Modular communication automation integration installation device

By using a modular communication automation integrated installation device, which incorporates angle adjustment components and installation adjustment components, the problems of cumbersome installation and poor stability of existing communication equipment are solved, enabling fast, stable, and flexible angle adjustment and signal optimization.

CN122393590APending Publication Date: 2026-07-14HUAYUN HOLDING GROUP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
HUAYUN HOLDING GROUP CO LTD
Filing Date
2026-05-18
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing communication equipment installation devices are cumbersome to operate when adjusting the tilt angle of the communication equipment, and the fastening bolts are prone to loosening, affecting the stability of the installation and making it difficult to make flexible adjustments according to signal requirements.

Method used

The modular communication automation integrated installation device utilizes angle adjustment components and installation adjustment components, including fixed blocks, gears, rotating frames and U-shaped telescopic frames. Through gear meshing and spring cooperation, the antenna plate can be flexibly adjusted and fixed. Combined with screw and knob drive, the antenna plate can be adjusted at multiple angles and supported stably.

Benefits of technology

It enables rapid and stable installation of communication equipment and flexible angle adjustment, enhances wind resistance, prevents fasteners from loosening, and improves signal transmission efficiency and equipment heat dissipation performance.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This invention belongs to the field of communication technology, specifically a modular automated integrated installation device for communication, including a mounting frame. An angle adjustment component is installed at the upper end of the mounting frame, and an antenna plate is mounted on one end of the angle adjustment component. The angle adjustment component is used to adjust the tilt angle of the antenna plate to achieve optimal signal transmission and transmission. This invention solves the problem that existing installation devices typically connect to communication equipment via multiple relatively rotatable support members, with the rotatable connections secured by fasteners. Adjusting the tilt angle of the communication equipment requires first loosening the fasteners, then adjusting the extension and retraction of the support members to move the communication equipment, and finally re-tightening the fasteners. However, this adjustment method is cumbersome, and when the communication equipment is subjected to wind vibration over a long period, which is transmitted to the support members for synchronous vibration, the fasteners are prone to loosening, affecting the stability of the communication equipment after adjustment and installation.
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Description

Technical Field

[0001] This invention belongs to the field of communication technology, specifically a modular communication automation integration and installation device. Background Technology

[0002] With the rapid development of communication technology in the information age, communication equipment has been deployed on a large scale, with 5G antennas being particularly prominent. Compared to 4G antennas, 5G antenna signals have higher frequencies, shorter wavelengths, and stronger directionality. Therefore, for different coverage areas, sometimes in order to improve network capacity, it is necessary to use signal refraction to expand the coverage area and bypass obstacles. This function can be accomplished by reconfiguring smart surface devices.

[0003] A patent with publication number CN119572910A discloses an installation device for a communication device. This device is used to install the communication device onto a support member. The installation device includes a first mounting member and a second mounting member. The first mounting member is disposed on the support member, and the second mounting member is used to mount the communication device. The installation device further includes: a connecting component disposed between the first and second mounting members, which is used to move under force to drive the second mounting member relative to the first mounting member to a preset position; and a self-locking component disposed on the connecting component, which is used to restrict the movement of the connecting component after the second mounting member has moved to the preset position.

[0004] The above solution still has some problems in practical application. It is usually installed by connecting the communication equipment with multiple relatively rotatable support components. The rotatable connection is fixed with fasteners. When adjusting the tilt angle of the communication equipment, the fasteners are loosened first, and then the support components are adjusted to drive the communication equipment to move. After the adjustment is completed, the fasteners are tightened again. However, this adjustment method is cumbersome. When the communication equipment is subjected to wind vibration for a long time and the vibration is transmitted to the support components, the fasteners are easy to loosen, which affects the stability of the communication equipment after adjustment and installation.

[0005] Therefore, the present invention provides a modular communication automated integrated installation device. Summary of the Invention

[0006] In order to overcome the shortcomings of the prior art, at least one technical problem raised in the background art is solved.

[0007] The technical solution adopted by the present invention to solve its technical problem is: a modular communication automated integrated installation device of the present invention includes a mounting frame, an angle adjustment component is provided in the upper end of the mounting frame, an antenna board is installed at one end of the angle adjustment component, and the angle adjustment component is used to adjust the tilt angle of the antenna board so that the antenna board can achieve the best effect in transmitting and transmitting signals. A radio frequency module is installed at the lower end of the antenna board, and mounting adjustment components are provided at the four corners on both sides of the mounting bracket. The installation and adjustment assembly includes fixed blocks at the four corners on both sides of the mounting frame. The inner cavity of the fixed block is rotatably connected to a first gear, and the two ends of the first gear pass through the fixed block and are fixed to a rotating frame. A rotating block is rotatably connected to one end of the rotating frame, and a U-shaped telescopic frame is provided at one end of the rotating block. The telescopic movement of the U-shaped telescopic frame is used to adjust the left and right tilt angle of the mounting frame, thereby driving the antenna plate to tilt synchronously. It can be adjusted according to the transmitted signal and signal transmission to achieve the best effect.

[0008] Preferably, the inner wall of the fixing block is provided with a first groove, a first spring is fixedly connected to the bottom of the inner cavity of the first groove, a first insert is fixedly connected to one end of the first spring, and the first insert engages with the tooth groove of the first gear.

[0009] Preferably, the inner cavity of the rotating block is rotatably connected to a second gear, and the rotating block is rotatably connected to the rotating frame through the second gear. The two ends of the second gear pass through the rotating block and are fixedly connected to the rotating frame.

[0010] Preferably, the inner wall of the rotating block is provided with a second groove, a second spring is fixedly connected to the bottom of the inner cavity of the second groove, a second insert is fixedly connected to one end of the second spring, and the second insert engages with the tooth groove of the second gear.

[0011] Preferably, one end of the rotating block has a slot, and the rotating block is inserted into the U-shaped telescopic frame through the slot. A fastening bolt is rotatably connected to the upper end of the rotating block.

[0012] Preferably, the angle adjustment assembly includes two storage slots formed on the upper end of the mounting bracket, and the inner cavities of the two storage slots are respectively rotatably connected to a first screw and a second screw. The first screw and the second screw are both threadedly connected to a slide rod, and the slide rod slides in the inner cavity of the storage slot to drive the antenna plate to adjust the tilt angle.

[0013] Preferably, the sliding rod is rotatably connected to a pusher frame at both ends, and a mounting block is rotatably connected to the inner cavity of one end of the pusher frame, and the mounting block is fixedly installed to the antenna plate by screws.

[0014] Preferably, a support frame is rotatably connected to one side of the inner cavity of the storage slot, one end of the support frame is rotatably connected to the push frame, and a knob is fixedly connected to one end of the first screw and the second screw through the mounting frame.

[0015] Preferably, a fan-driven heat dissipation component is provided at the lower middle part of the mounting bracket, and the fan-driven heat dissipation component includes a through groove opened at the lower end of the mounting bracket. A cross mounting bracket is installed at the lower end of the mounting bracket, and a rotating shaft is rotatably connected inside the cross mounting bracket. An impeller is installed on the outer side of the upper end of the rotating shaft, and fan blades are installed on the outer side of the lower end of the rotating shaft. A filter screen is installed on the upper part of the inner cavity of the through groove.

[0016] Preferably, the mounting bracket has multiple T-shaped grooves at its lower end, and each pair of T-shaped grooves forms a group. Each T-shaped groove has a third spring inside its cavity. One end of the third spring is fixedly connected to a T-shaped sliding column, and the lower end of the T-shaped sliding column is fixedly connected to a stop plate.

[0017] The beneficial effects of this invention are as follows: 1. The modular communication automation integrated installation device of the present invention, by turning the rotating frame to drive the first gear to rotate, the first gear uses its teeth to push the first plug to disengage, and the first plug then squeezes the first spring and is fully embedded in the inner cavity of the first groove, thereby realizing the flexible adjustment of the rotating frame. Then, turning the rotating block to drive the second plug to rotate synchronously, the second plug, through the engagement of its teeth with the arc-shaped teeth of the second gear, squeezes and slides into the inner cavity of the second groove, finally adjusting the rotating frame, rotating block and U-shaped telescopic frame into a ring-shaped structure, forming a ring-shaped clamping of the column support. At the same time, the abutment plate abuts against the column support, pushing the T-shaped sliding column to squeeze the third spring and slide into the inner cavity of the T-shaped sliding groove. With the help of the rebound force of the third spring, the T-shaped sliding column drives the abutment plate to continuously push the column support, ensuring the clamping force of the rotating frame, rotating block and U-shaped telescopic frame on the column support. Finally, the U-shaped telescopic frame is fixedly installed by external screws, so that the installation device can be installed and used according to different environments and positions.

[0018] 2. The modular communication automation integrated installation device of the present invention drives the first screw and the second screw to rotate synchronously by rotating a knob. The two screws then drive two sliding rods to slide away from each other in the inner cavity of the receiving slot. This causes the sliding rods to drive the push frame to move, pushing the mounting block upward, and thus moving the antenna plate upward synchronously. This allows for adjustment of the distance between the antenna plate and the mounting frame according to the installation position and height requirements, avoiding obstruction of signal transmission and transmission by surrounding buildings. If the antenna plate orientation needs to be adjusted upward, the knob can be driven to rotate the second screw, which continuously drives the sliding rod to move. This, in turn, causes the mounting block to move upward through the push frame, causing the antenna plate to flip upward to adjust the orientation angle. Conversely, if the antenna plate orientation needs to be adjusted downward, the first screw is driven to adjust it, thereby realizing the vertical angle adjustment function of the antenna plate. In addition, a support frame is rotatably connected to the middle part of the push frame, which can further improve the support stability of the push frame for the antenna plate and enhance the wind resistance of the device. Attached Figure Description

[0019] The invention will now be further described with reference to the accompanying drawings.

[0020] Figure 1 This is a schematic diagram of the overall structure of the main view of the present invention; Figure 2 This is a schematic diagram of the overall structure of the invention viewed from below; Figure 3This is a schematic diagram of the overall structure of the mounting bracket of the present invention; Figure 4 This is a partial cross-sectional schematic diagram of the mounting bracket of the present invention; Figure 5 This is the present invention. Figure 4 Schematic diagram of the structure of region A in the middle; Figure 6 This is the present invention. Figure 4 Schematic diagram of the structure of region B in the middle; Figure 7 This is a schematic diagram of the installation and adjustment components of the present invention and their installation on the wall; Figure 8 This is a schematic diagram of the overall structure of the wind-driven heat dissipation component of the present invention; Figure 9 This is a schematic diagram of the assembly and disassembly of the U-shaped telescopic frame of the present invention; In the diagram: 1. Mounting bracket; 2. Antenna board; 3. Filter screen; 4. Mounting and adjustment assembly; 41. Fixing block; 42. First groove; 43. First spring; 44. First insert block; 45. First gear; 46. Rotating bracket; 47. Second groove; 48. Second spring; 49. Second insert block; 410. Second gear; 411. Slot; 412. U-shaped telescopic bracket; 413. Rotating block; 5. RF module; 6. Fan-driven heat dissipation assembly; 61. Through slot; 62. Cross mounting bracket; 63. Rotating shaft; 64. Impeller; 65. Fan blade; 7. Support plate; 8. Angle adjustment assembly; 81. Storage slot; 82. First screw; 83. Second screw; 84. Slide rod; 85. Pushing bracket; 86. Support bracket; 87. Knob; 88. Mounting block; 9. T-shaped slide groove; 10. T-shaped slide column; 11. Third spring. Detailed Implementation

[0021] To make the technical means, creative features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments. Example 1

[0022] like Figure 1 , Figure 2 and Figure 6 As shown in the figure, a modular communication automation integrated installation device according to an embodiment of the present invention includes a mounting frame 1. An angle adjustment component 8 is provided in the upper end of the mounting frame 1. An antenna plate 2 is installed at one end of the angle adjustment component 8. The angle adjustment component 8 is used to adjust the tilt angle of the antenna plate 2 so that the antenna plate 2 can achieve the best effect in transmitting and transmitting signals. The antenna board 2 is equipped with an RF module 5 at its lower end, and the mounting bracket 1 is equipped with mounting adjustment components 4 at the four corners on both sides. The installation and adjustment assembly 4 includes fixed blocks 41 fixed to the four corners on both sides of the mounting frame 1. The inner cavity of the fixed block 41 is rotatably connected to a first gear 45, and the two ends of the first gear 45 pass through the fixed block 41 and are fixed to a rotating frame 46. A rotating block 413 is rotatably connected to one end of the rotating frame 46. A U-shaped telescopic frame 412 is provided at one end of the rotating block 413. The telescopic movement of the U-shaped telescopic frame 412 is used to adjust the left and right tilt angle of the mounting frame 1, thereby driving the antenna plate 2 to tilt synchronously. It can be adjusted according to the transmitted signal and signal transmission to achieve the best effect.

[0023] Specifically, in existing technologies, multiple mutually rotating support components are typically used to install the communication equipment. The rotating connections of the support components are fixed with fasteners. When it is necessary to adjust the tilt angle of the communication equipment, the fasteners need to be loosened, and then the telescopic movement of the support components is adjusted to drive the communication equipment to move. After the adjustment is completed, the fasteners are tightened again to fix the rotating connections of the support components. However, this adjustment method is not only cumbersome to operate, but also, by using the communication equipment to withstand wind vibration for a long time and transmitting the synchronous vibration of the support components, the fasteners may loosen, affecting the stability of the communication equipment after adjustment and installation.

[0024] When installing and using modular communication equipment, this invention connects the Chain1 and Chain0 interfaces of the RF module 5 to the H and V connectors of the antenna board 2, and then uses screws to fix the RF module 5 to the antenna board 2, thereby ensuring the stability of the interface and realizing the integrated installation of the wireless communication equipment. Furthermore, the fixed installation of the RF module 5 and the antenna board 2 can prevent rainwater from entering the interface and causing short circuits. Then, the antenna board 2 is fixedly installed with the angle adjustment component 8. When it is necessary to install the wireless communication equipment to the wall, the rotating brackets 46 on both sides of the mounting bracket 1 are adjusted. The rotation causes the rotating frame 46 to move closer to the rotating block 413, and then the U-shaped telescopic frame 412 is pressed tightly against the wall. The U-shaped telescopic frame 412 is then installed and fixed to the wall using expansion bolts. When it is necessary to adjust the angle of the antenna plate 2, the rotating block 413 is driven to slide outside the U-shaped telescopic frame 412, which in turn causes the U-shaped telescopic frame 412 to drive the rotating frame 46 to rotate and move. The rotating frame 46 pushes the fixing block 41 to move upward, while the fixing block 41 drives the mounting frame 1 to rotate. This allows the mounting frame 1 to work with the angle adjustment component 8 to tilt the antenna plate 2 left and right, thus solving the above problem.

[0025] like Figures 4 to 6 and Figure 9As shown, the inner wall of the fixed block 41 has a first groove 42, the bottom of the inner cavity of the first groove 42 is fixedly connected to a first spring 43, one end of the first spring 43 is fixedly connected to a first insert block 44, and the first insert block 44 is engaged with the tooth groove of the first gear 45. One end of the rotating block 413 has a slot 411, and the rotating block 413 is inserted into the U-shaped telescopic frame 412 through the slot 411. A fastening bolt is rotatably connected to the upper end of the rotating block 413.

[0026] Specifically, after the mounting bracket 1 is installed on the wall, the rotating bracket 46 is rotated, which in turn drives the first gear 45 to rotate. The first gear 45 then uses its teeth to push the first insert 44 into the first groove 42, which in turn squeezes the first spring 43 into the inner cavity of the first groove 42. This facilitates the rotation adjustment of the rotating bracket 46. During the rotation, the rotating bracket 46 drives the rotating block 413 to move synchronously and slides outside the U-shaped telescopic bracket 412. This causes the rotating bracket 46 to push the fixing block 41, causing the mounting bracket 1 to flip and tilt to one side, thus completing the left and right angle tilt adjustment of the antenna plate 2. Then, the U-shaped telescopic bracket 412 and the rotating block 413 are fixed with fastening bolts, and the first spring 43 lifts the first insert 44 out of the first groove 42, allowing the first insert 44 to be inserted into the inner cavity of the first gear 45 for fixation, thereby ensuring the stability of the wireless communication equipment after installation.

[0027] like Figures 4 to 6 and Figure 9 As shown, a second gear 410 is rotatably connected to the inner cavity of the rotating block 413, and the rotating block 413 is rotatably connected to the rotating frame 46 through the second gear 410. The two ends of the second gear 410 pass through the rotating block 413 and are fixedly connected to the rotating frame 46. A second groove 47 is provided in the inner wall of the rotating block 413. A second spring 48 is fixedly connected to the bottom of the inner cavity of the second groove 47. A second insert 49 is fixedly connected to one end of the second spring 48, and the second insert 49 is engaged with the tooth groove of the second gear 410.

[0028] Specifically, when installing the wireless communication equipment with the column bracket, the rotating frame 46 is rotated, causing the first gear 45 to rotate. The first gear 45 then uses its teeth to push the first insert 44 into the first groove 42, causing the first insert 44 to press against the first spring 43 and slide into the inner cavity of the first groove 42. This facilitates the rotation adjustment of the rotating frame 46. Then, the rotating block 413 is rotated, causing the second insert 49 to rotate synchronously. The second insert 49 then uses its arc-shaped teeth to engage with the teeth of the second gear 410 and slide into the inner cavity of the second groove 47. This adjusts the rotating frame 46, rotating block 413, and U-shaped telescopic frame 412 into a ring-like arrangement, clamping the column bracket. Simultaneously, the abutment plate 7 abuts against the column bracket, and the abutment plate 7 pushes the T-shaped... The sliding column 10 presses the third spring 11 into the inner cavity of the T-shaped sliding groove 9. Then, the rebound force of the third spring 11 pushes the T-shaped sliding column 10 to drive the abutment plate 7 to push the column bracket, ensuring the clamping force of the rotating frame 46, rotating block 413 and U-shaped telescopic frame 412 on the column bracket. Then, the U-shaped telescopic frame 412 is installed by external screws, thereby determining the installation position of the mounting frame 1. This solves the problem that when installing wireless communication equipment outdoors using existing modular communication automation integrated installation devices, the mounting plate is usually installed to the wall using expansion bolts or to the column bracket using clamps. However, this installation method is not only cumbersome to operate, but also difficult to disassemble after installation. This makes it difficult to adjust the angle of the wireless communication equipment according to the signal transmission or transmission requirements, resulting in the trouble of disassembly and reassembly every time the angle is adjusted.

[0029] Example 2 like Figure 3 , Figure 4 and Figure 7 As shown, the angle adjustment assembly 8 includes two storage slots 81 located on the upper end of the mounting frame 1. A first screw 82 and a second screw 83 are rotatably connected to the inner cavities of the two storage slots 81, respectively. A slide rod 84 is threadedly connected to the outside of both the first screw 82 and the second screw 83. The slide rod 84 slides in the inner cavity of the storage slot 81 and is used to drive the antenna plate 2 to adjust the tilt angle. A push frame 85 is rotatably connected to both ends of the slide rod 84. A mounting block 88 is rotatably connected to the inner cavity of one end of the push frame 85. The mounting block 88 is fixedly installed to the antenna plate 2 by screws. A support frame 86 is rotatably connected to one side of the inner cavity of the storage slot 81. One end of the support frame 86 is rotatably connected to the push frame 85. A knob 87 is fixedly connected to one end of the first screw 82 and the second screw 83 through the mounting frame 1.

[0030] Specifically, after the wireless communication equipment is installed on the wall or column, the first screw 82 and the second screw 83 are rotated by turning the knob 87. This causes the first screw 82 and the second screw 83 to drive the two sliding rods 84 to slide away from each other within the cavity of the receiving slot 81. Simultaneously, the sliding rods 84 drive the pusher frame 85 to move, which in turn pushes the mounting block 88 upwards. This causes the mounting block 88 to move the antenna plate 2 upwards, allowing the distance between the antenna plate 2 and the mounting frame 1 to be adjusted according to the installation position and height. This avoids obstruction of signal transmission and transmission by surrounding buildings. Then, when adjusting the orientation of the antenna plate 2 upwards, the second screw 83 is rotated by driving the knob 87. This causes the second screw 83 to continuously drive the sliding rod 84 to move, which in turn drives the pusher frame 85 to move. Simultaneously, the pusher frame 85 drives the mounting block 88 upwards, causing the mounting block 88 to move upwards. The antenna plate 2 is flipped upwards to adjust its orientation angle. Conversely, when the antenna plate 2 is adjusted downwards, the first screw 82 is driven to adjust the antenna plate 2, thereby achieving the vertical angle adjustment of the antenna plate 2. The middle part of the push frame 85 is rotatably connected to the support frame 86, which increases the stability of the push frame 85 in supporting the antenna plate 2 and increases wind resistance. This solves the problem that after the existing modular communication automation integrated installation device is installed outdoors, the angle of the communication equipment needs to be adjusted to increase the signal transmission efficiency of the communication equipment. The commonly used adjustment method is to adjust the angle through the telescopic push device of the foldable telescopic frame and then use fasteners to fix the fold of the telescopic frame. However, this operation method is not only cumbersome, but the fasteners are also prone to loosening after the communication equipment is subjected to wind vibration for a long time, causing the fold of the telescopic frame to lose its support capacity and fail to effectively fix the communication equipment.

[0031] like Figure 2 , Figure 5 and Figure 8 As shown, a fan-driven heat dissipation component 6 is provided in the middle of the lower end of the mounting frame 1. The fan-driven heat dissipation component 6 includes a through groove 61 opened at the lower end of the mounting frame 1. A cross mounting frame 62 is installed at the lower end of the mounting frame 1. A rotating shaft 63 is rotatably connected inside the cross mounting frame 62. An impeller 64 is installed on the outer side of the upper end of the rotating shaft 63. A fan blade 65 is installed on the outer side of the lower end of the rotating shaft 63. A filter screen 3 is installed in the upper part of the inner cavity of the through groove 61. Multiple T-shaped sliding grooves 9 are opened at the lower end of the mounting frame 1. Every two T-shaped sliding grooves 9 form a group. A third spring 11 is provided in the inner cavity of each T-shaped sliding groove 9. A T-shaped sliding column 10 is fixedly connected to one end of the third spring 11. A stop plate 7 is fixedly connected to the lower end of the T-shaped sliding column 10.

[0032] Specifically, after the mounting bracket 1 is installed and fixed to the wall or column, the abutment plate 7 abuts against the wall or column, causing the abutment plate 7 to push the T-shaped sliding column 10 to compress the third spring 11 into the inner cavity of the T-shaped sliding groove 9. This causes the abutment plate 7 to lift the mounting bracket 1 away from the wall or column. After the airflow passes through the mounting bracket 1, the wind blows the fan blades 65 to rotate, which in turn drives the rotating shaft 63 to rotate. The rotating shaft 63 then drives the impeller 64 to rotate, causing the impeller 64 to blow air through the filter screen 3 onto the radio frequency module 5. This allows the airflow to pass through the radio frequency module 5 and dissipate heat, thereby improving the heat dissipation efficiency of the communication equipment in hot summer weather. This solves the problem that after the existing modular communication automation integrated installation device is installed outdoors at a high altitude, the communication equipment is easily exposed to the elements for a long time, which can lead to high temperatures in summer. The communication equipment itself cannot effectively dissipate heat, and the internal components of the communication equipment may break due to high temperatures.

[0033] Working principle: When installing and using the modular communication equipment, the Chain1 and Chain0 interfaces of the RF module 5 are connected to the H and V connectors of the antenna board 2. Then, screws are used to fix the RF module 5 to the antenna board 2, ensuring interface stability and achieving integrated installation of the wireless communication equipment. Furthermore, the fixed installation of the RF module 5 and antenna board 2 prevents rainwater from entering the interface and causing short circuits. The antenna board 2 is then fixedly installed with the angle adjustment component 8. When installing the wireless communication equipment against a wall, the rotating parts on both sides of the mounting bracket 1 are adjusted. The rotating frame 46 rotates, causing the rotating block 413 to move closer to each other. Then, the U-shaped telescopic frame 412 is pressed tightly against the wall, and the U-shaped telescopic frame 412 is installed and fixed to the wall using expansion bolts. When it is necessary to adjust the angle of the antenna plate 2, the rotating block 413 is driven to slide outside the U-shaped telescopic frame 412, which in turn causes the U-shaped telescopic frame 412 to drive the rotating frame 46 to flip and move. The rotating frame 46 pushes the fixed block 41 to move upward, while the fixed block 41 drives the mounting frame 1 to flip. Then, the mounting frame 1, in conjunction with the angle adjustment component 8, drives the antenna plate 2 to tilt left and right. When installing the wireless communication equipment onto the column bracket, the rotating frame 46 is rotated, causing the first gear 45 to rotate. The first gear 45 then uses its teeth to push the first insert 44 into the first groove 42, causing the first insert 44 to press against the first spring 43 and slide into the inner cavity of the first groove 42. This facilitates the rotation adjustment of the rotating frame 46. Then, the rotating block 413 is rotated, causing the second insert 49 to rotate synchronously. The second insert 49 then uses its arc-shaped teeth to engage with the teeth of the second gear 410 and slide into the inner cavity of the second groove 47, thus connecting the rotating frame 46 and the rotating... The block 413 and the U-shaped telescopic frame 412 are adjusted to form a ring-shaped clamp, so that the rotating frame 46, the rotating block 413 and the U-shaped telescopic frame 412 clamp the column support. At the same time, the abutment plate 7 abuts against the column support, and the abutment plate 7 pushes the T-shaped sliding column 10 to squeeze the third spring 11 into the inner cavity of the T-shaped sliding groove 9. Then, the rebound force of the third spring 11 pushes the T-shaped sliding column 10 to drive the abutment plate 7 to push the column support, ensuring the clamping force of the rotating frame 46, the rotating block 413 and the U-shaped telescopic frame 412 on the column support. Then, the U-shaped telescopic frame 412 is installed by external screws, thereby determining the installation position of the mounting frame 1. After the wireless communication equipment is installed on the wall or column, the first screw 82 and the second screw 83 are rotated by turning the knob 87. This causes the first screw 82 and the second screw 83 to drive the two sliding rods 84 to slide away from each other within the receiving groove 81. Simultaneously, the sliding rods 84 drive the pusher frame 85 to move, which in turn pushes the mounting block 88 upwards. This, in turn, causes the mounting block 88 to move the antenna plate 2 upwards. This allows for adjustment of the distance between the antenna plate 2 and the mounting frame 1 according to the installation position and height, preventing surrounding buildings from obstructing signal transmission and transmission from the antenna plate 2. Then, the antenna plate 2 is adjusted upwards. When the antenna is facing upwards, the second screw 83 is rotated by the drive knob 87, and the second screw 83 continuously drives the slide bar 84 to move. In turn, the slide bar 84 drives the push frame 85 to move. At the same time, the push frame 85 drives the mounting block 88 to move upwards, so that the mounting block 88 drives the antenna plate 2 to flip upwards, thereby adjusting the orientation angle of the antenna plate 2. Conversely, when the orientation of the antenna plate 2 is adjusted downwards, the first screw 82 is driven to adjust the antenna plate 2, thereby realizing the vertical angle adjustment of the antenna plate 2. The middle part of the push frame 85 is rotatably connected to the support frame 86, thereby increasing the stability of the push frame 85 in supporting the antenna plate 2 and increasing the wind resistance.

[0034] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims

1. A modular communication automated integrated installation device, characterized in that: Includes a mounting bracket (1), an angle adjustment component (8) is provided in the upper end of the mounting bracket (1), an antenna plate (2) is installed at one end of the angle adjustment component (8), and the angle adjustment component (8) is used to adjust the tilt angle of the antenna plate (2) so that the antenna plate (2) can achieve the best effect in transmitting and transmitting signals. The antenna plate (2) is equipped with a radio frequency module (5) at its lower end, and the mounting bracket (1) is equipped with mounting adjustment components (4) at the four corners on both sides. The installation adjustment component (4) includes a fixing block (41) fixed to the four corners on both sides of the mounting frame (1). The inner cavity of the fixing block (41) is rotatably connected to a first gear (45), and the two ends of the first gear (45) pass through the fixing block (41) and are fixed to a rotating frame (46). One end of the rotating frame (46) is rotatably connected to a rotating block (413), and one end of the rotating block (413) is provided with a U-shaped telescopic frame (412). The telescopic movement of the U-shaped telescopic frame (412) is used to adjust the left and right tilt angle of the mounting frame (1), thereby driving the antenna plate (2) to tilt synchronously. It can be adjusted according to the transmitted signal and signal transmission to achieve the best effect.

2. The modular communication automated integrated installation device according to claim 1, characterized in that: The inner wall of the fixed block (41) is provided with a first groove (42), and a first spring (43) is fixedly connected to the bottom of the inner cavity of the first groove (42). One end of the first spring (43) is fixedly connected to a first insert (44), and the first insert (44) is engaged with the tooth groove of the first gear (45).

3. The modular communication automated integrated installation device according to claim 1, characterized in that: The inner cavity of the rotating block (413) is rotatably connected to the second gear (410), and the rotating block (413) is rotatably connected to the rotating frame (46) through the second gear (410). The two ends of the second gear (410) pass through the rotating block (413) and are fixedly connected to the rotating frame (46).

4. The modular communication automated integration and installation device according to claim 3, characterized in that: The inner wall of the rotating block (413) is provided with a second groove (47), and a second spring (48) is fixedly connected to the bottom of the inner cavity of the second groove (47). A second insert (49) is fixedly connected to one end of the second spring (48), and the second insert (49) is engaged with the tooth groove of the second gear (410).

5. The modular communication automated integration and installation device according to claim 4, characterized in that: The rotating block (413) has a slot (411) at one end, and the rotating block (413) is inserted into the U-shaped telescopic frame (412) through the slot (411). A fastening bolt is rotatably connected to the upper end of the rotating block (413).

6. The modular communication automated integration and installation device according to claim 1, characterized in that: The angle adjustment assembly (8) includes two storage slots (81) opened on the upper end of the mounting bracket (1), and the inner cavity of the two storage slots (81) is rotatably connected to a first screw (82) and a second screw (83). The first screw (82) and the second screw (83) are threadedly connected to a slide rod (84), and the slide rod (84) slides in the inner cavity of the storage slot (81) to drive the antenna plate (2) to adjust the tilt angle.

7. The modular communication automated integration and installation device according to claim 6, characterized in that: The sliding rod (84) is rotatably connected to a pusher frame (85) at both ends. The inner cavity of one end of the pusher frame (85) is rotatably connected to a mounting block (88), and the mounting block (88) is fixedly installed to the antenna plate (2) by screws.

8. The modular communication automated integration and installation device according to claim 6, characterized in that: A support frame (86) is rotatably connected to one side of the inner cavity of the storage slot (81). One end of the support frame (86) is rotatably connected to the push frame (85). A knob (87) is fixedly connected to one end of the first screw (82) and the second screw (83) through the mounting frame (1).

9. The modular communication automated integration and installation device according to claim 1, characterized in that: A fan-driven heat dissipation component (6) is provided at the lower middle of the mounting bracket (1), and the fan-driven heat dissipation component (6) includes a through groove (61) opened at the lower end of the mounting bracket (1). A cross mounting bracket (62) is installed at the lower end of the mounting bracket (1). A rotating shaft (63) is rotatably connected inside the cross mounting bracket (62). An impeller (64) is installed on the outer side of the upper end of the rotating shaft (63). A fan blade (65) is installed on the outer side of the lower end of the rotating shaft (63). A filter screen (3) is installed on the upper part of the inner cavity of the through groove (61).

10. A modular communication automated integrated installation device according to claim 9, characterized in that: The mounting bracket (1) has multiple T-shaped grooves (9) at its lower end, and each pair of T-shaped grooves (9) forms a group. Each T-shaped groove (9) has a third spring (11) in its inner cavity. One end of the third spring (11) is fixedly connected to a T-shaped sliding column (10), and the lower end of the T-shaped sliding column (10) is fixedly connected to a stop plate (7).