CN113015030A

CN113015030A - 5G communication base station

Info

Publication number: CN113015030A
Application number: CN202110225431.8A
Authority: CN
Inventors: 易佳佳
Original assignee: Individual
Current assignee: Hebei Yutian Communication Equipment Co ltd
Priority date: 2021-03-01
Filing date: 2021-03-01
Publication date: 2021-06-22
Anticipated expiration: 2041-03-01
Also published as: CN113015030B

Abstract

The invention discloses a 5G communication base station, which structurally comprises a machine body, a fixed strip, a signal transmitter and a connecting plate, wherein a 5G signal is transmitted to the outside through the signal transmitter, when the base station is installed in an environment with more ice and snow, the weight of the ice and snow on the signal rod is continuously increased due to the gradual accumulation of the ice and snow, the signal rod is continuously pressed to cause the outer shell to rotate, the outer shell and the sliding rod to generate relative displacement, when the sliding rod moves to the limit position of a reverse thrust groove, the sliding rod is subjected to rail change, the elastic force stored in a compression rod is released, the extending rod is quickly lifted up to cause the ice and snow to be greatly shaken off, and after the lifting is finished and stopped, the falling structure can continuously work through inertia to impact an ice layer, the ice layer is crushed through the pressurization of an impact head and simultaneously generates vibration to shake off the ice layer, so that the phenomenon that the signal transmitter is bent and broken due to the excessive accumulation of the ice and, the normal operation of the base station in the ice and snow environment is guaranteed.

Description

5G communication base station

Technical Field

The invention relates to the field of 5G communication base stations, in particular to a 5G communication base station.

Background

The 5G communication base station is the core equipment of the 5G network, can release wireless signals to the outside through the 5G communication base station, furthermore, wireless signals can be received and connected by the 5G equipment to form a 5G network, and in order to increase the signal coverage of the 5G communication base station, and reduces the influence of ground buildings on wireless signals, so 5G communication base stations are often disposed at higher places, because the 5G communication base station outputs signals through the antenna extending out, if the 5G communication base station is arranged in the northern place with high altitude, in winter, water vapor in the outside air is easily condensed into ice crystals to be combined with snowfall in the sky, the ice crystals fall to cover the antenna of the 5G communication base station, after the accumulation time is long, the antenna of the 5G communication base station is easily bent or even broken by pressure generated by excessive ice and snow, and the output of the 5G signal is affected.

Disclosure of Invention

In view of the above problems, the present invention provides a 5G communication base station.

In order to achieve the purpose, the invention is realized by the following technical scheme: A5G communication base station structurally comprises a machine body, a fixing strip, a signal transmitter and a connecting plate, wherein the front surface of the machine body is connected with the back surface of the fixing strip in a welding mode, the signal transmitter is embedded into the front surface of the machine body, and the back surface of the connecting plate is fixedly connected with the front surface of the machine body in an embedding mode; the signal transmitter comprises a fixing block, a receiving plate, two stabilizing springs and a signal rod, wherein the receiving plate is embedded into the fixing block, the upper surface and the lower surface of the signal rod are fixedly connected with the inner layer of the fixing block through the stabilizing springs, the left side of the signal rod is movably clamped with the right side of the receiving plate, the two stabilizing springs are arranged, and the two stabilizing springs are distributed on the upper surface and the lower surface of the signal rod in a mirror image mode.

Furthermore, the signal rod comprises an extension rod, an outer shell, a reverse thrust groove, a sliding rod, four pressing rods and an inner shaft, the left side of the extension rod is fixedly connected with the outer ring of the outer shell in an embedded mode, the reverse thrust groove and the inner part of the outer shell are integrally formed, the top end of the sliding rod is movably connected with the inner layer of the reverse thrust groove, the left side of the sliding rod is fixedly connected with the inner ring of the outer shell in an embedded mode through the pressing rods, and gaps among the four pressing rods are uniformly distributed on the inner ring of the outer shell in an annular mode.

Furthermore, stretch out the stick and include adapter sleeve, signal rod, shake the board, get rid of the head, adapter sleeve right side and signal rod left side welded connection, shake off the board bottom surface and inlay firmly with the signal rod skin, get rid of the head left side and inlay firmly with the signal rod right side and be connected, it is equipped with two to shake the board, and two shake the board mirror image distribution of falling and be in the signal rod upper and lower face.

Furthermore, shake off the board and include layer board, shrink frame, compression leg, beat the structure, layer board top surface and shrink frame integrated into one piece, shrink frame inlayer is connected through the compression leg with beat the structure bottom surface and inlay firmly, beat the structure and be equipped with threely, three beat the structure clearance and distribute in the layer board top surface evenly.

Furthermore, the structure of falling includes underframe, installation piece, bounce ball, swing structure, the underframe inner layer is through installation piece and swing structure middle section activity block, the bounce ball bottom surface is inlayed and is consolidated in the underframe inner layer, the bounce ball is equipped with two, and two bounce balls mirror image distributions are in the underframe inner layer.

Furthermore, the swing structure includes swivel becket, last swing plate, strikes head, resilience groove, the swivel becket outer loop is connected with last swing plate middle section is inlayed admittedly, strike the head and imbed in last swing plate top surface, resilience groove and last swing plate bottom surface be integrated into one piece, it is equipped with twelve to strike the head, and six a set of mirror image distributions of twelve impact heads are in last swing plate top surface.

Furthermore, the impact head comprises an outer pull ring, an inner pressure frame, an extrusion strip and an impact head, wherein the outer ring of the outer pull ring is fixedly connected with the bottom surface of the impact head through the inner pressure frame, two ends of the extrusion strip are embedded into the inner layer of the inner pressure frame, and the inner layer of the outer pull ring is provided with twelve V-shaped groove structures with uniform gaps.

Furthermore, the impact head comprises a bottom block, a pressure head, a pendulum bob, an impact plate and an impact ball, the bottom surface of the pressure head is connected with the top surface of the bottom block in a welding mode, the bottom of the pendulum bob is movably clamped with the inner layer of the bottom block, two ends of the impact plate are embedded into the inner layer of the bottom block, the outer layer of the impact ball is in mutual contact with the inner layer of the bottom block, and the outer layer of the bottom block is provided with fourteen sharpened triangular protruding structures.

Advantageous effects

Compared with the prior art, the invention has the following beneficial effects:

when the base station is installed in an environment with more ice and snow, the weight of the ice and snow on the signal rod is continuously increased due to the gradual accumulation of the ice and snow, the signal rod is continuously pressed to cause the outer shell to rotate, and the sliding rod is further relatively displaced.

Drawings

Fig. 1 is a schematic three-dimensional structure diagram of a 5G communication base station according to the present invention.

Fig. 2 is a schematic structural diagram of a top view cross section of the signal transmitter of the present invention.

FIG. 3 is a schematic structural diagram of a front cross section of a signal rod according to the present invention.

FIG. 4 is a schematic structural view of a front cross-section of an extended rod of the present invention.

Fig. 5 is a schematic structural view of a front cross section of the shake-down plate of the present invention.

FIG. 6 is a schematic structural view of a front cross-section of the drop structure of the present invention.

Fig. 7 is a schematic structural view of a front section of the swing structure of the present invention.

FIG. 8 is a schematic structural diagram of a front cross section of the impact head of the present invention.

Fig. 9 is a schematic structural view of a front cross section of the impact head of the present invention.

In the figure: the device comprises a machine body-1, a fixed bar-2, a signal transmitter-3, a connecting plate-4, a fixed block-31, a receiving plate-32, a stable spring-33, a signal rod-34, an extension rod-341, an outer shell-342, a reverse thrust groove-343, a sliding rod-344, a compression rod-345, an inner shaft-346, a connecting sleeve-A1, a signal rod-A2, a shake-off plate-A3, a swinging head-A4, a supporting plate-A31, a contraction frame-A32, a compression column-A33, a knock-off structure-A34, a bottom frame-B1, an installation block-B2, a rebound ball-B3, a swinging structure-B4, a rotating ring-B41, a swing-B42, an impact head-B43, a rebound groove-B44, an outer pull ring-C1, an inner pressure frame-C2, a pressing bar-C3, Impact head-C4, bottom block-C41, pressure head-C42, pendulum-C43, impact plate-C44 and impact ball-C45.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are some, not all embodiments of the present invention, and all other embodiments obtained by those skilled in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

The first embodiment is as follows:

referring to fig. 1-6, the embodiments of the present invention are as follows: A5G communication base station structurally comprises a machine body 1, a fixing strip 2, a signal emitter 3 and a connecting plate 4, wherein the front surface of the machine body 1 is connected with the back surface of the fixing strip 2 in a welding mode, the signal emitter 3 is embedded into the front surface of the machine body 1, and the back surface of the connecting plate 4 is fixedly connected with the front surface of the machine body 1 in an embedding mode; signal transmitter 3 includes fixed block 31, receiving plate 32, stabilizes spring 33, signal rod 34, receiving plate 32 imbeds inside fixed block 31, the lower extreme is connected with fixed block 31 inlayer embedding through stabilizing spring 33 about signal rod 34, signal rod 34 left side and receiving plate 32 right side activity block, it is equipped with two to stabilize spring 33, and two stabilize spring 33 mirror image distributions are in signal rod 34 upper and lower faces, are favorable to making wobbling signal rod 34 to revert fast.

The signal rod 34 includes an extension rod 341, an outer shell 342, a thrust reversal groove 343, a sliding rod 344, a pressure rod 345 and an inner shaft 346, the left side of the extension rod 341 is fixedly embedded in the outer ring of the outer shell 342, the thrust reversal groove 343 and the inner part of the outer shell 342 are integrally formed, the top end of the sliding rod 344 is movably connected with the inner layer of the thrust reversal groove 343, the left side of the sliding rod 344 is fixedly embedded in the outer ring of the inner shaft 346 through the pressure rod 345, the number of the pressure rods 345 is four, and the four pressure rods 345 are uniformly and annularly distributed in the outer ring of the inner shaft 346 at intervals, so that the maximum elastic force is increased, and the upward swinging is more rapid and.

The extending rod 341 includes a connecting sleeve a1, a signal rod a2, a shaking plate A3 and a shaking head a4, the right side of the connecting sleeve a1 is connected with the left side of the signal rod a2 in a welding manner, the bottom surface of the shaking plate A3 is embedded and fixed on the outer layer of the signal rod a2, the left side of the shaking head a4 is embedded and fixed on the right side of the signal rod a2, the shaking plate A3 is provided with two shaking plates A3, and the two shaking plates A3 are arranged on the upper surface and the lower surface of the signal rod a2 in a mirror image manner, so that the ice layer can be damaged from the upper surface.

Wherein, shake off board A3 includes layer board A31, shrink frame A32, compression leg A33, falls structure A34, layer board A31 top surface and shrink frame A32 are integrated into one piece, shrink frame A32 inlayer is connected through compression leg A33 and the bottom surface of falling structure A34 embedment, it is equipped with threely to fall structure A34, and three structure A34 clearance of falling distributes evenly on layer board A31 top surface, is favorable to increasing the area of falling ice and snow.

The falling structure A34 comprises a bottom frame B1, mounting blocks B2, bouncing balls B3 and a swinging structure B4, the inner layer of the bottom frame B1 is movably clamped with the middle section of the swinging structure B4 through the mounting blocks B2, the bottom surface of the bouncing balls B3 is embedded in the inner layer of the bottom frame B1, the bouncing balls B3 are two, the two bouncing balls B3 are distributed in the inner layer of the bottom frame B1 in a mirror image mode, bouncing of the swinging structure B4 from two sides is facilitated, and swinging balance is kept.

Based on the above embodiment, the specific working principle is as follows: the base station is locked at a required position through the fixing strip 2, a wired signal source is accessed through the connecting plate 4, wireless signals are output to the outside through the signal emitter 3, when the base station is used in a northern cold environment, ice and snow can be accumulated on the signal rod 34 of the signal emitter 3, the signal rod 34 can be caused to move downwards to press the stabilizing spring 33 and twist the outer shell 342, the sliding rod 344 can slide in the reverse pushing groove 343 and press the pressing rod 345 to generate elastic force, when the sliding rod 344 slides to reversely push one end of the groove 343, the sliding rod 344 can be caused to extend outwards and lose constraint, the pressing rod 345 releases the elastic force to jack the sliding rod 343 quickly, the extending rod 341 is thrown upwards to shake the snow accumulated on the shaking plate A3, meanwhile, in the process of upward throwing, the small ball structure in the shaking head A4 impacts the inside the shaking head A4 to generate a shaking enhancement shaking effect, and after the shaking head is thrown to the limit, the shaking-off plate A3 continuously moves upwards due to inertia, so that the shaking-off structure A34 of the shaking-off plate A3 moves upwards, the pressing column A33 is pulled, the swinging structure B4 of the shaking-off structure A34 swings upwards and falls after impacting an ice layer to break the ice layer, the bottom of the swinging structure B4 impacts on the bounce ball B3, the bouncing is further continuously performed, the ice layer is repeatedly beaten, and the ice layer is broken and beaten.

Example two:

referring to fig. 7-9, the embodiment of the present invention is as follows: swing structure B4 includes swivel ring B41, goes up balance B42, impact head B43, resilience groove B44, swivel ring B41 outer loop and last balance B42 middle section are embedded solid and are connected, impact head B43 embedding is in last balance B42 top surface, resilience groove B44 and last balance B42 bottom surface are integrated into one piece, impact head B43 is equipped with twelve, and six a set of mirror image distributions of twelve impact head B43 are in last balance B42 top surface, are favorable to increasing the intensity of impact, make the ice sheet destroyed to littleer piece.

The impact head B43 comprises an outer pull ring C1, an inner pressure frame C2, an extrusion strip C3 and an impact head C4, wherein the outer ring of the outer pull ring C1 is fixedly embedded and connected with the bottom surface of the impact head C4 through an inner pressure frame C2, two ends of the extrusion strip C3 are embedded into the inner layer of the inner pressure frame C2, and the inner layer of the outer pull ring C1 is provided with twelve V-shaped groove structures with uniform gaps, so that the impact head is rapidly deformed when thrown out, and resistance is reduced.

The impact head C4 comprises a bottom block C41, a pressure head C42, a pendulum bob C43, an impact plate C44 and an impact ball C45, wherein the bottom surface of the pressure head C42 is connected with the top surface of the bottom block C41 in a welding mode, the bottom of the pendulum bob C43 is movably clamped with the inner layer of the bottom block C41, two ends of the impact plate C44 are embedded into the inner layer of the bottom block C41, the outer layer of the impact ball C45 is in contact with the inner layer of the bottom block C41, and the outer layer of the bottom block C41 is provided with fourteen sharp triangular protruding structures, so that an additional cutting effect can be generated after the ice layer is inserted.

Based on the above embodiment, the specific working principle is as follows: when the swing structure B4 is subjected to inertia, the swinging plate B42 is caused to rotate upwards along the rotating ring B41, the impact head B43 directly impacts on the ice layer, after the impact head B43 moves upwards to the limit, the inertia continues to move upwards, the outer pull ring is stretched, after the impact head C4 contacts the ice layer, the inner pressing frame C2 is pressed at one moment to generate inward deformation, the pressing strip C3 is pressed, the pressing strip C3 generates outward expanding elastic force at the same time, the elastic force is applied to the inner pressing frame C2 to expand the inner pressing frame towards two sides, the upward pushing force of the impact head C4 is increased, the inertia force and the upward pushing force generated by the inner pressing frame C2 are concentrated on one point of the ice layer through the pressure head C42 of the impact head C4, the single-point unit pressure is increased sharply, the ice layer can be punctured, and meanwhile, the pendulum C43 generates swinging due to the inertia inside, the crushing device is rotated along the bottom to impact on an impact plate C44, an impact ball C45 is flicked to impact with the inner layer of a bottom block C41 to generate vibration, the vibration is applied to an ice layer through a pressure head C43, the crushing speed of the ice layer is accelerated, and after the ice layer is crushed and inserted into the ice layer, the ice layer is cut through a sharpened triangular convex structure arranged on the outer layer of the bottom block C41, so that the ice layer structure is cracked and falls off from the surface of a base station.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

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.

Claims

1. The utility model provides a 5G communication base station, its structure includes organism (1), fixed strip (2), signal transmitter (3), fishplate bar (4), its characterized in that:

the front surface of the machine body (1) is connected with the back surface of the fixing strip (2) in a welding mode, the signal emitter (3) is embedded into the front surface of the machine body (1), and the back surface of the connecting plate (4) is fixedly connected with the front surface of the machine body (1);

the signal transmitter (3) comprises a fixed block (31), a receiving plate (32), a stabilizing spring (33) and a signal rod (34), wherein the receiving plate (32) is embedded into the fixed block (31), the upper surface and the lower surface of the signal rod (34) are fixedly connected with the inner layer of the fixed block (31) through the stabilizing spring (33), and the left side of the signal rod (34) is movably clamped with the right side of the receiving plate (32).

2. A 5G communication base station according to claim 1, wherein: the signal rod (34) comprises an extension rod (341), an outer shell (342), a reverse thrust groove (343), a sliding rod (344), a pressure rod (345) and an inner shaft (346), the left side of the extension rod (341) is fixedly embedded with the outer ring of the outer shell (342), the reverse thrust groove (343) and the inner part of the outer shell (342) are integrally formed, the top end of the sliding rod (344) is movably connected with the inner layer of the reverse thrust groove (343), and the left side of the sliding rod (344) is fixedly embedded with the outer ring of the inner shaft (346) through the pressure rod (345).

3. A 5G communication base station according to claim 2, wherein: the extension rod (341) comprises a connecting sleeve (A1), a signal rod (A2), a shaking plate (A3) and a swinging head (A4), wherein the right side of the connecting sleeve (A1) is connected with the left side of the signal rod (A2) in a welding mode, the bottom surface of the shaking plate (A3) is embedded and fixed on the outer layer of the signal rod (A2), and the left side of the swinging head (A4) is embedded and fixed on the right side of the signal rod (A2).

4. A 5G communication base station according to claim 3, wherein: shake board (A3) and include layer board (A31), shrink frame (A32), compression leg (A33), beat structure (A34) down, layer board (A31) top surface and shrink frame (A32) are integrated into one piece, shrink frame (A32) inlayer is connected through compression leg (A33) and beating down structure (A34) bottom surface embedded solid.

5. A5G communication base station according to claim 4, characterized in that: the hitting structure (A34) comprises a bottom frame (B1), an installation block (B2), a rebound ball (B3) and a swing structure (B4), wherein the bottom frame (B1) is movably clamped with the middle section of the swing structure (B4) through the installation block (B2), and the bottom surface of the rebound ball (B3) is fixedly embedded in the bottom frame (B1) inner layer.

6. A5G communication base station according to claim 5, characterized in that: swing structure (B4) include swivel becket (B41), go up balance staff (B42), impact head (B43), resilience groove (B44), swivel becket (B41) outer loop and last balance staff (B42) middle section are inlayed and are fixed and are connected, impact head (B43) are embedded in last balance staff (B42) top surface, resilience groove (B44) and last balance staff (B42) bottom surface are integrated into one piece.

7. A 5G communications base station according to claim 6, wherein: the impact head (B43) comprises an outer pull ring (C1), an inner pressure frame (C2), an extrusion strip (C3) and an impact head (C4), wherein the outer ring of the outer pull ring (C1) is fixedly connected with the bottom surface of the impact head (C4) through an inner pressure frame (C2), and two ends of the extrusion strip (C3) are embedded into the inner layer of the inner pressure frame (C2).

8. A 5G communication base station according to claim 7, wherein: the impact head (C4) comprises a bottom block (C41), a pressure head (C42), a pendulum bob (C43), an impact plate (C44) and an impact ball (C45), wherein the bottom surface of the pressure head (C42) is connected with the top surface of the bottom block (C41) in a welding mode, the bottom of the pendulum bob (C43) is movably clamped with the inner layer of the bottom block (C41), two ends of the impact plate (C44) are embedded into the inner layer of the bottom block (C41), and the outer layer of the impact ball (C45) is in contact with the inner layer of the bottom block (C41).