CN111050527B - 5G mobile communication signal inductor - Google Patents

Abstract

The invention discloses a 5G mobile communication signal sensor, which structurally comprises a heat dissipation protection device, a steel ring, a positioning steel cable, a base, a motor and a positioning column, and has the following effects: be equipped with the flat blade on the tuber pipe outer wall, and tuber pipe bottom and base swing joint, utilize the flat blade can convert wind energy into tuber pipe pivoted mechanical energy, make platelike induction antenna rotate along with tuber pipe pivoted helical pitch, improve the receiving range of platelike induction antenna to the signal, reduce the signal delay, it is rotatory to drive the air inlet impeller in the tuber pipe rotation, admit air by the tuber pipe lower extreme, exhaust by the tuber pipe upper end, during the rotation platelike induction antenna jets, get rid of the dust on platelike induction antenna surface, improve platelike induction antenna's radiating efficiency, under the unable drive tuber pipe of natural wind energy carries out the pivoted condition, the drive torque that the motor produced drives the tuber pipe rotation automatically.

Description

5G mobile communication signal inductor

Technical Field

The invention relates to the field of 5G signal sensors, in particular to a 5G mobile communication signal sensor.

Background

The 5G mobile network is a digital cellular network, like earlier 2G, 3G and 4G mobile networks, in which the service area covered by the provider is divided into many small geographical areas called cells, analog signals representing sound and images are digitized in handsets, converted by analog-to-digital converters and transmitted as bit streams, in some remote mountainous areas or mountainous areas not covered by communication base stations, usually cellular communication sensors are installed in high terrains or high buildings, all 5G wireless devices in the cells communicate with local antenna arrays and automatic low-power transceivers in the cells through radio waves, so as to satisfy the sensing and omni-directional coverage between signals, existing cellular communication sensors generate a certain electromagnetic field around the perimeter during operation, making floating dust around easily adsorbed by the antennas, in the past, signal transmission of the sensor can be weakened, and the aging speed of the antenna array can be accelerated due to the fact that the sensor is exposed to the sun for a long time and the surface temperature of the sensor is high, so that a heat dissipation protection device of the 5G mobile communication signal sensor needs to be developed to solve the problems that a certain electromagnetic field can be generated around the existing honeycomb communication sensor during work, floating dust floating around the existing honeycomb communication sensor is easily adsorbed by the antenna, the signal transmission of the sensor can be weakened in the past, and the aging speed of the antenna array can be accelerated due to the fact that the sensor is exposed to the sun for a long time and the surface temperature of the sensor is high.

Summary of the invention

Aiming at the defects of the prior art, the invention is realized by the following technical scheme: the utility model provides a mobile communication signal inductor, its structure includes heat dissipation protection device, steel ring, location cable wire, base, motor, reference column, the central point at base top put and is equipped with heat dissipation protection device, heat dissipation protection device and base swing joint, base bottom central point put and is equipped with the motor, the base on be equipped with the reference column, heat dissipation protection device middle section position be equipped with the steel ring, steel ring and heat dissipation protection device swing joint, the steel ring both sides be equipped with the location cable wire, location cable wire and steel ring connect.

As a further optimization of the technical scheme, the heat dissipation protection device consists of an implementation mechanism and a driven mechanism, wherein the implementation mechanism is arranged at the top of the driven mechanism, and the implementation mechanism is matched with the driven mechanism.

As the further optimization of this technical scheme, implementation mechanism constitute by jetting mechanism, regulation pole, platelike induction antenna, siphunculus, connection terminal, the siphunculus both sides be equipped with platelike induction antenna, platelike induction antenna bottom and siphunculus adopt hinge fit, platelike induction antenna rear end central point put and be equipped with the regulation pole, regulation pole around both ends respectively with platelike induction antenna and siphunculus be connected, the siphunculus bottom be equipped with the connection terminal, connection terminal and siphunculus pass through the bearing and connect, connection terminal and platelike induction antenna swing joint, the siphunculus top be equipped with jetting mechanism.

As a further optimization of the technical scheme, the blowing mechanism consists of a blowing nozzle, an air port and a blowing cover, the air port is arranged at the center of the bottom of the blowing cover, the blowing cover is connected with the through pipe through the air port, the blowing nozzles are arranged at the bottoms of the blowing nozzles, and the blowing nozzles are connected with the blowing cover.

As the further optimization of this technical scheme, driven mechanism constitute by tuber pipe, flat blade, air inlet cover, air inlet impeller, pivot, tuber pipe bottom be equipped with the air inlet cover, the inside central point of air inlet cover put and be equipped with the pivot, the pivot on be equipped with the air inlet impeller, air inlet impeller central point put and the pivot is connected, air inlet impeller outer lane and air inlet cover adopt interference fit, air inlet cover and base pass through the bearing and connect, the tuber pipe outer wall on be equipped with flat blade, flat blade and tuber pipe connect.

As a further optimization of the technical scheme, the inner wall of the air pipe is provided with a spiral groove.

As a further optimization of the technical scheme, the central position of the air inlet impeller is connected with the rotating shaft, and the outer ring of the air inlet impeller and the air inlet cover are in interference fit.

Advantageous effects

The mobile communication signal sensor is reasonable in design and strong in functionality, and has the following beneficial effects:

the flat plate blades are arranged on the outer wall of the air pipe, the bottom of the air pipe is movably connected with the base, wind energy can be converted into mechanical energy for rotating the air pipe by utilizing the flat plate blades, the plate-shaped induction antenna rotates along with a lead of the rotation of the air pipe, the receiving range of the plate-shaped induction antenna for signals is improved, the signal delay is reduced, the air inlet impeller is driven to rotate in the rotation of the air pipe, air is fed from the lower end of the air pipe, air is exhausted from the upper end of the air pipe, the plate-shaped induction antenna in rotation is blown, dust on the surface of the plate-shaped induction antenna is removed, the heat dissipation efficiency of the plate-shaped induction antenna is improved, and the air pipe is automatically driven to rotate by driving torque generated by the motor under the condition that natural wind energy cannot drive the air pipe to rotate;

the inner wall of the air pipe is provided with the spiral groove, and the air flow sucked by the air inlet impeller is spirally lifted upwards under the guiding action of the spiral groove by the air pipe, so that the flow rate and the utilization rate of the air flow can be greatly improved;

the upper end of the air pipe is connected with the through pipe, the lower end of the air pipe is connected with the air inlet cover, the air inlet cover is connected with the base through the bearing, and the air inlet impeller and the air inlet cover which are arranged in the air inlet cover are fixedly connected, so that the flat plate blades can convert wind energy into mechanical energy to drive the air pipe to rotate under the action of a circular wall structure formed by the flat plate blades, the air pipe is exhausted from the upper part from the lower part, and the air inlet impeller is connected with the motor through the rotating shaft, so that the driving torque generated by the motor can automatically drive the air pipe to rotate under the condition that natural wind energy cannot push the air pipe to rotate through the flat plate blades.

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 diagram of a front view of a 5G mobile communication signal sensor according to the present invention;

FIG. 2 is a front view of the heat dissipation protection device of the present invention;

FIG. 3 is a schematic front view of the mechanism of the present invention;

FIG. 4 is a schematic structural view of the bottom of the blowing mechanism of the present invention;

fig. 5 is a schematic sectional structure view of the driven mechanism of the present invention.

In the figure: the heat dissipation protection device comprises a heat dissipation protection device-1, an implementation mechanism-11, a blowing mechanism-11 a, a blowing nozzle-11 a1, an air port-11 a2, a blowing cover-11 a3, an adjusting rod-11 b, a plate-shaped induction antenna-11 c, a through pipe-11 d, a wire holder-11 e, a driven mechanism-12, an air pipe-12 a, a flat plate blade-12 b, an air inlet cover-12 c, an air inlet impeller-12 d, a rotating shaft-12 e, a steel ring-2, a positioning steel cable-3, a base-4, a motor-5 and a positioning column-6.

Detailed Description

In order to make the technical means, the original characteristics, the achieved purposes and the effects of the invention easy to understand, the following description and the accompanying drawings further illustrate the preferred embodiments of the invention.

Examples

Referring to fig. 1-5, the present invention provides an embodiment of a 5G mobile communication signal sensor:

referring to fig. 1, a 5G mobile communication signal sensor comprises a heat dissipation protection device 1, a steel ring 2, a positioning steel cable 3, a base 4, a motor 5, and a positioning post 6, the base 4 is in a circular structure, the central position of the top is provided with a heat dissipation protection device 1, the heat dissipation protection device 1 is movably connected with the base 4, the central position of the bottom of the base 4 is provided with a motor 5, the motor 5 is matched with the heat dissipation protection device 1, four positioning columns 6 are arranged on the base 4, each positioning column 6 is vertically arranged on the base 4 and forms a circular wall structure along the base 4, a steel ring 2 is arranged at the middle section of the heat dissipation protection device 1, the steel ring 2 is movably connected with the heat dissipation protection device 1, two sides of the steel ring 2 are provided with two positioning steel cables 3 in an axisymmetric structure, and the positioning steel cables 3 are connected with the steel ring 2.

Referring to fig. 2, the heat dissipation protection device 1 is composed of an implementing mechanism 11 and a driven mechanism 12, the implementing mechanism 11 is disposed on the top of the driven mechanism 12, and the implementing mechanism 11 is matched with the driven mechanism 12.

Referring to fig. 3, the implementation mechanism 11 is composed of a blowing mechanism 11a, an adjusting rod 11b, two plate-shaped induction antennas 11c, a through pipe 11d, and a wire holder 11e, two sides of the through pipe 11d are provided with the two plate-shaped induction antennas 11c in an axisymmetric structure, the bottom end of the plate-shaped induction antenna 11c is matched with the through pipe 11d through a hinge, the adjusting rod 11b is arranged at the center of the rear end of the plate-shaped induction antenna 11c, the front end and the rear end of the adjusting rod 11b are respectively connected with the plate-shaped induction antenna 11c and the through pipe 11d, the wire holder 11e is arranged at the bottom end of the through pipe 11d, the wire holder 11e is connected with the through pipe 11d through a bearing, the wire holder 11e is movably connected with the plate-shaped induction antenna 11c, and the blowing mechanism 11a is arranged at the top end of the through pipe 11 d.

Referring to fig. 4, the blowing mechanism 11a includes a blowing nozzle 11a1, an air opening 11a2, and a blowing nozzle 11a3, the blowing nozzle 11a3 is a hollow cone-shaped structure, the air opening 11a2 is disposed at the center of the bottom of the blowing nozzle 11a3, the blowing nozzle 11a3 and the through pipe 11d are connected through the air opening 11a2, six blowing nozzles 11a1 are uniformly and equidistantly disposed at the bottom of the blowing nozzle 11a1, each blowing nozzle 11a1 surrounds the blowing nozzle 11a3 to form a circular wall structure, and the blowing nozzle 11a1 is connected with the blowing nozzle 11a 3.

Referring to fig. 5, the driven mechanism 12 comprises an air duct 12a, a flat blade 12b, an air inlet cover 12c, an air inlet impeller 12d, and a rotating shaft 12e, an air inlet cover 12c is arranged at the bottom of the air pipe 12a, the air inlet cover 12c is of a hollow circular structure, a rotating shaft 12e is arranged at the center of the interior of the air inlet cover 12c, the rotating shaft 12e generates driving torque through the motor 5, the rotating shaft 12e is provided with an air inlet impeller 12d, the central position of the air inlet impeller 12d is connected with the rotating shaft 12e, the outer ring of the air inlet impeller 12d is in interference fit with the air inlet cover 12c, the air inlet cover 12c is connected with the base 4 through a bearing, the inner wall of the air pipe 12a is provided with a spiral groove, four flat plate blades 12b are uniformly arranged on the outer wall of the air pipe 12a at equal intervals, each flat plate blade 12b surrounds the air pipe 12a to form a circular wall structure, and the flat plate blades 12b are connected with the air pipe 12 a.

The specific realization principle is as follows:

the outer wall of the air pipe 12a is provided with flat blades 12b, the bottom of the air pipe 12a is movably connected with the base 4, the flat blades 12b can convert wind energy into mechanical energy for rotating the air pipe 12a, so that the plate-shaped induction antenna 11c rotates along with the rotating lead of the air pipe 12a, the signal receiving range of the plate-shaped induction antenna 11c is improved, the signal delay is reduced, the air inlet impeller 12d is driven to rotate by the rotation of the air pipe 12a, air is fed from the lower end of the air pipe 12a, the air is exhausted from the upper end of the air pipe 12a, the rotating plate-shaped induction antenna 11c is blown, dust on the surface of the plate-shaped induction antenna 11c is removed, the heat dissipation efficiency of the plate-shaped induction antenna 11c is improved, under the condition that the air pipe 12a cannot be driven to rotate by natural wind energy, the driving torque generated by the motor 5 automatically drives the air pipe 12a to rotate, because the upper end of the air pipe 12a is connected with the through pipe 11d, and the lower end is connected with the air inlet hood 12c, because the air inlet cover 12c is connected with the base 4 through a bearing, and the air inlet impeller 12d arranged in the air inlet cover 12c is fixedly connected with the air inlet cover 12c, under the action of a ring wall structure formed by the flat blades 12b, the flat blades 12b can convert wind energy into mechanical energy to drive the air pipe 12a to rotate, so that the air pipe 12a can be exhausted from the lower part to the upper part through air inlet, because the air inlet impeller 12d is connected with the motor 5 through the rotating shaft 12e, under the condition that natural wind energy can not push the air pipe 12a to rotate through the flat blades 12b, the driving torque generated by the motor 5 can automatically drive the air pipe 12a to rotate, because the spiral groove is arranged on the inner wall of the air pipe 12a, the air flow sucked by the air inlet impeller 12d is spirally and upwards lifted under the guiding action of the spiral groove through the air pipe 12a, the flow rate and the utilization rate of the air flow can be greatly improved, because the blowing cover 11a3 is of a hollow conical structure, and the bottom outer edge is provided with the blowing nozzle 11a1, the air flow is pressurized and ejected from the blowing nozzle 11a1 by the guiding action of the tapered surface formed by the blowing hood 11a3, so that the air flow can sufficiently pass through the surface of the plate-shaped induction antenna 11c to radiate heat and remove dust from the plate-shaped induction antenna 11 c.

While there have been shown and described what are at present considered the fundamental principles of the invention, the essential features and advantages thereof, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but rather, is capable of numerous changes and modifications in various forms without departing from the spirit or essential characteristics thereof, and it is intended that the invention be limited not by the foregoing descriptions, but rather by the appended claims and their equivalents.

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)

1. The utility model provides a 5G mobile communication signal inductor, its structure includes heat dissipation protection device (1), steel ring (2), location cable wire (3), base (4), motor (5), reference column (6), its characterized in that:

the heat dissipation protection device is characterized in that the top of the base (4) is provided with a heat dissipation protection device (1), the bottom of the base (4) is provided with a motor (5), the base (4) is provided with a positioning column (6), the middle section of the heat dissipation protection device (1) is provided with a steel ring (2), and two sides of the steel ring (2) are provided with positioning steel cables (3);

the heat dissipation protection device (1) consists of an implementation mechanism (11) and a driven mechanism (12), wherein the implementation mechanism (11) is arranged at the top of the driven mechanism (12), and the implementation mechanism (11) is matched with the driven mechanism (12);

the implementation mechanism (11) consists of a blowing mechanism (11a), an adjusting rod (11b), a plate-shaped induction antenna (11c), a through pipe (11d) and a wire holder (11e), wherein the plate-shaped induction antenna (11c) is arranged on two sides of the through pipe (11d), the adjusting rod (11b) is arranged at the rear end of the plate-shaped induction antenna (11c), the wire holder (11e) is arranged at the bottom end of the through pipe (11d), and the blowing mechanism (11a) is arranged at the top end of the through pipe (11 d);

the blowing mechanism (11a) consists of a blowing nozzle (11a1), an air opening (11a2) and a blowing cover (11a3), wherein the air opening (11a2) is arranged at the center of the blowing cover (11a3), and the blowing nozzle (11a1) is arranged at the bottom of the blowing cover (11a 3);

driven mechanism (12) constitute by tuber pipe (12a), dull and stereotyped blade (12b), air inlet cover (12c), air inlet impeller (12d), pivot (12e), tuber pipe (12a) bottom be equipped with air inlet cover (12c), air inlet cover (12c) inside be equipped with pivot (12e), pivot (12e) on be equipped with air inlet impeller (12d), tuber pipe (12a) outer wall on be equipped with dull and stereotyped blade (12 b).

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