CN111244603A

CN111244603A - 5G mobile communication signal inductor

Info

Publication number: CN111244603A
Application number: CN202010025591.3A
Authority: CN
Inventors: 谢永宁; 赖丽君; 李志护; 谢剑嘉; 林涵; 张晓晶; 林燕红; 谢瑞玲
Original assignee: Fujian Zaodao Culture Media Co Ltd
Current assignee: CERTUSNET Corp.
Priority date: 2020-01-10
Filing date: 2020-01-10
Publication date: 2020-06-05
Anticipated expiration: 2040-01-10
Also published as: CN111244603B

Abstract

The invention discloses a 5G mobile communication signal sensor, which structurally comprises an underframe, a supporting rod, a shaft sleeve, a control box, an adjusting structure and an induction antenna, wherein the supporting rod is vertically arranged at the upper end of the underframe; set up rotatory adaptation mechanism in rotatory conduction structure upper end, can be even rotate and slow detection, make the signal that the response detected more stable to make the communication signal that the response detected more accurate, reduced the number of times that the response detected, and then reduced work load.

Description

5G mobile communication signal inductor

Technical Field

The invention belongs to the field of 5G mobile communication, and particularly relates to a 5G mobile communication signal sensor.

Background

The 5G mobile communication, i.e. the fifth generation mobile communication technology, is an improved technology of 4G at present, and as the 5G mobile communication technology is gradually popularized, 5G mobile communication base stations will be continuously covered, and when these base stations are built, the 5G mobile communication signals in their areas need to be sensed and detected, so that the 5G mobile communication signal sensors need to be used to detect the 5G mobile communication signals in their areas, but the prior art has the following disadvantages:

because the communication signal in the area near the 5G mobile communication base station is in a random coverage mode, and surrounding buildings can influence the communication signal in the area, the communication signal needs to be subjected to all-around rotation induction detection during detection, and the communication signal is subjected to inaccurate induction detection due to the fact that the communication signal is rotated too fast during detection at present, so that the induction detection needs to be carried out for multiple times, and the workload is increased.

Therefore, the present application provides a 5G mobile communication signal sensor, which improves the above-mentioned drawbacks.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a 5G mobile communication signal sensor to solve the problems that in the prior art, because the communication signals in the area near a 5G mobile communication base station are in a random coverage mode, and surrounding buildings will influence the communication signals in the area, the communication signals in the area need to be subjected to omnibearing rotation induction detection during detection, and the communication signals are subjected to inaccurate induction detection due to the fact that the communication signals rotate too fast at present, so that multiple times of induction detection are required, and the workload is increased.

In order to achieve the purpose, the invention is realized by the following technical scheme: A5G mobile communication signal sensor structurally comprises an underframe, supporting rods, shaft sleeves, a control box, an adjusting structure and an induction antenna, wherein the supporting rods are vertically arranged at the upper end of the underframe and are in mechanical connection; the adjusting structure comprises a rotating structure, a stand column and an installation pipe, wherein the stand column is vertically installed at the upper end of the rotating structure and welded together, the installation pipe is welded at the upper end of the stand column and located on the same axis, and the lower end of the induction antenna is embedded and installed on the inner side of the installation pipe and connected through threads.

The invention is further improved, the rotating structure comprises a support, a rotating conducting structure and a rotating adapting mechanism, the rotating conducting structure is embedded in the bottom of the inner side of the support and is positioned on the same axis, and the lower end of the rotating adapting mechanism is embedded in the inner side of the support and is positioned at the upper end of the rotating conducting structure.

The invention is further improved, the rotary conduction structure comprises a connection seat, a continuous conduction structure, a fixed pipe and a connection seat, the connection seat is arranged at the lower end of the outer side of the continuous conduction structure and is electrically connected, the fixed pipe is vertically arranged at the upper end and is welded with the upper end, and the connection seat is arranged at the inner side of the fixed pipe and is electrically connected with the upper end of the continuous conduction structure.

The invention is further improved, the continuous conduction structure comprises a fixed seat, an inner conduction disc, a movable structure and a rotating block, the inner conduction disc is embedded and installed on the inner side of the fixed seat, two pairs of inner conduction discs are arranged, the movable structure is embedded and installed on the inner side of the rotating block, the outer side of the movable structure abuts against the inner side of the inner conduction disc, the fixed pipe is vertically installed at the upper end of the movable structure and welded with the movable structure, and the communication seat is electrically connected with the movable structure through a lead.

The invention is further improved, the movable structure comprises a connecting disc, a connecting block, a clamping seat, springs and balls, the connecting block is embedded and installed on the inner side of the connecting disc and is electrically connected with the balls through a lead, the clamping seat is sleeved on the outer side of the connecting disc and clamped, the balls are embedded and installed on the inner side of the clamping seat and are movably connected, the springs are embedded in the inner side of the clamping seat, one end of each spring abuts against the inner side of each ball, and the number of the balls is 4, and the balls are uniformly distributed on the inner side of the clamping seat.

The invention is further improved, the rotary adapting mechanism comprises a sleeve block, an inner groove, a rotary seat, an iron plate and a driving structure, the inner groove penetrates through the sleeve block and is arranged inside the rotary seat and the driving structure, the sleeve block is horizontally arranged at the upper end of the rotary seat and is welded with the rotary seat, the iron plate is embedded and arranged at the bottom of the inner side of the rotary seat, and the driving structure is arranged at the lower end of the rotary seat and is positioned on the same axis.

The invention is further improved, the inner side of the driving structure is provided with 12 electromagnets which are uniformly distributed on the inner side of the driving structure, and the electromagnets are arranged at the lower end of the iron block plate.

The invention is further improved, the electromagnet comprises clamping blocks, an iron rod and a coil, the clamping blocks are arranged on two sides of the iron rod and clamped on the inner side of the driving structure, and the coil is wound on the outer side of the iron rod.

According to the technical scheme, the 5G mobile communication signal sensor has the following beneficial effects:

the rotary conduction structure is arranged on the inner side of the support, the rotary adaptation mechanism rotates to drive the rotary conduction structure at the lower end to work, at the moment, the fixed pipe rotates to enable the continuous conduction structure at the lower end to correspondingly rotate, the rotating block rotates on the inner side of the fixed seat, the movable structure at the upper end of the rotating block also rotates on the inner side of the inner conduction disc, the clamping seat on the outer side of the connecting disc also rotates along with the rotating block, and the spring on the inner side of the clamping seat pushes the ball to be close to the inner conduction disc all the time to keep the conduction of signals so as to enable the induction antenna communicated with the connecting seat to perform induction detection on 5G mobile communication signals.

According to the invention, the rotary adapting mechanism is arranged at the upper end of the rotary conduction structure, the electromagnet on the inner side of the driving structure is conducted, the electromagnet close to the iron plate is selected for conduction, at the moment, electric energy enters the coil and is matched with the iron rod on the inner side to generate magnetism, the iron plate is attracted, the rotary seat with the iron plate is driven to rotate, the rotary conduction structure is driven to rotate, the induction antenna at the upper end rotates along with the rotary conduction structure, and because signals are always conducted, the induction detection is better carried out on 5G mobile communication signals, the rotary detection can be uniformly carried out and slowly, and the induction detection signals are more stable, so that the induction detection communication signals are more accurate, the induction detection times are reduced, and the workload is further reduced.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural diagram of a 5G mobile communication signal sensor according to the present invention;

FIG. 2 is a schematic structural diagram of an adjustment mechanism of the present invention;

FIG. 3 is a schematic structural view of a rotary structure according to the present invention;

FIG. 4 is a schematic structural diagram of a rotary feedthrough structure of the present invention;

FIG. 5 is a schematic structural diagram of a continuous via structure according to the present invention;

FIG. 6 is a schematic front view of the movable structure of the present invention;

FIG. 7 is a schematic top view of the mobile structure of the present invention;

FIG. 8 is a schematic structural view of a rotary adaptive mechanism of the present invention;

FIG. 9 is a schematic front view of the driving structure of the present invention;

FIG. 10 is a schematic top view of the driving structure of the present invention;

fig. 11 is a schematic structural view of an electromagnet according to the present invention.

In the figure: an underframe-1, a support rod-2, a shaft sleeve-3, a control box-4, an adjusting structure-5, an induction antenna-6, a rotating structure-51, an upright post-52, a mounting pipe-53, a support-511, a rotating conduction structure-512, a rotating adaptation mechanism-513, a connection seat-12 a, a continuous conduction structure-12 b, a fixed pipe-12 c, a connection seat-12 d, a fixed seat-b 1, an internal conduction disc-b 2, a movable structure-b 3, a rotating block-b 4, a connection disc-b 31, a connection block-b 32, a clamping seat-b 33, a spring-b 34, a ball-b 35, an internal groove block-13 a, an internal groove-13 b, a rotating seat-13 c, an iron block plate-13 d, a driving structure-13 e, an electromagnet-e 1, A fixture block-e 11, an iron rod-e 12 and a coil-e 13.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment is as follows: referring to fig. 1-7, the embodiments of the present invention are as follows:

the structure of the device comprises an underframe 1, a supporting rod 2, a shaft sleeve 3, a control box 4, an adjusting structure 5 and an induction antenna 6, wherein the supporting rod 2 is vertically arranged at the upper end of the underframe 1 and is in mechanical connection, the shaft sleeve 3 is horizontally arranged at the upper end of the supporting rod 2 and is welded with the upper end of the supporting rod, the control box 4 is mechanically connected with the upper end of the shaft sleeve 3 and is positioned on the same axis, the adjusting structure 5 is horizontally arranged at the upper end of the control box 4 and is in mechanical connection, and the induction antenna 6 is vertically embedded and arranged at the upper end of the inner side of; the adjusting structure 5 comprises a rotating structure 51, a vertical column 52 and a mounting pipe 53, wherein the vertical column 52 is vertically mounted at the upper end of the rotating structure 51 and welded with the rotating structure, the mounting pipe 53 is welded at the upper end of the vertical column 52 and located on the same axis, and the lower end of the induction antenna 6 is embedded and mounted inside the mounting pipe 53 and connected by threads.

Referring to fig. 3, the rotating structure 51 includes a support 511, a rotating conducting structure 512, and a rotating adaptive mechanism 513, wherein the rotating conducting structure 512 is embedded in the bottom of the support 511 and located on the same axis, and the lower end of the rotating adaptive mechanism 513 is embedded in the support 511 and located at the upper end of the rotating conducting structure 512, so that the signal is always conducted during rotation, and better sensing detection is performed.

Referring to fig. 4, the rotating conduction structure 512 includes a conduction seat 12a, a continuous conduction structure 12b, a fixed tube 12c, and a conduction seat 12d, the conduction seat 12a is installed at the lower end of the outer side of the continuous conduction structure 12b and is electrically connected to the outer side of the continuous conduction structure 12b, the fixed tube 12c is vertically installed at the upper end of the continuous conduction structure and is welded to the upper end of the continuous conduction structure, the conduction seat 12d is installed at the inner side of the fixed tube 12c and is electrically connected to the upper end of the continuous conduction structure 12b, and the conduction seat 12d is conducted with the induction antenna 6 through a wire and maintains connection with.

Referring to fig. 5, the continuous conduction structure 12b includes a fixed seat b1, an inner conduction plate b2, a movable structure b3, and a rotating block b4, the inner conduction plate b2 is embedded inside the fixed seat b1 and has two pairs, the movable structure b3 is embedded inside the rotating block b4 and has an outer side abutting against the inner conduction plate b2, the fixed tube 12c is vertically installed at the upper end of the movable structure b3 and is welded to the upper end of the movable structure b3, and the connection seat 12d is electrically connected with the movable structure b3 through a wire, rotates inside the inner conduction plate b2 and keeps contact with the movable structure b3 to connect signals.

Referring to fig. 6-7, the movable structure b3 includes a connection plate b31, a connection block b32, a clamping seat b33, a spring b34, and a ball b35, the connection block b32 is embedded in the connection plate b31 and electrically connected to the ball b35 through a wire, the clamping seat b33 is sleeved outside the connection plate b31 and clamped, the ball b35 is embedded in the clamping seat b33 and movably connected, the spring b34 is embedded inside the clamping seat b33 and one end of the spring b35 abuts against the inside, the balls b35 are provided with 4 pieces and uniformly distributed inside the clamping seat b33 and matched with the spring b34, the balls always rotate against the inside of the inner conductive plate b2, and the smooth rotation is ensured.

Based on the above embodiment, the specific working principle is as follows:

the device is taken to the position where the 5G mobile communication signal needs to be detected, the chassis 1 can be erected for use, when the rotation is needed to perform the signal sensing detection, the rotation adaptive mechanism 513 rotates to drive the lower rotary conducting structure 512 to operate, at this time, the fixed tube 12c rotates to make the lower continuous conducting structure 12b rotate correspondingly, the rotating block b4 rotates inside the fixed seat b1, and the movable structure b3 at the upper end thereof will also rotate inside the inner conductive disc b2, the clamping seat b33 outside the connecting disc b31 will also rotate along with the inner conductive disc b2, because the spring b34 inside the cassette b33 pushes the ball b35 to approach outwards all the time, and then the ball abuts against the inside of the inner conductive disc b2, the conduction of the signal is kept, the induction antenna 6 communicated with the communicating seat 12d conducts induction detection on the 5G mobile communication signal, and the induction detection is better conducted by rotating the induction antenna to keep the signal in contact all the time.

Example two: referring to fig. 1-3 and 8-11, the embodiments of the present invention are as follows:

Referring to fig. 8, the rotation adaptive mechanism 513 includes a sleeve block 13a, an inner groove 13b, a rotary base 13c, an iron block plate 13d, and a driving structure 13e, wherein the inner groove 13b penetrates through the sleeve block 13a inside the rotary base 13c and the driving structure 13e, the sleeve block 13a is horizontally installed at the upper end of the rotary base 13c and welded to the same, the iron block plate 13d is embedded in the bottom inside the rotary base 13c, the driving structure 13e is installed at the lower end of the rotary base 13c and located on the same axis, and the rotary base 13c with the iron block plate 13d is driven to rotate by the driving structure 13 e.

Referring to fig. 9-10, the inside of the driving structure 13e is provided with electromagnets e1, the electromagnets e1 are 12 and are uniformly distributed on the inside of the driving structure 13e, the electromagnets e1 are provided at the lower end of the iron plate 13d, the electromagnets e1 are independently powered, and can intermittently power the driving structure to rotate slowly, and the angle of each rotation is fixed.

Referring to fig. 11, the electromagnet e1 includes a latch e11, an iron rod e12, and a coil e13, the latch e11 is disposed on two sides of the iron rod e12 and is engaged with the inner side of the driving structure 13e, and the coil e13 is wound around the outer side of the iron rod e12, and when the power is turned on, the coil generates magnetism to attract the iron block plate 13d, so that the rotating base 13c on the outer side rotates along with the iron block plate, thereby better controlling the rotation angle.

Based on the above embodiment, the specific working principle is as follows:

the device is brought to a position where a 5G mobile communication signal needs to be detected, the chassis 1 can be used by being erected, when the device needs to rotate to perform signal induction detection, the electromagnet e1 on the inner side of the driving structure 13e is conducted, the electromagnet e1 close to the iron plate 13d is selected to be conducted, electric energy enters the coil e13 and is matched with the iron rod e12 on the inner side to generate magnetism, the iron plate 13d is attracted, the rotating seat 13c with the iron plate 13d is driven to rotate, the rotating conducting structure 512 is driven to rotate, the induction antenna 6 at the upper end rotates along with the rotation, the signal is conducted all the time, and the 5G mobile communication signal is better subjected to induction detection.

The invention solves the problems that in the prior art, because the communication signal in the area near the 5G mobile communication base station is in a random covering form, and surrounding buildings can also influence the communication signal in the area, the communication signal needs to be subjected to omnibearing rotary induction detection when being detected, but the communication signal is rotated too fast when being detected at present, so that the induction detection of the communication signal is inaccurate, and further multiple induction detections need to be carried out, and the workload is increased, the invention sets a rotary conduction structure at the inner side of a support through the mutual combination of the components, a rotary adaptation mechanism rotates to drive the rotary conduction structure at the lower end to work, at the moment, a fixed pipe rotates to ensure that the continuous conduction structure at the lower end also correspondingly rotates, a rotating block rotates at the inner side of a fixed seat, and a movable structure at the upper end also rotates at the inner side of an inner conduction disc, the clamping seat on the outer side of the connecting disc also rotates along with the connecting disc, and the spring on the inner side of the clamping seat pushes the ball to be always close to the outer side and further to be abutted against the inner side of the inner conducting disc to keep the conduction of signals, so that the induction antenna communicated with the connecting seat can carry out induction detection on 5G mobile communication signals, the induction detection is better carried out by rotating to keep the signals in contact all the time, the stability of the signals is ensured, and the induction detection of the communication signals is more accurate; set up rotatory adaptation mechanism in rotatory conduction structure upper end, switch on the inboard electro-magnet of drive structure, and select the electro-magnet that is close to the iron sheet board and switch on, the electric energy will get into the coil and the inboard iron set of cooperation produces magnetism this moment, and then attract the iron sheet board, and then the roating seat that drives to have the iron sheet board rotates, it rotates to drive rotatory conduction structure, the induction antenna of upper end this moment will rotate thereupon and because the signal switches on all the time, better detect 5G mobile communication signal induction, what can be even rotates and slow detection, make the signal stability that the response detected, thereby make the communication signal accuracy that the response detected more, the number of times that the response detected has been reduced, and then work load has been reduced.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. A5G mobile communication signal sensor structurally comprises an underframe (1), a supporting rod (2), a shaft sleeve (3), a control box (4), an adjusting structure (5) and an induction antenna (6), wherein the supporting rod (2) is vertically arranged at the upper end of the underframe (1), the shaft sleeve (3) is horizontally arranged at the upper end of the supporting rod (2), the control box (4) is mechanically connected to the upper end of the shaft sleeve (3), the adjusting structure (5) is horizontally arranged at the upper end of the control box (4), and the induction antenna (6) is vertically embedded and arranged at the upper end of the inner side of the adjusting structure (5); the method is characterized in that:

adjusting structure (5) includes revolution mechanic (51), stand (52), installation pipe (53), stand (52) are vertical to be installed in revolution mechanic (51) upper end, installation pipe (53) weld in stand (52) upper end, induction antenna (6) lower extreme embedding is installed in installation pipe (53) inboard.

2. The 5G mobile communication signal sensor according to claim 1, wherein: the rotating structure (51) comprises a support (511), a rotating conducting structure (512) and a rotating adaptive mechanism (513), wherein the rotating conducting structure (512) is embedded in the bottom of the inner side of the support (511), and the lower end of the rotating adaptive mechanism (513) is embedded in the inner side of the support (511).

3. The 5G mobile communication signal sensor according to claim 2, wherein: rotatory conduction structure (512) are including switching on seat (12a), continuous conduction structure (12b), fixed pipe (12c), intercommunication seat (12d), install in continuous conduction structure (12b) outside lower extreme switching on seat (12a), fixed pipe (12c) are vertically installed in the upper end, fixed pipe (12c) inboard is located in intercommunication seat (12 d).

4. The 5G mobile communication signal sensor according to claim 3, wherein: continuous conduction structure (12b) include fixing base (b1), interior conduction dish (b2), active structure (b3), turning block (b4), interior conduction dish (b2) embedding is installed in fixing base (b1) inboard, active structure (b3) embedding is installed in turning block (b4) inboard, fixed pipe (12c) are vertically installed in active structure (b3) upper end, it is connected through the wire electricity with active structure (b3) to lead to seat (12 d).

5. The 5G mobile communication signal sensor according to claim 4, wherein: the movable structure (b3) comprises a connecting disc (b31), a connecting block (b32), a clamping seat (b33), a spring (b34) and balls (b35), wherein the connecting block (b32) is embedded in the connecting disc (b31), the clamping seat (b33) is sleeved on the outer side of the connecting disc (b31), the balls (b35) are embedded in the inner side of the clamping seat (b33), the spring (b34) is embedded in the inner side of the clamping seat (b33), and the balls (b35) are arranged in a plurality and are uniformly distributed on the inner side of the clamping seat (b 33).

6. The 5G mobile communication signal sensor according to claim 2, wherein: rotatory adaptation mechanism (513) include nest block (13a), inside groove (13b), roating seat (13c), iron plate board (13d), drive structure (13e), inside groove (13b) run through in nest block (13a) in roating seat (13c) and drive structure (13e) inboard, nest block (13a) horizontal installation is in roating seat (13c) upper end, iron plate board (13d) embedding is installed in roating seat (13c) inboard bottom, drive structure (13e) are installed in roating seat (13c) lower extreme.

7. The 5G mobile communication signal sensor according to claim 6, wherein: the inner side of the driving structure (13e) is provided with a plurality of electromagnets (e1), the electromagnets (e1) are uniformly distributed on the inner side of the driving structure (13e), and the electromagnets (e1) are arranged at the lower end of the iron plate (13 d).

8. The 5G mobile communication signal sensor according to claim 7, wherein: the electromagnet (e1) comprises a clamping block (e11), an iron rod (e12) and a coil (e13), the clamping block (e11) is arranged on two sides of the iron rod (e12), and the coil (e13) is wound on the outer side of the iron rod (e 12).