CN112203161A

CN112203161A - Diversified adjustable 5G communication base station

Info

Publication number: CN112203161A
Application number: CN202011080204.2A
Authority: CN
Inventors: 王盛
Original assignee: Individual
Current assignee: Zhongding Information Technology Co ltd
Priority date: 2020-10-10
Filing date: 2020-10-10
Publication date: 2021-01-08
Anticipated expiration: 2040-10-10
Also published as: CN112203161B

Abstract

The invention belongs to the technical field of 5G communication, and particularly relates to a multidirectional adjustable 5G communication base station. The system comprises a signal rod, one or more 5G antennas and an adjusting mechanism for adjusting the state or position of each 5G antenna; the side wall of the signal rod close to the upper end part is fixedly connected with a positioning mounting ring; the adjusting mechanism is connected on the positioning mounting ring in a sliding and clamping manner; the adjusting mechanism comprises a mounting frame, an elevation angle adjusting mechanism and a positioning mechanism; the elevation angle adjusting mechanism comprises an elevation angle adjusting rod and a worm wheel; a worm is fixedly connected to the elevation adjusting rod; the positioning mechanism comprises a positioning rotating column, a lifting rod, a lifting switching rod, a switching gear and a driving adjusting handle. The elevation angle, the direction and the height of a single 5G antenna can be adjusted by arranging the adjusting mechanism without influencing other 5G antennas; through setting up switching gear and lift switching pole, can make the 5G antenna switch different regulatory function, realize the regulation of height and orientation.

Description

Diversified adjustable 5G communication base station

Technical Field

The invention belongs to the technical field of 5G communication, and particularly relates to a multidirectional adjustable 5G communication base station.

Background

The construction of 5G base stations is more and more widespread, antennas are important components for transmitting signals from the base stations, and the antennas can receive signals transmitted by mobile phones and transmit the signals to other base stations or mobile phones to realize signal transmission; when the base station is built, parameters such as the angular position of the antenna and the like need to be specifically designed and considered, and the existing adjustable parameters of the antenna are few, so that the difficulty of installation is improved in order to achieve an ideal coverage effect.

Chinese patent No. CN111224211A discloses a 5G base station antenna elevation angle regulating mechanism, which realizes circumferential regulation of a signal transmitting antenna by lifting and rotating a handle to drive a movable sleeve to rotate, and realizes regulation of the elevation angle of the signal transmitting antenna by regulating the position of a sliding block on a sliding plate; however, when the signal transmission antenna is installed on a signal tower, the handle needs to be lifted above the signal transmission antenna in the adjustment process of the signal transmission antenna, and an installer needs to reach a position above the signal transmission antenna where the signal transmission antenna needs to pass through, and the possibility of collision exists in the rotation process of the signal transmission antenna, so that certain potential safety hazards exist; the driving of the movable sleeve is to synchronously adjust all signal transmitting antennas, and the single adjustment cannot be carried out; the adjustment of the sliding block during the adjustment of the elevation angle has the condition that an installer needs to share part of force to lift or pull the signal transmitting antenna, so that the adjustment difficulty is increased.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: aiming at the defect that a single signal transmitting antenna cannot be singly adjusted in the prior art, the 5G communication base station with adjustable multiple directions is provided.

In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose: a multi-azimuth adjustable 5G communication base station comprises a signal rod, one or more 5G antennas and an adjusting mechanism for adjusting the state or position of each 5G antenna;

the side wall of the signal rod close to the upper end part is fixedly connected with a positioning mounting ring; the adjusting mechanism is slidably clamped on the positioning mounting ring; the adjusting mechanism comprises a mounting frame for mounting the 5G antenna, an elevation angle adjusting mechanism for adjusting the elevation angle of the 5G antenna and a positioning mechanism for adjusting the height and the orientation of the 5G antenna; the 5G antenna is rotatably connected to the outer side of the mounting rack; the elevation angle adjusting mechanism comprises an elevation angle adjusting rod which is vertically arranged and a worm wheel which is used for driving the 5G antenna to rotate; the worm wheel is fixedly connected to a connecting end of the 5G antenna and the mounting rack; the worm wheel is coaxial with the rotation center of the connecting end; a worm for driving the worm wheel to rotate is fixedly connected to the elevation adjusting rod;

the positioning mechanism comprises a positioning rotating column rotatably connected to the mounting frame, a lifting rod inserted in the positioning rotating column, a lifting switching rod used for switching to a lifting state, a switching gear used for switching to an adjusting orientation and a driving adjusting handle used for driving the positioning rotating column to rotate; the lower end of the positioning rotating column is fixedly connected with a driven gear; a driving gear is fixedly connected to the driving adjusting handle corresponding to the driven gear; a positioning block for mounting the positioning rotating column is formed at the lower end of the mounting rack; the upper end of the lifting rod is slidably clamped in the positioning mounting ring; the periphery of the signal rod is fixedly connected with a fixed gear ring in meshing transmission connection with the switching gear;

when the lifting switching rod moves to a state of being connected with the lifting rod, the driving adjusting handle rotates to drive the positioning rotating column to rotate the lifting rod to realize the lifting of the 5G antenna; when the switching gear moves to the state connected with the positioning rotating column, the driving adjusting handle rotates to drive the positioning rotating column to enable the switching gear to rotate to realize that the 5G antenna rotates around the signal rod.

As a preferable scheme: the upper part of the lifting rod is formed with a lifting thread; an internal thread in threaded connection with the lifting thread is formed at the upper end of the mounting rack; a limiting shaft for limiting the lower end of the stroke of the 5G antenna in vertical movement is formed below the lifting screw thread of the lifting rod;

the lifting switching rod comprises a sliding rod which coaxially penetrates through the positioning rotating column; the upper end of the sliding rod is fixedly connected with a rotating chuck with a non-circular section; the rotary chuck protrudes out of the side wall of the sliding rod; the lower end of the lifting rod is provided with a rotary connecting hole which has the same section as the rotary chuck; when the lifting switching rod slides to the uppermost end, the rotating chuck is always in sliding connection with the rotating connecting hole; when the lifting switching rod slides to the lowest end, the rotating chuck is always separated from the rotating connecting hole.

As a preferable scheme: the switching gear is coaxially sleeved on the positioning rotating column and is positioned between the positioning block and the driven gear; a plurality of clamping grooves are uniformly formed in the upper part of the positioning rotating column below the mounting block along the circumferential direction; and a plurality of clamping teeth matched with the clamping grooves are formed on the inner wall of the switching gear.

As a preferable scheme: the lower part of the lifting switching rod is fixedly connected with a first magnet; the driven gear is made of a magnetic material; when the lifting switching rod moves to the uppermost end, the first magnet is attracted with the driven gear.

As a preferable scheme: the mounting frame is vertically and rotatably connected with a poking plate; one side of the poking plate after rotation is clamped between the gear teeth of the fixed gear ring. The orientation of the mounting frame can be kept unchanged after the mounting frame is rotated through the poking plate.

As a preferable scheme: the switching gear is made of a magnetic material; the lower end of the positioning block is fixedly connected with a second magnet which is attracted with the switching gear.

Compared with the prior art, the invention has the beneficial effects that: when the elevation angle of the 5G antenna needs to be adjusted, the poking plate is kept still, and at the moment, an installer rotates the elevation angle adjusting rod to enable the worm to rotate, so that the worm wheel is driven to rotate, and the adjustment of the elevation angle of the 5G antenna is realized; when the 5G antenna needs to be adjusted in a lifting mode, the switching gear is moved to the lowest end of the stroke, the lifting switching rod is moved to the highest end of the stroke, the first magnet and the driven gear are attracted at the moment, and meanwhile the adjusting handle is driven to rotate through rotation, so that the lifting rod rotates to adjust the height of the 5G antenna; when the orientation of the 5G antenna needs to be adjusted, the poking plate is rotated outwards to be separated from the fixed gear ring, the switching gear is moved to the uppermost end of the stroke, the lifting switching rod is moved to the lowermost end of the stroke, the second magnet is attracted with the switching gear, and the orientation of the 5G antenna can be adjusted by driving the adjusting handle to rotate; when the switching gear and the lifting switching rod are both positioned at the uppermost end of the stroke, the orientation and the height of the 5G antenna can be synchronously adjusted by driving the adjusting handle so as to meet specific adjusting requirements; after the adjustment is completed, the switching gear and the lifting switching rod are both positioned at the lowest end of the stroke, and the poking plate is rotated to be clamped between the two gear teeth of the fixed gear ring again.

The elevation angle, the direction and the height of a single 5G antenna can be adjusted by arranging the adjusting mechanism without influencing other 5G antennas; the elevation angle of the 5G antenna is adjusted by using the structure of the worm gear and the worm, so that the 5G antenna can be kept fixed after the elevation angle is adjusted, and meanwhile, the elevation angle adjustment of the 5G antenna can be accurately controlled through the rotation angle of the worm; by arranging the switching gear and the lifting switching rod, the 5G antenna can be switched to different adjusting functions, and the adjustment of the height and the orientation is realized; by arranging the poking plate and the poking head, the adjusting mechanism can keep the circumferential direction of the 5G antenna fixed when the antenna is normally used, and workers can rotate the adjusting mechanism to adjust the orientation of the 5G antenna; elevation angle adjusting rod and drive adjustment handle are located the below, and the installer of being convenient for adjusts adjustment mechanism from up climbing the back down, and need not climb to the top of 5G antenna.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 and 3 are schematic structural diagrams of the adjusting mechanism and the 5G antenna.

Fig. 4 is an exploded structural schematic diagram of the adjustment mechanism and the 5G antenna.

FIG. 5 is a cross-sectional structural view of the positioning collar.

Fig. 6 and 7 are schematic structural views of the mounting frame.

Fig. 8 is a schematic structural view of the positioning rotary column.

Fig. 9 is a schematic structural view of the lifter.

Fig. 10 is a schematic structural view of the elevation switching lever.

1. A signal lever; 2. an adjustment mechanism; 21. a mounting frame; 211. positioning blocks; 2111. positioning holes; 2112. a second magnet; 212. an internal thread; 213. a first connection hole; 214. a second connection hole; 22. an elevation angle adjusting mechanism; 221. an elevation adjusting rod; 2211. a worm; 222. a worm gear; 223. a connecting rod; 2231. a sliding groove; 23. a positioning mechanism; 231. positioning the rotating column; 2311. a driven gear; 2312. a limiting sheet; 2313. a card slot; 232. a lifting rod; 2321. a sliding support block; 2322. lifting screw threads; 2323. a limiting shaft; 2324. rotating the connecting hole; 233. a lifting switching rod; 2331. a slide bar; 2332. rotating the chuck; 2333. a first magnet; 2334. a ball head; 234. a switching gear; 2341. clamping teeth; 235. driving the adjustment handle; 2351. a drive gear; 24. a poking plate; 3. a 5G antenna; 31. a first connecting seat; 32. a second connecting seat; 321. a sliding head; 4. positioning the mounting ring; 41. an annular groove; 42. an annular support groove; 43. mounting holes; 5. the ring gear is fixed.

Detailed Description

Example 1

Referring to fig. 1 to 10, a multi-azimuth adjustable 5G communication base station includes a signal rod 1, one or more 5G antennas 3, and an adjusting mechanism 2 for adjusting states or positions of the 5G antennas.

The side wall of the signal rod close to the upper end part is fixedly connected with a positioning mounting ring 4; the adjusting mechanism is slidably clamped on the positioning mounting ring; the adjusting mechanism comprises a mounting frame 21 for mounting the 5G antenna, an elevation angle adjusting mechanism 22 for adjusting the elevation angle of the 5G antenna and a positioning mechanism 23 for adjusting the height and the orientation of the 5G antenna; the 5G antenna is rotatably connected to the outer side of the mounting rack; the elevation angle adjusting mechanism comprises an elevation angle adjusting rod 221 which is vertically arranged and a worm wheel 222 which is used for driving the 5G antenna to rotate; the worm wheel is fixedly connected to a connecting end of the 5G antenna and the mounting rack; the worm wheel is coaxial with the rotation center of the connecting end; the elevation adjusting rod is fixedly connected with a worm 2211 for driving the worm wheel to rotate.

The positioning mechanism comprises a positioning rotating column 231 rotatably connected to the mounting frame, a lifting rod 232 inserted into the positioning rotating column, a lifting switching rod 233 used for switching to a lifting state, a switching gear 234 used for switching to an adjusting direction, and a driving adjusting handle 235 used for driving the positioning rotating column to rotate; the lower end of the positioning rotating column is fixedly connected with a driven gear 2311; a driving gear 2351 is fixedly connected to the driving adjusting handle corresponding to the driven gear; a positioning block 211 for mounting the positioning rotary column is formed at the lower end of the mounting rack; a positioning hole 2111 for the positioning rotating column to pass through is formed in the positioning block; the positioning rotating column is positioned at the upper end and the lower end of the positioning hole and is fixedly connected with limiting pieces 2312 respectively; the positioning rotating column and the mounting rack are kept fixed in the vertical direction; the upper end of the lifting rod is slidably clamped in the positioning mounting ring; and a fixed gear ring 5 in meshing transmission connection with the switching gear is fixedly connected to the periphery of the signal rod.

The upper end of the lifting rod is fixedly connected with a sliding supporting block 2321; an annular groove 41 for the lifting rod to pass through is formed at the lower end of the positioning mounting ring; an annular supporting groove 42 is formed at the upper end of the annular groove; the sliding support block is connected in the annular support groove in a sliding manner; the upper end of the positioning and mounting ring is also formed with a plurality of mounting holes 43 for mounting the sliding support block. Through the annular supporting groove and the supporting block, the mounting frame can be kept fixed in the vertical direction and can rotate along the signal rod, and meanwhile, the mounting frame cannot fall off the positioning mounting ring; simultaneously, because the setting of ring channel is right there is the guide effect in the lifter, is that the lifter is in vertical state all the time to prevent that the mounting bracket from deviating from the outside of signal pole and breaking away from with fixed ring gear.

Because the worm wheel can not drive the worm to rotate, the angle of the 5G antenna after rotation can be kept fixed through the worm, and the elevation angle of the 5G antenna can be conveniently adjusted by a worker. Furthermore, the worm wheel is coaxially provided with an angle scale for accurately adjusting the elevation angle of the 5G antenna.

The elevation angle adjusting rod and the driving part of the driving adjusting handle are both positioned below the lifting rod.

A first connecting seat 31 and a second connecting seat 32 are respectively and fixedly connected to the 5G antenna facing the mounting rack; a first connection hole 213 and a second connection hole 214 are respectively formed at the mounting bracket corresponding to the first connection seat and the second connection seat; the first connecting seat is rotatably connected with the mounting rack, and the rotating center of the first connecting seat is collinear with the center of the first connecting hole; the worm wheel is fixedly connected to the first connecting seat and is coaxial with the first connecting hole; the mounting rack is also rotatably connected with a connecting rod 223; the rotating center of the connecting rod is collinear with the center of the second connecting hole; a sliding groove 2231 is formed at one end of the connecting rod, which is far away from the second connecting hole; one side of the second connecting seat facing the mounting frame is fixedly connected with a sliding head 321; the sliding head is connected in the sliding groove in a sliding mode. Through the setting of connecting rod makes when the 5G antenna rotates, the one end of second connecting seat can normally rotate, in order to guarantee the normal regulation of the angle of elevation of 5G antenna.

A lifting thread 2322 is formed at the upper part of the lifting rod; the upper end of the mounting rack is provided with an internal thread 212 in threaded connection with the lifting thread; a limiting shaft 2323 used for limiting the lower end of the stroke of the 5G antenna in the up-and-down movement is formed below the lifting screw thread of the lifting rod; the limiting shaft is coaxially inserted into the positioning rotating column, so that the lifting rod is prevented from being separated from the positioning rotating column. When the lifting rod rotates, the internal thread moves downwards to abut against the upper end of the limiting shaft, and the mounting rack is located at the lowest end of the stroke, namely the lowest position of 5G antenna adjustment; the upper end stroke of the mounting bracket is determined between the mounting bracket and the mounting ring.

The lifting screw thread has a self-locking function, and the height of the 5G antenna can be kept after the lifting adjustment is completed through the self-locking of the lifting screw thread.

The elevation switching bar includes a sliding bar 2331 coaxially passing through the positioning rotation column; a rotary chuck 2332 with a non-circular section is fixedly connected to the upper end of the sliding rod; the rotary chuck protrudes out of the side wall of the sliding rod; a rotary connecting hole 2324 with the same section as the rotary chuck is formed at the lower end of the lifting rod; when the lifting switching rod slides to the uppermost end, the rotating chuck is always in sliding connection with the rotating connecting hole; when the lifting switching rod slides to the lowest end, the rotating chuck is always separated from the rotating connecting hole. When the lift switching pole slides to the top, through drive adjustment handle rotates and drives the lifter rotates, thereby makes the mounting bracket can reciprocate, realizes the regulation to 5G antenna height.

A first magnet 2333 is fixedly connected to the lower part of the lifting switching rod; the driven gear is made of a magnetic material; when the lifting switching rod moves to the uppermost end, the first magnet is attracted with the driven gear. Or the lower end of the positioning rotating column is fixedly connected with a magnetic material such as a magnet or an iron block attracted with the first magnet. Through setting up first magnet makes the switching rod that goes up and down can keep its ascending position in vertical direction when removing to the top for switching rod and lifter remain connected state all the time, thereby make drive adjustment handle can effectively drive the lifter rotates.

The lower end of the lifting switching rod is fixedly connected with a ball head 2334; the first magnet of the lift switching lever is conveniently detached from the positioning rotation post by using a ball head.

The switching gear is coaxially sleeved on the positioning rotating column and is positioned between the positioning block and the driven gear; a plurality of clamping grooves 2313 are uniformly formed in the upper part of the positioning rotating column below the mounting block along the circumferential direction; a plurality of clamping teeth 2341 matched with the clamping grooves are formed on the inner wall of the switching gear. When the switching gear is located at the upper end of the stroke, the driving adjusting handle rotates to drive the lifting rod to rotate, so that the switching gear rotates around the fixed gear ring, and the orientation of the 5G antenna is adjusted.

The mounting frame is vertically and rotatably connected with a poking plate 24; one side of the poking plate after rotation is clamped between two adjacent gear teeth of the fixed gear ring. The orientation of the mounting frame can be kept unchanged after the mounting frame is rotated through the poking plate. The friction force between the poking plate and the mounting frame enables the state of the poking plate to be kept unchanged after the poking plate is poked.

The switching gear is made of a magnetic material; the lower end of the positioning block is fixedly connected with a second magnet 2112 attracted with the switching gear. When the second magnet is attracted with the switching gear, the position of the switching gear in the vertical direction can be kept, so that the positioning rotating column can be kept connected with the switching gear.

Further, for the convenience of installation, the signal rod is fixedly connected with an installation platform or a bulge for an installer to fall feet, and the installation platform is positioned below the adjusting mechanism.

Furthermore, for reducing the installation time of installation personnel or avoiding unnecessary climbing during adjustment, the elevation angle adjusting rod and the driving adjusting handle are both accurately controlled through a servo motor or a stepping motor.

When the elevation angle of the 5G antenna needs to be adjusted, the poking plate is kept still, and at the moment, an installer rotates the elevation angle adjusting rod to enable the worm to rotate, so that the worm wheel is driven to rotate, and the adjustment of the elevation angle of the 5G antenna is realized; when the 5G antenna needs to be adjusted in a lifting mode, the switching gear is moved to the lowest end of the stroke, the lifting switching rod is moved to the highest end of the stroke, the first magnet and the driven gear are attracted at the moment, and meanwhile the adjusting handle is driven to rotate through rotation, so that the lifting rod rotates to adjust the height of the 5G antenna; when the orientation of the 5G antenna needs to be adjusted, the poking plate is rotated outwards to be separated from the fixed gear ring, the switching gear is moved to the uppermost end of the stroke, the lifting switching rod is moved to the lowermost end of the stroke, the second magnet is attracted with the switching gear, and the orientation of the 5G antenna can be adjusted by driving the adjusting handle to rotate; when the switching gear and the lifting switching rod are both positioned at the uppermost end of the stroke, the orientation and the height of the 5G antenna can be synchronously adjusted by driving the adjusting handle so as to meet specific adjusting requirements; after the adjustment is completed, the switching gear and the lifting switching rod are both positioned at the lowest end of the stroke, and the poking plate is rotated to be clamped between the two gear teeth of the fixed gear ring again.

The elevation angle, the direction and the height of a single 5G antenna can be adjusted by arranging the adjusting mechanism without influencing other 5G antennas; the elevation angle of the 5G antenna is adjusted by using the structure of the worm gear and the worm, so that the 5G antenna can be kept fixed after the elevation angle is adjusted, and meanwhile, the elevation angle adjustment of the 5G antenna can be accurately controlled through the rotation angle of the worm; by arranging the switching gear and the lifting switching rod, the 5G antenna can be switched to different adjusting functions, and the adjustment of the height and the orientation is realized; by arranging the poking plate and the poking head, the adjusting mechanism can keep the circumferential direction of the 5G antenna fixed when the antenna is normally used, and workers can rotate the adjusting mechanism to adjust the orientation of the 5G antenna; elevation angle adjusting rod and drive adjustment handle's drive division are located the below, and the installer of being convenient for is adjusted adjustment mechanism from up climbing back down, and need not climb to the top of 5G antenna.

Claims

1. A multi-azimuth adjustable 5G communication base station comprises a signal rod, one or more 5G antennas and an adjusting mechanism for adjusting the state or position of each 5G antenna; the method is characterized in that:

2. The multi-azimuth adjustable 5G communication base station as claimed in claim 1, wherein: the upper part of the lifting rod is formed with a lifting thread; an internal thread in threaded connection with the lifting thread is formed at the upper end of the mounting rack; a limiting shaft for limiting the lower end of the stroke of the 5G antenna in vertical movement is formed below the lifting screw thread of the lifting rod;

3. The multi-azimuth adjustable 5G communication base station as claimed in claim 1, wherein: the switching gear is coaxially sleeved on the positioning rotating column and is positioned between the positioning block and the driven gear; a plurality of clamping grooves are uniformly formed in the upper part of the positioning rotating column below the mounting block along the circumferential direction; and a plurality of clamping teeth matched with the clamping grooves are formed on the inner wall of the switching gear.

4. The multi-azimuth adjustable 5G communication base station of claim 2, wherein: the lower part of the lifting switching rod is fixedly connected with a first magnet; the driven gear is made of a magnetic material; when the lifting switching rod moves to the uppermost end, the first magnet is attracted with the driven gear.

5. The multi-azimuth adjustable 5G communication base station of claim 3, wherein: the mounting frame is vertically and rotatably connected with a poking plate; one side of the poking plate after rotation is clamped between the gear teeth of the fixed gear ring; the orientation of the mounting frame can be kept unchanged after the mounting frame is rotated through the poking plate.

6. The multi-azimuth adjustable 5G communication base station as claimed in claim 3 or 5, wherein: the switching gear is made of a magnetic material; the lower end of the positioning block is fixedly connected with a second magnet which is attracted with the switching gear.