CN110469761B

CN110469761B - 5G signal enhancement adjusting device

Info

Publication number: CN110469761B
Application number: CN201910806826.XA
Authority: CN
Inventors: 王明程
Original assignee: Qingtian Yuanyuan Technology Co Ltd
Current assignee: Anhui Jingyimen Technology Development Co ltd
Priority date: 2019-08-29
Filing date: 2019-08-29
Publication date: 2020-12-22
Anticipated expiration: 2039-08-29
Also published as: CN110469761A

Abstract

The invention discloses a 5G signal enhancement adjusting device, which relates to the technical field of wireless signal enhancers and comprises a fixed rack, a loading and unloading control mechanism, a lower fixing piece, a hinge rod, an upper fixing piece, an angle adjusting seat, a direction adjusting and enhancing assembly and an angle adjusting and enhancing assembly. The loading and unloading control mechanism is arranged in the middle of the fixed rack, the lower fixing pieces are four, the four lower fixing pieces are uniformly arranged at the lower end of the fixed rack in a surrounding mode, the loading and unloading control mechanism is in transmission connection with the four lower fixing pieces, the loading and unloading control mechanism is uniformly arranged at the upper end of the fixed rack in a surrounding mode, the four hinge rods are hinged to the four upper fixing pieces, the four upper fixing pieces are provided with four upper fixing pieces, the four upper fixing pieces are uniformly arranged at the upper end of the fixed rack in a surrounding mode, the upper ends of the four hinge rods.

Description

5G signal enhancement adjusting device

Technical Field

The invention relates to the technical field of wireless signal intensifiers, in particular to a 5G signal intensifying and adjusting device.

Background

The utility model discloses a router with a signal enhancement device, which has the prior patent number of CN201820982441.X, and comprises a router body, an interface, a base, an antenna, a clamping groove and the signal enhancement device, wherein the base is fixedly arranged at the bottom of the router body; the lower ends of the first signal enhancement device and the second signal enhancement device are fixedly connected with a hoop; the clamp is provided with a locking hole and a notch, and a fixing hole perpendicular to the notch is formed in the clamp; the locking hole is sleeved on the antenna; the area of the first signal enhancement device is one half of that of the second signal enhancement device; the router is provided with a first signal enhancement device and a second signal enhancement device, can enhance signals in two directions, and can prevent the router from deviating and prevent the network cable and the crystal head from being broken. However, the device cannot further enhance the signal in the designated direction, and the direction adjustment of the signal enhancement device is inconvenient.

Disclosure of Invention

The invention aims to provide a 5G signal enhancement adjusting device which has the advantages that the position of a direction adjustment enhancing component is convenient to adjust, signals in a specified direction can be further enhanced, the signal enhancement strength is adjustable, and the device is convenient to assemble and disassemble.

The purpose of the invention is realized by the following technical scheme:

A5G signal enhancement adjusting device comprises a fixed frame, a loading and unloading control mechanism, four lower fixing pieces, four hinge rods, an upper fixing piece, an angle adjusting seat, a direction adjusting and enhancing assembly and an angle adjusting and enhancing assembly, wherein the loading and unloading control mechanism is arranged in the middle of the fixed frame, the four lower fixing pieces are uniformly arranged at the lower end of the fixed frame in a surrounding manner, the loading and unloading control mechanism is in transmission connection with the four lower fixing pieces, the four hinge rods are uniformly arranged on the loading and unloading control mechanism in a surrounding manner, the four upper fixing pieces are uniformly arranged at the upper end of the fixed frame in a surrounding manner, the upper ends of the four hinge rods are respectively hinged on the four upper fixing pieces, the angle adjusting seat is fixedly connected at the upper end of the fixed frame, the direction adjusting and enhancing assembly is arranged on the angle adjusting seat, and the direction adjusting and enhancing assembly, the angle adjustment reinforcing assemblies are arranged in two numbers, the two angle adjustment reinforcing assemblies are symmetrically arranged on the direction adjustment reinforcing assembly, and the two angle adjustment reinforcing assemblies are in transmission connection with the direction adjustment reinforcing assembly.

As further optimization of the technical scheme, the 5G signal enhancement adjusting device comprises a fixed frame, a control device and a signal processing device, wherein the fixed frame comprises a circular underframe, a vertical frame plate, a rectangular through groove, an upper fixed seat, an arc-shaped connecting rod, a motor I and a screw rod; the upper end of circular chassis evenly encircles four perpendicular frame plates of fixed connection, all is provided with the rectangle on four perpendicular frame plates and leads to the groove, and four upper ends of erecting the frame plate are fixed connection one respectively and go up the fixing base, go up fixing base and the crisscross fixed connection in four arc connecting rod intervals on four, and motor I passes through motor frame fixed connection on an arc connecting rod, and the output shaft of motor I passes through the coupling joint lead screw, and the lower extreme of lead screw is rotated through taking a seat bearing and is connected on circular chassis.

As the further optimization of the technical scheme, the 5G signal enhancement adjusting device comprises a loading and unloading control mechanism, a loading and unloading control mechanism and a linkage block, wherein the loading and unloading control mechanism comprises an annular frame, a hinged seat, a rack I and the linkage block; the outer end of the annular frame is uniformly and fixedly connected with four hinged seats in a surrounding manner, the lower ends of the four hinged seats are respectively and fixedly connected with a rack I, and the linkage block is fixedly connected to the annular frame; the annular frame is positioned on the inner sides of the four vertical frame plates, the four hinge seats are respectively connected in the four rectangular through grooves in a sliding fit manner, the lower ends of the four hinge rods are respectively connected to the four hinge seats in a rotating manner through hinge shafts, and the linkage block is connected to the lead screw in a threaded fit manner; the rack I is in transmission connection with the lower fixing piece.

As further optimization of the technical scheme, the invention relates to a 5G signal enhancement adjusting device, wherein a lower fixing piece comprises a lower arc-shaped fixing plate, a guide rod, a fixing plate, an outer screw rod, an inner thread sleeve and a gear I; the inner end and the outer end of the guide rod are respectively and fixedly connected with a lower arc-shaped fixing plate and a fixing plate, the inner end and the outer end of the outer screw rod are respectively and rotatably connected to the lower arc-shaped fixing plate and the fixing plate through bearings with seats, the inner thread sleeve is connected to the outer screw rod in a threaded fit mode, and the gear I is fixedly connected to the inner thread sleeve; the lower arc-shaped fixing plate is located on the inner side of the circular bottom frame, the guide rod is connected to the lower end of the vertical frame plate in a sliding fit mode, the internal thread sleeve is connected to the outer end of the circular bottom frame in a rotating fit mode through the bearing with the seat, the external thread rod is connected to the circular bottom frame in a clearance fit mode, and the rack I is in meshing transmission connection with the gear I.

As further optimization of the technical scheme, the 5G signal enhancement adjusting device comprises an upper fixing piece, a lower fixing piece and a control device, wherein the upper fixing piece comprises an upper arc-shaped fixing plate, a trapezoidal rod, an outer fixing seat and a circular sliding rod; the inner of trapezoidal pole and circle slide bar all fixed connection on last arc fixed plate, the outer end of trapezoidal pole and circle slide bar all fixed connection on outer fixing base, trapezoidal pole and circle slide bar all sliding fit connect on last fixing base, the upper end of hinge bar is passed through the articulated shaft and is rotated and be connected on outer fixing base.

As further optimization of the technical scheme, the 5G signal enhancement adjusting device comprises an angle adjusting seat, a first adjusting seat, a second adjusting seat and a third adjusting seat, wherein the angle adjusting seat comprises an annular top frame, a supporting rod, an outer gear ring, an annular groove and a semi-annular trapezoidal sliding rail; four bracing pieces of lower extreme fixed connection of annular roof-rack, four bracing pieces are fixed connection respectively on four arc connecting rods, and outer ring gear fixed connection is provided with the ring channel on the annular roof-rack, and two trapezoidal slide rail symmetries fixed connection of semiannulus are in the upper end of annular roof-rack, and two trapezoidal slide rail of semiannulus form a confined circular.

As a further optimization of the technical scheme, the 5G signal enhancement adjusting device comprises a direction adjusting plate, a storage groove, an upper sliding groove, a lower sliding groove, a rack ii, a side plate, a bidirectional screw, a screw base, a screwing ring, an arc-shaped sliding block, an arc-shaped connecting plate, a motor ii, a motor base and a gear ii; the direction adjusting plate is symmetrically provided with two accommodating grooves, the upper end of the direction adjusting plate is provided with two upper sliding grooves, and the lower end of the direction adjusting plate is provided with two lower sliding grooves; the accommodating groove, the upper sliding groove and the lower sliding groove are communicated; two ends of the rack II are respectively and fixedly connected to a side plate, the two side plates are both fixedly connected to the upper end of the direction adjusting plate, two ends of the bidirectional screw are respectively and rotatably connected with a screw seat through a bearing with a seat, the two screw seats are both fixedly connected to the upper end of the direction adjusting plate, and the screwing ring is fixedly connected to the middle part of the bidirectional screw; the lower end of the direction adjusting plate is symmetrically and fixedly connected with two arc-shaped sliding blocks, an arc-shaped connecting plate is fixedly connected between the two arc-shaped sliding blocks, a motor II is fixedly connected onto the arc-shaped connecting plate through a motor base, and an output shaft of the motor II is fixedly connected with a gear II; two arc slider are all sliding fit connection in the ring channel, and the arc connecting plate is located the ring channel, and motor cabinet sliding fit connects on half annular trapezoidal slide rail, and gear II is connected with outer ring gear meshing transmission.

As further optimization of the technical scheme, the 5G signal enhancement adjusting device comprises an angle adjustment enhancement assembly, a control assembly and a control assembly, wherein the angle adjustment enhancement assembly comprises a rotating shaft, an L-shaped upper sliding block, a lower sliding block, an angle adjusting plate and a gear III; the upper and lower both ends of axis of rotation are rotated through taking the seat bearing respectively and are connected L type top shoe and lower slider, angle adjusting plate fixed connection is at the middle part of axis of rotation, III fixed connection of gear is on the top of axis of rotation, L type top shoe and lower slider are sliding fit respectively and are connected at last spout and lower chute, angle adjusting plate is located and accomodates the inslot, L type top shoe passes through screw-thread fit and connects in one side of two-way screw rod, gear III is connected with II meshing transmissions of rack.

The 5G signal enhancement adjusting device has the beneficial effects that:

according to the 5G signal enhancement adjusting device, the position of the direction adjustment enhancing component is convenient to adjust, so that the enhancement of a signal in a specified direction is realized, the two angle adjustment enhancing components can be unfolded towards the outer end, the working area of the direction adjustment enhancing component is increased, the two angle adjustment enhancing components can rotate while being unfolded, a certain angle is formed between the two angle adjustment enhancing components and the direction adjustment enhancing component, the effect of further enhancing the signal in the direction towards which the direction adjustment enhancing component faces is achieved, and the intensity of signal enhancement is adjustable; the device is provided with lower mounting and last mounting, and loading and unloading control mechanism can drive down mounting and last mounting simultaneously and press from both sides tightly to fix the device on the signal tower more firm, avoid being blown and take place the displacement or drop, play dual fail-safe's effect, and install and remove the convenience.

Drawings

FIG. 1 is a first schematic structural diagram of the present invention;

FIG. 2 is a schematic diagram of the structure of the invention in cooperation with a signal tower;

FIG. 3 is a second schematic structural view of the present invention;

FIG. 4 is a third schematic structural view of the present invention;

FIG. 5 is a schematic structural view of a stationary gantry;

FIG. 6 is a schematic structural view of a loading/unloading control mechanism;

FIG. 7 is a schematic structural view of the lower fixing member;

FIG. 8 is a schematic structural view of an upper fixing member;

FIG. 9 is a schematic structural view of the angle adjustment base;

FIG. 10 is a first schematic view of the orientation adjustment enhancing assembly;

FIG. 11 is a second schematic structural view of the direction adjustment enhancing assembly;

fig. 12 is a schematic view of the structure of the angle-adjustment enhancing assembly.

In the figure: a fixed frame 1; a circular chassis 1-1; 1-2 of vertical frame plates; 1-3 rectangular through grooves; an upper fixing seat 1-4; 1-5 of an arc connecting rod; 1-6 parts of a motor; 1-7 parts of a screw rod; a loading and unloading control mechanism 2; a ring frame 2-1; a hinged seat 2-2; a rack I2-3; 2-4 of a linkage block; a lower fixing member 3; a lower arc-shaped fixing plate 3-1; 3-2 of a guide rod; 3-3 of a fixing plate; 3-4 parts of an outer screw; 3-5 parts of an internal thread sleeve; 3-6 parts of a gear I; a hinge lever 4; an upper fixing member 5; an upper arc-shaped fixing plate 5-1; a trapezoidal bar 5-2; 5-3 of an outer fixed seat; 5-4 of a circular slide bar; an angle adjusting seat 6; an annular top frame 6-1; 6-2 of a support rod; 6-3 of an outer gear ring; 6-4 of an annular groove; 6-5 of a semi-annular trapezoidal sliding rail; a direction adjustment enhancing component 7; a direction adjusting plate 7-1; a housing groove 7-2; 7-3 of an upper chute; 7-4 of a lower chute; 7-5 of a rack; 7-6 of side plates; 7-7 of a bidirectional screw; 7-8 of a screw seat; 7-9 of a screwing ring; 7-10 parts of an arc-shaped sliding block; arc-shaped connecting plates 7-11; 7-12 of a motor II; 7-13 of a motor base; gears II 7-14; an angle adjustment enhancing component 8; a rotating shaft 8-1; an L-shaped upper slide block 8-2; 8-3 of a lower sliding block; 8-4 of an angle adjusting plate; and 8-5 of a gear.

Detailed Description

The present invention is described in further detail below with reference to the accompanying figures 1-12 and the detailed description.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, and a 5G signal enhancement adjusting device includes a fixed frame 1, a loading and unloading control mechanism 2, lower fixing members 3, four hinge rods 4, upper fixing members 5, an angle adjusting seat 6, a direction adjusting and enhancing assembly 7, and an angle adjusting and enhancing assembly 8, wherein the loading and unloading control mechanism 2 is disposed in the middle of the fixed frame 1, the four lower fixing members 3 are disposed in the lower end of the fixed frame 1, the loading and unloading control mechanism 2 is in transmission connection with the four lower fixing members 3, the loading and unloading control mechanism 2 is hinged with the four hinge rods 4 in a surrounding manner, the four upper fixing members 5 are disposed in the upper end of the fixed frame 1, the upper ends of the four hinge rods 4 are respectively hinged with the four upper fixing members 5, and the angle adjusting seat 6 is fixedly connected to the upper end of the fixed frame 1, the direction regulation reinforcing component 7 is arranged on the angle regulation seat 6, the direction regulation reinforcing component 7 is in transmission connection with the angle regulation seat 6, the angle regulation reinforcing component 8 is provided with two, the two angle regulation reinforcing components 8 are symmetrically arranged on the direction regulation reinforcing component 7, and the two angle regulation reinforcing components 8 are in transmission connection with the direction regulation reinforcing component 7. When the device is used, the device is sleeved on a signal tower main body from the upper part of the signal tower, so that a direction adjusting and reinforcing component 7 corresponds to the position of an antenna on the signal tower, a motor I1-6 on a fixed rack 1 is started to drive a loading and unloading control mechanism 2 to move downwards, the loading and unloading control mechanism 2 drives four lower fixing pieces 3 to move inwards and clamp on the signal tower, meanwhile, the loading and unloading control mechanism 2 drives four upper fixing pieces 5 to move inwards and clamp on the signal tower through four hinged rods 4, the device is stably fixed on the signal tower through the four lower fixing pieces 3 and the four upper fixing pieces 5, the motor II 7-12 on the direction adjusting and reinforcing component 7 drives the direction adjusting and reinforcing component 7 to rotate on an angle adjusting seat 6, so that the direction of the direction adjusting and reinforcing component 7 is changed, and the enhancement of a specified direction signal is realized, the direction adjusting and enhancing component 7 is adjusted to drive the two angle adjusting and enhancing components 8 to expand towards the outer ends, the working area of the direction adjusting and enhancing component 7 is increased, the two angle adjusting and enhancing components 8 can rotate while expanding, a certain angle is formed between the two angle adjusting and enhancing components 7, the effect of further enhancing signals of the direction in which the direction adjusting and enhancing component 7 faces is achieved, the angle between the two angle adjusting and enhancing components 8 is controlled by adjusting the distance between the two angle adjusting and enhancing components 8, and the strength of the signal enhancement in the specified direction is changed; through reverse control motor I1-6, make four lower mounting 3 and four last mounting 5 outwards slide simultaneously and keep away from the signal tower, can lift the device off from the signal tower, loading and unloading are convenient.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, wherein the fixed frame 1 includes a circular bottom frame 1-1, a vertical frame plate 1-2, a rectangular through groove 1-3, an upper fixed seat 1-4, an arc-shaped connecting rod 1-5, a motor i 1-6 and a screw rod 1-7; the upper end of a circular underframe 1-1 is uniformly and fixedly connected with four vertical frame plates 1-2 in a surrounding mode, rectangular through grooves 1-3 are formed in the four vertical frame plates 1-2, the upper ends of the four vertical frame plates 1-2 are respectively and fixedly connected with an upper fixed seat 1-4, the four upper fixed seats 1-4 are fixedly connected with four arc connecting rods 1-5 in an interval and staggered mode, motors I1-6 are fixedly connected onto the arc connecting rods 1-5 through motor frames, output shafts of the motors I1-6 are connected with lead screws 1-7 through shaft couplings, and the lower ends of the lead screws 1-7 are rotatably connected onto the circular underframe 1-1 through bearings with seats. When the fixing frame is used, the whole fixing frame 1 is sleeved at the position of the signal tower main body close to the antenna from bottom to top.

The third concrete implementation mode:

the present embodiment will be described with reference to fig. 1-12, wherein the loading and unloading control mechanism 2 comprises a ring frame 2-1, a hinge base 2-2, a rack i 2-3 and a linkage block 2-4; the outer end of the annular frame 2-1 is uniformly and fixedly connected with four hinged seats 2-2 in a surrounding manner, the lower ends of the four hinged seats 2-2 are respectively and fixedly connected with a rack I2-3, and the linkage block 2-4 is fixedly connected to the annular frame 2-1; the annular frame 2-1 is positioned at the inner sides of the four vertical frame plates 1-2, the four hinge seats 2-2 are respectively connected in the four rectangular through grooves 1-3 in a sliding fit manner, the lower ends of the four hinge rods 4 are respectively connected on the four hinge seats 2-2 in a rotating manner through hinge shafts, and the linkage blocks 2-4 are connected on the screw rods 1-7 in a threaded fit manner; the rack I2-3 is in transmission connection with the lower fixing piece 3. When the loading and unloading control mechanism 2 is used, the motors I1-6 are connected with a power supply and a control switch through leads and are started, the motors I1-6 drive the screw rods 1-7 to rotate, the screw rods 1-7 and the linkage blocks 2-4 are connected through threads to generate relative displacement and drive the linkage blocks 2-4 to move downwards, the linkage blocks 2-4 drive the annular frame 2-1 to move downwards, the annular frame 2-1 drives the four hinged seats 2-2 and the four racks I2-3 to move downwards simultaneously, the four hinged seats 2-2 drive the four upper fixing pieces 5 to move inwards through the four hinged rods 4, and the four racks I2-3 drive the four lower fixing pieces 3 to move inwards.

The fourth concrete implementation mode:

referring to fig. 1-12, the lower fixing member 3 includes a lower arc-shaped fixing plate 3-1, a guide rod 3-2, a fixing plate 3-3, an outer screw rod 3-4, an inner screw sleeve 3-5 and a gear i 3-6; the inner end and the outer end of the guide rod 3-2 are respectively and fixedly connected with a lower arc-shaped fixing plate 3-1 and a fixing plate 3-3, the inner end and the outer end of an outer screw rod 3-4 are respectively and rotatably connected to the lower arc-shaped fixing plate 3-1 and the fixing plate 3-3 through a bearing with a seat, an inner thread sleeve 3-5 is connected to the outer screw rod 3-4 through thread fit, and a gear I3-6 is fixedly connected to the inner thread sleeve 3-5; the lower arc-shaped fixing plate 3-1 is located on the inner side of the circular bottom frame 1-1, the guide rod 3-2 is connected to the lower end of the vertical frame plate 1-2 in a sliding fit mode, the internal thread sleeve 3-5 is connected to the outer end of the circular bottom frame 1-1 in a rotating fit mode through a bearing with a seat, the external thread rod 3-4 is connected to the circular bottom frame 1-1 in a clearance fit mode, and the rack I2-3 is in meshing transmission connection with the gear I3-6. When the lower fixing piece 3 is used, the rack I2-3 moves downwards to drive the gear I3-6 to rotate, the gear I3-6 drives the internal thread sleeve 3-5 to rotate, the internal thread sleeve 3-5 and the external thread rod 3-4 are connected through threads to generate relative displacement to drive the external thread rod 3-4 to move inwards, the external thread rod 3-4 drives the lower arc-shaped fixing plate 3-1 to move inwards, and the guide rod 3-2 plays a role in limiting and guiding the lower arc-shaped fixing plate 3-1; and the lower arc-shaped fixing plates 3-1 on the four lower fixing pieces 3 simultaneously move inwards to be clamped on the signal tower, so that the device is fixed on the signal tower.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 12, wherein the upper fixing member 5 includes an upper arc-shaped fixing plate 5-1, a trapezoidal bar 5-2, an outer fixing seat 5-3, and a circular sliding bar 5-4; the inner ends of the trapezoid rod 5-2 and the circular slide rod 5-4 are fixedly connected to the upper arc-shaped fixing plate 5-1, the outer ends of the trapezoid rod 5-2 and the circular slide rod 5-4 are fixedly connected to the outer fixing seat 5-3, the trapezoid rod 5-2 and the circular slide rod 5-4 are connected to the upper fixing seat 1-4 in a sliding fit mode, and the upper end of the hinge rod 4 is rotatably connected to the outer fixing seat 5-3 through a hinge shaft. When the upper fixing piece 5 is used, the hinge base 2-2 moves downwards to drive the outer fixing base 5-3 to move inwards through the hinge rod 4, the outer fixing base 5-3 drives the upper arc-shaped fixing plate 5-1 to move inwards through the circular slide rod 5-4, and the trapezoidal rod 5-2 plays a role in limiting and guiding the upper arc-shaped fixing plate 5-1; the upper arc-shaped fixing plates 5-1 on the four upper fixing pieces 5 simultaneously move inwards and are clamped on the signal tower, so that the device is more stably fixed on the signal tower.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 12, where the angle adjusting base 6 includes an annular top frame 6-1, a support rod 6-2, an outer gear ring 6-3, an annular groove 6-4, and a semi-annular trapezoidal slide rail 6-5; the lower end of the annular top frame 6-1 is fixedly connected with four supporting rods 6-2, the four supporting rods 6-2 are respectively fixedly connected to four arc-shaped connecting rods 1-5, the outer gear ring 6-3 is fixedly connected to the annular top frame 6-1, the annular top frame 6-1 is provided with an annular groove 6-4, the two semi-annular trapezoidal sliding rails 6-5 are symmetrically and fixedly connected to the upper end of the annular top frame 6-1, and the two semi-annular trapezoidal sliding rails 6-5 form a closed circle.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 12, where the direction adjustment enhancing assembly 7 includes a direction adjustment plate 7-1, a storage groove 7-2, an upper slide groove 7-3, a lower slide groove 7-4, a rack bar ii 7-5, a side plate 7-6, a bidirectional screw 7-7, a screw base 7-8, a screw ring 7-9, an arc-shaped slider 7-10, an arc-shaped connecting plate 7-11, a motor ii 7-12, a motor base 7-13, and a gear ii 7-14; the direction adjusting plate 7-1 is symmetrically provided with two accommodating grooves 7-2, the upper end of the direction adjusting plate 7-1 is provided with two upper sliding grooves 7-3, and the lower end of the direction adjusting plate 7-1 is provided with two lower sliding grooves 7-4; the accommodating groove 7-2, the upper sliding groove 7-3 and the lower sliding groove 7-4 are communicated; two ends of a rack II 7-5 are respectively fixedly connected to a side plate 7-6, the two side plates 7-6 are both fixedly connected to the upper end of a direction adjusting plate 7-1, two ends of a bidirectional screw 7-7 are respectively rotatably connected with a screw seat 7-8 through a bearing with a seat, the two screw seats 7-8 are both fixedly connected to the upper end of the direction adjusting plate 7-1, and a screwing ring 7-9 is fixedly connected to the middle part of the bidirectional screw 7-7; the lower end of the direction adjusting plate 7-1 is symmetrically and fixedly connected with two arc-shaped sliding blocks 7-10, an arc-shaped connecting plate 7-11 is fixedly connected between the two arc-shaped sliding blocks 7-10, a motor II 7-12 is fixedly connected onto the arc-shaped connecting plate 7-11 through a motor base 7-13, and an output shaft of the motor II 7-12 is fixedly connected with a gear II 7-14; the two arc-shaped sliding blocks 7-10 are connected in the annular groove 6-4 in a sliding fit mode, the arc-shaped connecting plates 7-11 are located in the annular groove 6-4, the motor bases 7-13 are connected on the semi-annular trapezoidal sliding rails 6-5 in a sliding fit mode, and the gears II 7-14 are in meshed transmission connection with the outer gear ring 6-3. When the direction adjusting and reinforcing component 7 is used, the motors II 7-12 are connected with a power supply and a control switch through leads and are started, the motors II 7-12 drive the gears II 7-14 to rotate, the gears II 7-14 are connected with the outer gear ring 6-3 in a meshing transmission way to drive the direction adjusting and reinforcing component 7 to integrally rotate on the annular top frame 6-1 around the axis of the annular top frame 6-1, the two arc-shaped sliding blocks 7-10 slide in the annular groove 6-4, therefore, the direction of the direction adjusting plate 7-1 is changed, the signal generated by the antenna is folded back on the direction adjusting plate 7-1, the signal in the designated direction is enhanced, the motor base 7-13 is matched with the semi-annular trapezoidal slide rail 6-5 to play a role in limiting and guiding the direction adjusting plate 7-1, and the direction adjusting plate 7-1 is prevented from being separated from the annular top frame 6-1.

The specific implementation mode is eight:

the present embodiment will be described with reference to fig. 1 to 12, wherein the angle adjustment enhancing assembly 8 comprises a rotating shaft 8-1, an L-shaped upper slide block 8-2, a lower slide block 8-3, an angle adjusting plate 8-4 and a gear iii 8-5; the upper end and the lower end of a rotating shaft 8-1 are respectively connected with an L-shaped upper sliding block 8-2 and a lower sliding block 8-3 in a rotating mode through a bearing with a seat, an angle adjusting plate 8-4 is fixedly connected to the middle of the rotating shaft 8-1, a gear III 8-5 is fixedly connected to the top end of the rotating shaft 8-1, the L-shaped upper sliding block 8-2 and the lower sliding block 8-3 are respectively connected into an upper sliding groove 7-3 and a lower sliding groove 7-4 in a sliding fit mode, the angle adjusting plate 8-4 is located in the accommodating groove 7-2, the L-shaped upper sliding block 8-2 is connected to one side of a bidirectional screw 7-7 in a threaded fit mode, and the gear III 8-5 is in. When the angle adjustment enhancing component 8 is used, the screwing ring 7-9 is rotated, the screwing ring 7-9 drives the bidirectional screw 7-7 to rotate, the bidirectional screw 7-7 drives the two L-shaped upper sliding blocks 8-2 to slide away from each other, the two L-shaped upper sliding blocks 8-2 drive the two angle adjusting plates 8-4 to slide away from each other through the two rotating shafts 8-1, the two angle adjusting plates 8-4 move outwards to increase the working area of the direction adjusting plate 7-1 and increase the signal intensity, meanwhile, the two gears III 8-5 on the two rotating shafts 8-1 also slide away from each other, the two gears III 8-5 are meshed with the rack II 7-5 to be in transmission connection to drive the two gears III 8-5 to rotate, and the two gears III 8-5 drive the two rotating shafts 8-1 to rotate, the two rotating shafts 8-1 drive the two angle adjusting plates 8-4 to rotate, the two angle adjusting plates 8-4 rotate when moving outwards, a certain angle is formed between the two angle adjusting plates 8-4 and the direction adjusting plate 7-1, the effect of further enhancing signals in the direction in which the direction adjusting and enhancing assembly 7 faces is achieved, the larger the distance between the two angle adjusting plates 8-4 is, the smaller the angle between the two angle adjusting plates 8-4 is, the stronger the effect of enhancing the signals is, and vice versa.

The invention relates to a working principle of a 5G signal enhancement adjusting device, which comprises the following steps: when the device is used, the device is sleeved on a signal tower main body from the upper part of the signal tower, so that a direction adjusting and reinforcing component 7 corresponds to the position of an antenna on the signal tower, a motor I1-6 on a fixed rack 1 is started to drive a loading and unloading control mechanism 2 to move downwards, the loading and unloading control mechanism 2 drives four lower fixing pieces 3 to move inwards and clamp on the signal tower, meanwhile, the loading and unloading control mechanism 2 drives four upper fixing pieces 5 to move inwards and clamp on the signal tower through four hinged rods 4, the device is stably fixed on the signal tower through the four lower fixing pieces 3 and the four upper fixing pieces 5, the motor II 7-12 on the direction adjusting and reinforcing component 7 drives the direction adjusting and reinforcing component 7 to rotate on an angle adjusting seat 6, so that the direction of the direction adjusting and reinforcing component 7 is changed, and the enhancement of a specified direction signal is realized, the direction adjusting and enhancing component 7 is adjusted to drive the two angle adjusting and enhancing components 8 to expand towards the outer ends, the working area of the direction adjusting and enhancing component 7 is increased, the two angle adjusting and enhancing components 8 can rotate while expanding, a certain angle is formed between the two angle adjusting and enhancing components 7, the effect of further enhancing signals of the direction in which the direction adjusting and enhancing component 7 faces is achieved, the angle between the two angle adjusting and enhancing components 8 is controlled by adjusting the distance between the two angle adjusting and enhancing components 8, and the strength of the signal enhancement in the specified direction is changed; through reverse control motor I1-6, make four lower mounting 3 and four last mounting 5 outwards slide simultaneously and keep away from the signal tower, can lift the device off from the signal tower, loading and unloading are convenient.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a 5G signal enhancement adjusting device, includes fixed frame (1), loading and unloading control mechanism (2), lower mounting (3), hinge bar (4), goes up mounting (5), angle modulation seat (6), direction regulation reinforcing component (7) and angle modulation reinforcing component (8), its characterized in that: the loading and unloading control mechanism (2) is arranged in the middle of the fixed rack (1), four lower fixing pieces (3) are arranged, four lower fixing pieces (3) are uniformly arranged at the lower end of the fixed rack (1) in a surrounding manner, the loading and unloading control mechanism (2) is in transmission connection with the four lower fixing pieces (3), four hinged rods (4) are uniformly hinged on the loading and unloading control mechanism (2) in a surrounding manner, four upper fixing pieces (5) are arranged, four upper fixing pieces (5) are uniformly arranged at the upper end of the fixed rack (1) in a surrounding manner, the upper ends of the four hinged rods (4) are respectively hinged on the four upper fixing pieces (5), an angle adjusting seat (6) is fixedly connected at the upper end of the fixed rack (1), a direction adjusting reinforcing component (7) is arranged on the angle adjusting seat (6), the direction adjusting reinforcing component (7) is in transmission connection with the angle adjusting seat (6), and two angle adjusting reinforcing components (8) are, two angle modulation reinforcing component (8) symmetry sets up on direction modulation reinforcing component (7), and two angle modulation reinforcing component (8) all are connected with direction modulation reinforcing component (7) transmission.

2. The apparatus of claim 1, wherein the signal enhancement adjusting device for 5G signal comprises: the fixed rack (1) comprises a circular underframe (1-1), a vertical frame plate (1-2), a rectangular through groove (1-3), an upper fixed seat (1-4), an arc connecting rod (1-5), a motor I (1-6) and a lead screw (1-7); the upper end of a circular chassis (1-1) is uniformly and fixedly connected with four vertical frame plates (1-2) in a surrounding mode, rectangular through grooves (1-3) are formed in the four vertical frame plates (1-2), the upper ends of the four vertical frame plates (1-2) are respectively and fixedly connected with an upper fixing seat (1-4), the four upper fixing seats (1-4) and four arc-shaped connecting rods (1-5) are fixedly connected in a staggered mode at intervals, a motor I (1-6) is fixedly connected onto one arc-shaped connecting rod (1-5) through a motor frame, an output shaft of the motor I (1-6) is connected with a lead screw (1-7) through a coupler, and the lower end of the lead screw (1-7) is rotatably connected onto the circular chassis (1-1.

3. The apparatus of claim 2, wherein the signal enhancement adjusting device for 5G signal comprises: the loading and unloading control mechanism (2) comprises an annular frame (2-1), a hinged seat (2-2), a rack I (2-3) and a linkage block (2-4); the outer end of the annular frame (2-1) is uniformly and fixedly connected with four hinged seats (2-2) in a surrounding manner, the lower ends of the four hinged seats (2-2) are respectively and fixedly connected with a rack I (2-3), and the linkage block (2-4) is fixedly connected to the annular frame (2-1); the annular frame (2-1) is positioned at the inner sides of the four vertical frame plates (1-2), the four hinge seats (2-2) are respectively connected in the four rectangular through grooves (1-3) in a sliding fit manner, the lower ends of the four hinge rods (4) are respectively connected on the four hinge seats (2-2) in a rotating manner through hinge shafts, and the linkage blocks (2-4) are connected on the lead screws (1-7) in a threaded fit manner; the rack I (2-3) is in transmission connection with the lower fixing piece (3).

4. The apparatus of claim 3, wherein the signal enhancement adjusting device for 5G signal comprises: the lower fixing piece (3) comprises a lower arc-shaped fixing plate (3-1), a guide rod (3-2), a fixing plate (3-3), an outer screw rod (3-4), an inner thread sleeve (3-5) and a gear I (3-6); the inner end and the outer end of the guide rod (3-2) are respectively and fixedly connected with a lower arc-shaped fixing plate (3-1) and a fixing plate (3-3), the inner end and the outer end of the outer screw rod (3-4) are respectively and rotatably connected to the lower arc-shaped fixing plate (3-1) and the fixing plate (3-3), the inner thread sleeve (3-5) is connected to the outer screw rod (3-4) in a threaded fit mode, and the gear I (3-6) is fixedly connected to the inner thread sleeve (3-5); the lower arc-shaped fixing plate (3-1) is located on the inner side of the circular bottom frame (1-1), the guide rod (3-2) is connected to the lower end of the vertical frame plate (1-2) in a sliding fit mode, the internal thread sleeve (3-5) is connected to the outer end of the circular bottom frame (1-1) in a rotating fit mode, the external screw rod (3-4) is connected to the circular bottom frame (1-1) in a clearance fit mode, and the rack I (2-3) is in meshing transmission connection with the gear I (3-6).

5. The apparatus of claim 4, wherein the signal enhancement adjusting device for 5G signal comprises: the upper fixing piece (5) comprises an upper arc-shaped fixing plate (5-1), a trapezoidal rod (5-2), an outer fixing seat (5-3) and a circular sliding rod (5-4); the inner ends of the trapezoidal rod (5-2) and the circular slide rod (5-4) are fixedly connected to the upper arc-shaped fixing plate (5-1), the outer ends of the trapezoidal rod (5-2) and the circular slide rod (5-4) are fixedly connected to the outer fixing seat (5-3), the trapezoidal rod (5-2) and the circular slide rod (5-4) are connected to the upper fixing seat (1-4) in a sliding fit mode, and the upper end of the hinge rod (4) is rotatably connected to the outer fixing seat (5-3) through a hinge shaft.

6. The apparatus of claim 5G signal enhancement adjusting, wherein: the angle adjusting seat (6) comprises an annular top frame (6-1), a supporting rod (6-2), an outer gear ring (6-3), an annular groove (6-4) and a semi-annular trapezoidal sliding rail (6-5); the lower end of the annular top frame (6-1) is fixedly connected with four supporting rods (6-2), the four supporting rods (6-2) are respectively and fixedly connected onto four arc-shaped connecting rods (1-5), the outer gear ring (6-3) is fixedly connected onto the annular top frame (6-1), an annular groove (6-4) is formed in the annular top frame (6-1), the two semi-annular trapezoidal sliding rails (6-5) are symmetrically and fixedly connected to the upper end of the annular top frame (6-1), and the two semi-annular trapezoidal sliding rails (6-5) form a closed circle.

7. The apparatus of claim 6, wherein the signal enhancement adjusting device for 5G signal comprises: the direction adjusting and reinforcing component (7) comprises a direction adjusting plate (7-1), a containing groove (7-2), an upper sliding groove (7-3), a lower sliding groove (7-4), a rack II (7-5), a side plate (7-6), a bidirectional screw (7-7), a screw seat (7-8), a screwing ring (7-9), an arc-shaped sliding block (7-10), an arc-shaped connecting plate (7-11), a motor II (7-12), a motor seat (7-13) and a gear II (7-14); two accommodating grooves (7-2) are symmetrically arranged on the direction adjusting plate (7-1), two upper sliding grooves (7-3) are arranged at the upper end of the direction adjusting plate (7-1), and two lower sliding grooves (7-4) are arranged at the lower end of the direction adjusting plate (7-1); the accommodating groove (7-2), the upper sliding groove (7-3) and the lower sliding groove (7-4) are communicated; two ends of the rack II (7-5) are respectively and fixedly connected with a side plate (7-6), the two side plates (7-6) are both fixedly connected with the upper end of the direction adjusting plate (7-1), two ends of the bidirectional screw (7-7) are respectively and rotatably connected with a screw seat (7-8), the two screw seats (7-8) are both fixedly connected with the upper end of the direction adjusting plate (7-1), and the screwing ring (7-9) is fixedly connected with the middle part of the bidirectional screw (7-7); the lower end of a direction adjusting plate (7-1) is symmetrically and fixedly connected with two arc-shaped sliding blocks (7-10), an arc-shaped connecting plate (7-11) is fixedly connected between the two arc-shaped sliding blocks (7-10), a motor II (7-12) is fixedly connected onto the arc-shaped connecting plate (7-11) through a motor base (7-13), and an output shaft of the motor II (7-12) is fixedly connected with a gear II (7-14); the two arc-shaped sliding blocks (7-10) are connected in the annular groove (6-4) in a sliding fit mode, the arc-shaped connecting plates (7-11) are located in the annular groove (6-4), the motor bases (7-13) are connected on the semi-annular trapezoidal sliding rails (6-5) in a sliding fit mode, and the gears II (7-14) are in meshed transmission connection with the outer gear ring (6-3).

8. The apparatus of claim 7, wherein the signal enhancement adjusting device for 5G signal comprises: the angle adjusting and reinforcing component (8) comprises a rotating shaft (8-1), an L-shaped upper sliding block (8-2), a lower sliding block (8-3), an angle adjusting plate (8-4) and a gear III (8-5); the upper end and the lower end of a rotating shaft (8-1) are respectively rotatably connected with an L-shaped upper sliding block (8-2) and a lower sliding block (8-3), an angle adjusting plate (8-4) is fixedly connected to the middle of the rotating shaft (8-1), a gear III (8-5) is fixedly connected to the top end of the rotating shaft (8-1), the L-shaped upper sliding block (8-2) and the lower sliding block (8-3) are respectively connected in a sliding fit mode in an upper sliding groove (7-3) and a lower sliding groove (7-4), the angle adjusting plate (8-4) is located in a containing groove (7-2), the L-shaped upper sliding block (8-2) is connected to one side of a bidirectional screw rod (7-7) in a threaded fit mode, and the gear III (8-5) is in meshed transmission connection with a rack II (7-5.