues a lifting command to the electric hydraulic cylinder 502, the output end of the electric hydraulic cylinder 502 extends and retracts according to the lifting command. The bearing housing 3 is lifted and retracted through the placement platform 503 until all the springs 402 have no compression. This means that the center hole of the bearing housing 3 is aligned with the end of the bearing body 1. The two are aligned and the extension and retraction of the output end of the electric hydraulic cylinder 502 is stopped.

[0036] Finally, the bearing housing 3 is installed, and the remote control center resumes the rotation of the dual-output motor 506, which drives the moving wheel 505 to rotate. This allows the bearing housing 3 to be installed on the bearing body 1 via the support assembly 5, i.e., the bearing body 1 passes through the central hole of the bearing housing 3, thus completing the installation of the bearing housing 3 and the bearing body 1.

[0037] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A bearing housing support characterized by: The bearing housing (3) and the support assembly (5) are included. The bearing housing (3) is installed on the top of the support assembly (5). The bottom of the support assembly (5) is provided with a track (6). A placement frame (2) is provided in the middle of the track (6). The placement frame (2) holds the bearing body (1). The bearing housing (3) is provided with a central circular hole through which the bearing body (1) passes. Detection components (4) are evenly arranged on the circumference of the central circular hole. It also includes a remote control center, which is electrically connected to the electronic components in the support component (5) and the detection component (4).

2. A bearing housing support according to claim 1, characterised in that: The detection component (4) includes a telescopic column (401), a spring (402) and a detection plate (403). The spring (402) and the detection plate (403) are respectively disposed at both ends of the telescopic column (401), and one end of the spring (402) is fixedly connected to the bearing housing (3).

3. A bearing housing support according to claim 2, characterised in that: A blind hole is provided on the outside of the central circular hole of the bearing housing (3). The spring (402) and the telescopic column (401) are arranged in the blind hole. One end of the spring (402) is fixedly connected to the inner end of the blind hole, and the other end is fixedly connected to the end of the telescopic column (401). One end of the telescopic column (401) extends to the outside of the blind hole and is connected to the detection plate (403).

4. A bearing housing bracket according to claim 1, characterized in that: The support assembly (5) includes a movable plate (501), on which electric hydraulic cylinders (502) are evenly arranged. A placement platform (503) is fixedly arranged at the output end of the electric hydraulic cylinder (502), and a fixing buckle (504) for fixing the bearing housing (3) is arranged on the placement platform (503).

5. A bearing housing bracket according to claim 4, characterized in that: The bottom surface of the movable plate (501) is provided with an array of movable wheels (505), and a dual-output motor (506) is provided at any end of the bottom surface of the movable plate (501). The dual-output motor (506) is fixed to the bottom of the movable plate (501) by a mounting bracket (507), and the output end of the dual-output motor (506) is connected to the movable wheel (505).

6. A bearing housing bracket according to claim 5, characterized in that: The movable wheel (505) has an annular groove along its circumference, and the track (6) has a protrusion that fits into the annular groove. The movable wheel (505) travels along the track (6).