CN110499946B - 5G distributed network architecture communication tower erection device - Google Patents

Abstract

The invention relates to the field of communication, in particular to a communication tower erection device with a 5G distributed network architecture, which comprises an erection plate, a middle adjusting seat, a rectangular frame, a fixed underframe and a rope pulling device. Erect the dish and pass through threaded connection and adjust the seat in, erect the dish and adjust the meshing transmission between the seat in with, well regulation seat sliding connection is on the rectangle frame in vertical direction, and the rectangle frame is sliding connection in the upper end of fixed chassis in the front and back direction, and the rope pulling device is provided with four, and four rope pulling devices all rotate to be connected in the upper end of rectangle frame, erect the dish and all rotate with four rope pulling devices and be connected.

Description

5G distributed network architecture communication tower erection device

Technical Field

The invention relates to the field of communication, in particular to a communication tower erection device with a 5G distributed network architecture.

Background

Application number is CN201520981167.0 discloses a modularization communication tower, this utility model relates to a modularization communication tower, has solved among the prior art when communication tower erects that construction cost is high, the not enough of tower body non-used repeatedly. The utility model provides a pair of modularization communication tower, be fixed with the tower body on the base that is formed by a plurality of member concatenations, and be fixed with on the base and carry out the balancing weight fixed to the tower body, it is fixed by connecting bolt between the member, the tower body adopts releasable connection's mode combination to form by a plurality of sections tower body, when setting up the tower body, place the balancing weight in suitable position, then fix the base of assembling together with the balancing weight again, the tower body that finishes is assembled to the equipment again after base and the fixed completion of balancing weight is fixed on the base, at last fixed vaulting pole between base and tower body, need not be to the base in the work progress, the balancing weight is pre-buried, utilize the weight of balancing weight to fix the tower body, construction cost when having reduced communication tower set up greatly. But the utility model discloses a can not be convenient for carry out direction control and fixed to the communication tower.

Disclosure of Invention

The invention provides a communication tower erection device with a 5G distributed network architecture, which has the beneficial effects that a communication tower can be arranged on the communication tower erection device, and the communication tower can be conveniently adjusted and fixed in direction.

The invention relates to the field of communication, in particular to a communication tower erection device with a 5G distributed network architecture, which comprises an erection plate, a middle adjusting seat, a rectangular frame, a fixed underframe and a rope pulling device.

Erect the dish and pass through threaded connection and adjust the seat in, erect the dish and adjust the meshing transmission between the seat in with, well regulation seat sliding connection is on the rectangle frame in vertical direction, and the rectangle frame is sliding connection in the upper end of fixed chassis in the front and back direction, and the rope pulling device is provided with four, and four rope pulling devices all rotate to be connected in the upper end of rectangle frame, erect the dish and all rotate with four rope pulling devices and be connected.

The frame erecting plate comprises a circular ring, a cross plate, fixing seats, a sliding gear, a center shaft, a vertical groove and a blocking ring, the cross plate is fixedly connected to the circular ring, the four fixing seats are uniformly distributed on the cross plate in an annular mode, screw inserting holes are formed in the four fixing seats, the center shaft is fixedly connected to the middle position of the lower end of the cross plate, the vertical groove is axially formed in the center shaft, the sliding gear is connected to the center shaft and the vertical groove in a sliding mode, and the blocking ring is fixedly connected to the upper end and the lower end of the sliding gear.

Well regulation seat includes the slat, motor II, the upstand, fastening screw I, gear and lift door-shaped piece, the equal fixedly connected with upstand in both ends around the slat, both ends difference sliding connection is on two upstands around the lift door-shaped piece, both ends all have fastening screw I through threaded connection around the lift door-shaped piece, two fastening screw I push up respectively on two upstands, the axis cooperatees through the middle part of screw thread with the lift door-shaped piece, the smooth gear is located the downside of lift door-shaped piece, the upper end fixedly connected with motor II of slat, fixedly connected with gear on motor II's the output shaft, gear and smooth gear meshing transmission, the gear is located two and keeps off between the ring.

The rectangle frame is last to be provided with well spout, L shape backup pad, round bar and lug, the equal fixedly connected with round bar in four angle departments of rectangle frame upside, and both ends all are provided with well spout around the inboard middle part of rectangle frame, and both ends difference sliding connection is on two well spouts around the lift door-shaped piece, the equal fixedly connected with L shape backup pad in the left and right sides of rectangle frame, fixedly connected with lug in one of them L shape backup pad.

The 5G distributed network architecture communication tower erection device further comprises a motor I, wherein the motor I is provided with two convex plates and a screw rod, the two convex plates are arranged in the front and at the back, the motor I is fixedly connected to one of the convex plates, the screw rod is fixedly connected to an output shaft of the motor I, the front end and the back end of the screw rod are respectively rotatably connected to the two convex plates, and the screw rod is matched with the convex blocks through threads.

Fixed chassis includes the hack lever around, control the hack lever, trapezoidal sand grip and peg, be provided with two around the hack lever, the hack lever about equal fixedly connected with between the left end of hack lever and between the right-hand member of two front and back hack levers around two around, the upside of hack lever all is provided with trapezoidal sand grip about two, the equal fixedly connected with peg in both ends about two of hack lever downside around two, both ends difference sliding connection is at the middle part of hack lever around two around the slat, the lower extreme difference sliding connection of two L shape backup pads is on two trapezoidal sand grips, the lower extreme difference fixed connection of two flanges is on two hack levers.

The rope pulling device comprises a rotating wheel, an annular groove, a rope pulling block, a vertical sliding rod, a hand screw, a flat rod and a tying ring, wherein the annular groove is formed in the rotating wheel; the four rotating wheels are respectively connected to the four round rods in a rotating mode, and the circular rings are inserted into four annular grooves in the four rotating wheels.

5G distributed network architecture communication tower frame establishes device still includes the arc slide, all is provided with two around the arc slide, is located to be connected through connecting the center pillar between two arc slides of front end, is located to be connected through connecting the center pillar between two arc slides of rear end, and both ends difference fixed connection is on two connection center pillars around the slat.

The 5G distributed network architecture communication tower erection device further comprises a manual adjustment sliding block, wherein a vertical blind hole, a fastening screw II and a pulley are arranged on the manual adjustment sliding block, the vertical blind hole is formed in the upper end of the manual adjustment sliding block, the lower end of the manual adjustment sliding block is rotatably connected with the two pulleys, and the lower end of the manual adjustment sliding block is connected with the fastening screw II through threads; the manual adjustment sliding blocks are four in number, the four manual adjustment sliding blocks are connected to the four arc-shaped sliding ways in a sliding mode respectively, the two pulleys on the same manual adjustment sliding block are located on two sides of the corresponding arc-shaped sliding ways respectively, and the four fastening screws II are supported on the outer sides of the four arc-shaped sliding ways respectively.

The 5G distributed network architecture communication tower erection device has the beneficial effects that:

according to the 5G distributed network architecture communication tower erection device, when the middle shaft rotates on the lifting door-shaped part by taking the axis of the middle shaft as a shaft, the middle shaft vertically moves relative to the lifting door-shaped part, and then the heights of a ring and a communication tower are adjusted.

Sometimes, the communication tower needs to be rotated to change the direction of the communication tower, the height of the communication tower does not need to be changed, at the moment, the communication tower can be driven to rotate through the gear to change the direction of the communication tower, and then the height of the lifting door-shaped piece is adjusted, so that the original height of the communication tower is kept.

The two L-shaped supporting plates respectively slide back and forth on the two trapezoidal raised lines to finally drive the whole rectangular frame and the erection plate to move back and forth, and the position of the communication tower is adjusted in the front and back direction.

The manual adjustment slider can drive corresponding vertical slide bar, flat bar and rotation wheel when sliding and use the axis of corresponding round bar to rotate as the axle, changes the direction of four flat bars, and then changes the direction of dragging of drawing rope piece to four wire rope, adjusts wire rope's the direction of dragging to suitable position.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic overall structure diagram of a 5G distributed network architecture communication tower erection device according to the present invention;

fig. 2 is a schematic diagram of an overall structure of a 5G distributed network architecture communication tower erection device according to the present invention;

fig. 3 is a schematic partial structure diagram of a communication tower erection device with a 5G distributed network architecture according to the present invention;

fig. 4 is a schematic partial structural diagram of a communication tower erection device with a 5G distributed network architecture according to the present invention;

FIG. 5 is a first schematic structural view of the mounting plate;

FIG. 6 is a second schematic structural view of the mounting plate;

FIG. 7 is a schematic structural view of the middle adjustment seat;

FIG. 8 is a first structural diagram of a rectangular frame and a motor I;

FIG. 9 is a second schematic structural diagram of a rectangular frame and a motor I;

FIG. 10 is a first view illustrating a structure of a fixed chassis;

FIG. 11 is a second schematic structural view of a fixed chassis;

FIG. 12 is a first schematic view of the construction of the rope pulling device;

FIG. 13 is a second schematic structural view of the cord retractor;

FIG. 14 is a schematic structural view of an arcuate chute;

FIG. 15 is a first schematic structural view of a manual adjustment slider;

fig. 16 is a structural schematic diagram of a hand-adjusting slider.

In the figure: erecting a tray 1; 1-1 of a circular ring; 1-2 of a cross plate; a fixed seat 1-3; 1-4 of a sliding gear; 1-5 of a middle shaft; 1-6 of vertical groove; 1-7 parts of baffle ring; a middle adjusting seat 2; 2-1 of laths; motor II 2-2; 2-3 of vertical columns; fastening screw I2-4; 2-5 parts of gear; lifting door parts 2-6; a rectangular frame 3; a middle chute 3-1; an L-shaped support plate 3-2; 3-3 parts of a round rod; 3-4 parts of a bump; 3-5 of a bump; motor I4; 4-1 of a convex plate; 4-2 parts of a screw rod; a fixed chassis 5; front and rear frame rods 5-1; 5-2 of left and right frame rods; 5-3 trapezoidal convex strips; 5-4 of plug pins; a rope puller 6; a rotating wheel 6-1; an annular groove 6-2; 6-3 of a pull rope block; 6-4 of a vertical sliding rod; 6-5 parts of hand-screwed screw; 6-6 of a flat rod; 6-7 of a tie ring; an arc-shaped slideway 7; connecting the central columns 7-1; a manual adjustment slide block 8; 8-1 of vertical blind holes; fastening screw II 8-2; and 8-3 of pulleys.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

The first embodiment is as follows:

the present invention is described below with reference to fig. 1 to 16, and the present invention relates to the field of communications, and more specifically, to a communication tower erection device with a 5G distributed network architecture, which includes an erection tray 1, a middle adjustment seat 2, a rectangular frame 3, a fixed underframe 5 and a rope puller 6.

Erect dish 1 and adjust on seat 2 through threaded connection in, erect the dish 1 and adjust the meshing transmission between the seat 2 in with, well adjust seat 2 sliding connection on vertical direction on rectangle frame 3, rectangle frame 3 sliding connection is in the upper end of fixed chassis 5 in the front and back direction, stay cord ware 6 is provided with four, and four stay cord wares 6 all rotate to be connected in the upper end of rectangle frame 3, erect dish 1 and four stay cord wares 6 all rotate to be connected.

The second embodiment is as follows:

in the following, referring to fig. 1-16, the mounting plate 1 includes a circular ring 1-1, a cross plate 1-2, and a fixing seat 1-3, the sliding gear comprises a sliding gear 1-4, a center shaft 1-5, vertical grooves 1-6 and stop rings 1-7, wherein a cross plate 1-2 is fixedly connected to a circular ring 1-1, four fixing seats 1-3 are uniformly distributed on the cross plate 1-2 in an annular manner, screw jacks are arranged on the four fixing seats 1-3, the center shaft 1-5 is fixedly connected to the middle position of the lower end of the cross plate 1-2, the vertical grooves 1-6 are axially arranged on the center shaft 1-5, the sliding gear 1-4 is connected to the center shaft 1-5 and the vertical grooves 1-6 in a sliding manner, and the stop rings 1-7 are fixedly connected to the upper end and the lower end of the sliding gear 1-4. The communication tower is placed at the upper ends of the four fixing seats 1-3, the four bottom corners of the communication tower are respectively and fixedly connected to the four fixing seats 1-3 through screws, and then the communication tower is fixed at the upper end of the circular ring 1-1. The sliding gears 1-4 can vertically slide on the middle shafts 1-5, and the sliding gears 1-4 are also connected to the vertical grooves 1-6 in a sliding mode, so that the sliding gears 1-4 can only vertically slide on the middle shafts 1-5, the sliding gears 1-4 cannot rotate on the middle shafts 1-5 by taking the axes of the middle shafts 1-5 as axes, and the sliding gears 1-4 can drive the middle shafts 1-5 to rotate when rotating.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 16, the middle adjusting seat 2 includes a strip plate 2-1, a motor II2-2, vertical posts 2-3, fastening screws I2-4, gears 2-5 and a lifting door 2-6, the front and rear ends of the strip plate 2-1 are fixedly connected with the vertical posts 2-3, the front and rear ends of the lifting door 2-6 are respectively slidably connected to the two vertical posts 2-3, the front and rear ends of the lifting door 2-6 are respectively connected with the fastening screws I2-4 through threads, the two fastening screws I2-4 are respectively supported on the two vertical posts 2-3, a middle shaft 1-5 is matched with the middle part of the lifting door 2-6 through threads, the sliding gears 1-4 are located at the lower side of the lifting door 2-6, the upper end of the strip plate 2-1 is fixedly connected with the motor II2-2, the output shaft of the motor II2-2 is fixedly connected with a gear 2-5, the gear 2-5 is in meshed transmission with a sliding gear 1-4, and the gear 2-5 is positioned between two retaining rings 1-7. When the output shaft of the motor II2-2 rotates, the gear 2-5 is driven to rotate, the gear 2-5 drives the sliding gear 1-4 and the middle shaft 1-5 to rotate by taking the axis of the middle shaft 1-5 as a shaft, and when the middle shaft 1-5 rotates on the lifting door-shaped part 2-6 by taking the axis of the middle shaft 1-5 as a shaft, the middle shaft 1-5 vertically moves relative to the lifting door-shaped part 2-6, so that the heights of the circular ring 1-1 and the communication tower are adjusted. Because the lifting door-shaped parts 2-6 can vertically slide on the two vertical columns 2-3, the lifting door-shaped parts 2-6 can be fixed on the two vertical columns 2-3 by rotating the two fastening screws I2-4, sometimes the communication tower needs to be rotated to change the direction of the communication tower, and the height of the communication tower does not need to be changed, at this time, the communication tower can be driven to rotate by the gears 2-5 to change the direction of the communication tower, and then the height of the lifting door-shaped parts 2-6 is adjusted, so that the communication tower can keep the original height.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 16, the rectangular frame 3 is provided with a middle chute 3-1, an L-shaped support plate 3-2, a round bar 3-3 and a projection 3-4, the round bar 3-3 is fixedly connected to four corners of the upper side of the rectangular frame 3, the middle chutes 3-1 are respectively provided at the front and rear ends of the middle part of the inner side of the rectangular frame 3, the front and rear ends of the lifting door-shaped member 2-6 are respectively slidably connected to the two middle chutes 3-1, the L-shaped support plates 3-2 are fixedly connected to the left and right sides of the rectangular frame 3, and one of the L-shaped support plates 3-2 is fixedly connected to the projection 3-4. The front end and the rear end of the lifting door-shaped part 2-6 can respectively vertically slide on the two middle chutes 3-1, and the lifting door-shaped part 2-6 and the whole middle adjusting seat 2 can be driven to move back and forth when the rectangular frame 3 moves back and forth.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 16, the 5G distributed network architecture communication tower erection device further includes a motor I4, the motor I4 is provided with two convex plates 4-1 and a screw rod 4-2, the convex plates 4-1 are arranged in front of and behind, the motor I4 is fixedly connected to one of the convex plates 4-1, the output shaft of the motor I4 is fixedly connected to the screw rod 4-2, the front end and the rear end of the screw rod 4-2 are respectively rotatably connected to the two convex plates 4-1, and the screw rod 4-2 is matched with the convex blocks 3-4 through threads.

The sixth specific implementation mode:

referring to fig. 1-16, the embodiment will be described, wherein the fixed chassis 5 comprises a front and a rear frame rods 5-1, a left and a right frame rods 5-2, trapezoidal ribs 5-3 and studs 5-4, two front and rear frame rods 5-1 are arranged in front and at rear, a left and a right frame rods 5-2 are fixedly connected between the left ends of the two front and rear frame rods 5-1 and between the right ends of the two front and rear frame rods 5-1, the upper sides of the two left and right frame rods 5-2 are respectively provided with trapezoidal ribs 5-3, the left and right ends of the lower sides of the two front and rear frame rods 5-1 are respectively fixedly connected with studs 5-4, the front and rear ends of the strip plate 2-1 are respectively slidably connected to the middle portions of the two front and rear frame rods 5-1, the lower, the lower ends of the two convex plates 4-1 are respectively fixedly connected to the two front and rear frame rods 5-1. When the output shaft of the motor I4 rotates, the projection 3-4 can be driven to move back and forth, at this time, the batten 2-1 can slide back and forth on the two front and rear frame rods 5-1 relative to the two front and rear frame rods 5-1, and further, the two L-shaped support plates 3-2 are driven to respectively slide back and forth on the two trapezoidal convex strips 5-3, finally, the whole rectangular frame 3 and the erection plate 1 are driven to move back and forth, and the position of the communication tower is adjusted in the front and rear directions. The four insert pins 5-4 may be buried in the ground, thereby stably fixing the fixed base frame 5 as a whole to the ground.

The seventh embodiment:

referring to fig. 1-16, the rope puller 6 comprises a rotating wheel 6-1, an annular groove 6-2, a rope pulling block 6-3, the device comprises a vertical sliding rod 6-4, a hand screw 6-5, a flat rod 6-6 and a tie ring 6-7, wherein an annular groove 6-2 is formed in a rotating wheel 6-1, the flat rod 6-6 is fixedly connected to the rotating wheel 6-1, the vertical sliding rod 6-4 is fixedly connected to the outer end of the flat rod 6-6, a pull rope block 6-3 is slidably connected to the flat rod 6-6, one end of the hand screw 6-5 is rotatably connected to the vertical sliding rod 6-4, the other end of the hand screw 6-5 is matched with the pull rope block 6-3 through threads, and the tie ring 6-7 is fixedly connected to the upper end of the pull rope block 6-3; the four rotating wheels 6-1 are respectively connected to the four round rods 3-3 in a rotating mode, and the circular rings 1-1 are inserted into the four annular grooves 6-2 on the four rotating wheels 6-1. When the circular ring 1-1 is lifted, the communication tower is driven to lift, and simultaneously, the four rotating wheels 6-1 are driven to vertically slide on the four circular rods 3-3 respectively, so that the four rotating wheels 6-1 are always at the same height with the circular ring 1-1, and the communication tower can be conveniently fixed by pulling ropes on the next step. Meanwhile, the four rotating wheels 6-1 also play a role in enabling the circular ring 1-1 to stably rotate and lift. When the communication tower is used, the upper ends of the four steel wire ropes are tied to the communication tower, the lower ends of the four steel wire ropes are tied to the four tie rings 6-7 respectively, the corresponding pull rope blocks 6-3 and the tie rings 6-7 can be driven to slide outwards by rotating the hand-screwed screws 6-5, the four steel wire ropes are tensioned, and the four steel wire ropes pull the communication tower, so that the communication tower is more stable. It should be noted that the communication tower needs to be pulled by using the wire rope after the position of the communication tower is adjusted.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1 to 16, the 5G distributed network architecture communication tower erection device further includes two arc slideways 7, two arc slideways 7 are disposed at the front and the back of each arc slideway 7, the two arc slideways 7 located at the front end are connected with each other through a connecting central pillar 7-1, the two arc slideways 7 located at the back end are connected with each other through a connecting central pillar 7-1, and the front end and the back end of the slat 2-1 are respectively and fixedly connected to the two connecting central pillars 7-1. When the lath 2-1 slides forwards and backwards, the two connecting central columns 7-1 and the four arc-shaped slideways 7 can be driven to slide forwards and backwards.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 16, the 5G distributed network architecture communication tower erection device further includes a manual adjustment sliding block 8, the manual adjustment sliding block 8 is provided with a vertical blind hole 8-1, a fastening screw II8-2 and a pulley 8-3, the vertical blind hole 8-1 is arranged at the upper end of the manual adjustment sliding block 8, the lower end of the manual adjustment sliding block 8 is rotatably connected with the two pulleys 8-3, and the lower end of the manual adjustment sliding block 8 is connected with the fastening screw II8-2 through threads; four manual adjusting sliding blocks 8 are arranged, the four manual adjusting sliding blocks 8 are respectively connected to the four arc-shaped sliding ways 7 in a sliding mode, two pulleys 8-3 on the same manual adjusting sliding block 8 are respectively located on two sides of the corresponding arc-shaped sliding way 7, and four fastening screws II8-2 are respectively pressed against the outer sides of the four arc-shaped sliding ways 7. The four hand-adjusting sliding blocks 8 can respectively slide on the four arc-shaped sliding ways 7, and the pulleys 8-3 at the lower ends of the hand-adjusting sliding blocks 8 play a role in preventing the hand-adjusting sliding blocks 8 from being separated from the arc-shaped sliding ways 7. The position of the manual adjusting slide block 8 can be fixed by rotating the fastening screw II8-2 to prop against the arc-shaped slide way 7. When the manual adjusting sliding block 8 slides, the corresponding vertical sliding rod 6-4, the corresponding flat rod 6-6 and the corresponding rotating wheel 6-1 can be driven to rotate by taking the axis of the corresponding round rod 3-3 as an axis, the directions of the four flat rods 6-6 are changed, the pulling directions of the four steel wire ropes by the pulling rope block 6-3 are further changed, and the pulling directions of the steel wire ropes are adjusted to proper positions.

The working principle of the invention is as follows: the communication tower is placed at the upper ends of the four fixing seats 1-3, the four bottom corners of the communication tower are respectively and fixedly connected to the four fixing seats 1-3 through screws, and then the communication tower is fixed at the upper end of the circular ring 1-1. The sliding gears 1-4 can vertically slide on the middle shafts 1-5, and the sliding gears 1-4 are also connected to the vertical grooves 1-6 in a sliding mode, so that the sliding gears 1-4 can only vertically slide on the middle shafts 1-5, the sliding gears 1-4 cannot rotate on the middle shafts 1-5 by taking the axes of the middle shafts 1-5 as axes, and the sliding gears 1-4 can drive the middle shafts 1-5 to rotate when rotating. When the output shaft of the motor II2-2 rotates, the gear 2-5 is driven to rotate, the gear 2-5 drives the sliding gear 1-4 and the middle shaft 1-5 to rotate by taking the axis of the middle shaft 1-5 as a shaft, and when the middle shaft 1-5 rotates on the lifting door-shaped part 2-6 by taking the axis of the middle shaft 1-5 as a shaft, the middle shaft 1-5 vertically moves relative to the lifting door-shaped part 2-6, so that the heights of the circular ring 1-1 and the communication tower are adjusted. Because the lifting door-shaped parts 2-6 can vertically slide on the two vertical columns 2-3, the lifting door-shaped parts 2-6 can be fixed on the two vertical columns 2-3 by rotating the two fastening screws I2-4, sometimes the communication tower needs to be rotated to change the direction of the communication tower, and the height of the communication tower does not need to be changed, at this time, the communication tower can be driven to rotate by the gears 2-5 to change the direction of the communication tower, and then the height of the lifting door-shaped parts 2-6 is adjusted, so that the communication tower can keep the original height. The front end and the rear end of the lifting door-shaped part 2-6 can respectively vertically slide on the two middle chutes 3-1, and the lifting door-shaped part 2-6 and the whole middle adjusting seat 2 can be driven to move back and forth when the rectangular frame 3 moves back and forth. When the output shaft of the motor I4 rotates, the projection 3-4 can be driven to move back and forth, at this time, the batten 2-1 can slide back and forth on the two front and rear frame rods 5-1 relative to the two front and rear frame rods 5-1, and further, the two L-shaped support plates 3-2 are driven to respectively slide back and forth on the two trapezoidal convex strips 5-3, finally, the whole rectangular frame 3 and the erection plate 1 are driven to move back and forth, and the position of the communication tower is adjusted in the front and rear directions. The four insert pins 5-4 may be buried in the ground, thereby stably fixing the fixed base frame 5 as a whole to the ground. When the circular ring 1-1 is lifted, the communication tower is driven to lift, and simultaneously, the four rotating wheels 6-1 are driven to vertically slide on the four circular rods 3-3 respectively, so that the four rotating wheels 6-1 are always at the same height with the circular ring 1-1, and the communication tower can be conveniently fixed by pulling ropes on the next step. Meanwhile, the four rotating wheels 6-1 also play a role in enabling the circular ring 1-1 to stably rotate and lift. When the communication tower is used, the upper ends of the four steel wire ropes are tied to the communication tower, the lower ends of the four steel wire ropes are tied to the four tie rings 6-7 respectively, the corresponding pull rope blocks 6-3 and the tie rings 6-7 can be driven to slide outwards by rotating the hand-screwed screws 6-5, the four steel wire ropes are tensioned, and the four steel wire ropes pull the communication tower, so that the communication tower is more stable. It should be noted that the communication tower needs to be pulled by using the wire rope after the position of the communication tower is adjusted. When the lath 2-1 slides forwards and backwards, the two connecting central columns 7-1 and the four arc-shaped slideways 7 can be driven to slide forwards and backwards. The four hand-adjusting sliding blocks 8 can respectively slide on the four arc-shaped sliding ways 7, and the pulleys 8-3 at the lower ends of the hand-adjusting sliding blocks 8 play a role in preventing the hand-adjusting sliding blocks 8 from being separated from the arc-shaped sliding ways 7. The position of the manual adjusting slide block 8 can be fixed by rotating the fastening screw II8-2 to prop against the arc-shaped slide way 7. When the manual adjusting sliding block 8 slides, the corresponding vertical sliding rod 6-4, the corresponding flat rod 6-6 and the corresponding rotating wheel 6-1 can be driven to rotate by taking the axis of the corresponding round rod 3-3 as an axis, the directions of the four flat rods 6-6 are changed, the pulling directions of the four steel wire ropes by the pulling rope block 6-3 are further changed, and the pulling directions of the steel wire ropes are adjusted to proper positions.

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 (7)

1. The utility model provides a 5G distributed network architecture communication tower erects device, includes erects dish (1), well regulation seat (2), rectangle frame (3), fixed chassis (5) and stay cord ware (6), its characterized in that: the erection plate (1) is connected onto the middle adjusting seat (2) through threads, the erection plate (1) and the middle adjusting seat (2) are in meshing transmission, the middle adjusting seat (2) is connected onto the rectangular frame (3) in a sliding mode in the vertical direction, the rectangular frame (3) is connected onto the upper end of the fixed underframe (5) in a sliding mode in the front-rear direction, four rope pulling devices (6) are arranged, the four rope pulling devices (6) are connected onto the upper end of the rectangular frame (3) in a rotating mode, and the erection plate (1) is connected with the four rope pulling devices (6) in a rotating mode;

the erection plate (1) comprises a circular ring (1-1), a cross plate (1-2), a fixed seat (1-3), a sliding gear (1-4), a middle shaft (1-5), a vertical groove (1-6) and a baffle ring (1-7), a cross plate (1-2) is fixedly connected to the circular ring (1-1), four fixing seats (1-3) are annularly and uniformly distributed on the cross plate (1-2), screw jacks are formed in the four fixing seats (1-3), a middle shaft (1-5) is fixedly connected to the middle position of the lower end of the cross plate (1-2), vertical grooves (1-6) are axially formed in the middle shaft (1-5), a sliding gear (1-4) is slidably connected to the middle shaft (1-5) and the vertical grooves (1-6), and blocking rings (1-7) are fixedly connected to the upper end and the lower end of the sliding gear (1-4);

the middle adjusting seat (2) comprises a batten (2-1), a motor II (2-2), vertical posts (2-3), fastening screws I (2-4), gears (2-5) and lifting door-shaped parts (2-6), the front and rear ends of the batten (2-1) are fixedly connected with the vertical posts (2-3), the front and rear ends of the lifting door-shaped parts (2-6) are respectively connected onto the two vertical posts (2-3) in a sliding manner, the front and rear ends of the lifting door-shaped parts (2-6) are respectively connected with the fastening screws I (2-4) through threads, the two fastening screws I (2-4) are respectively propped against the two vertical posts (2-3), a middle shaft (1-5) is matched with the middle parts of the lifting door-shaped parts (2-6) through threads, and the sliding gears (1-4) are positioned at the lower sides of the lifting door-shaped parts (2-6), the upper end of the batten (2-1) is fixedly connected with a motor II (2-2), an output shaft of the motor II (2-2) is fixedly connected with a gear (2-5), the gear (2-5) is in meshing transmission with a sliding gear (1-4), and the gear (2-5) is positioned between two retaining rings (1-7).

2. The 5G distributed network architecture communication tower erection device of claim 1, wherein: the lifting door is characterized in that a middle sliding groove (3-1), L-shaped supporting plates (3-2), round rods (3-3) and a lug (3-4) are arranged on the rectangular frame (3), the round rods (3-3) are fixedly connected with four corners of the upper side of the rectangular frame (3), the middle sliding groove (3-1) is arranged at each of the front end and the rear end of the middle portion of the inner side of the rectangular frame (3), the front end and the rear end of the lifting door-shaped part (2-6) are respectively connected onto the two middle sliding grooves (3-1) in a sliding mode, the L-shaped supporting plates (3-2) are fixedly connected with the left side and the right side of the rectangular frame (3), and the lug (3-4) is fixedly.

3. The 5G distributed network architecture communication tower erection device of claim 2, wherein: the 5G distributed network architecture communication tower erection device further comprises a motor I (4), wherein the motor I (4) is provided with two convex plates (4-1) and two lead screws (4-2), the convex plates (4-1) are arranged in the front and at the back, the motor I (4) is fixedly connected to one of the convex plates (4-1), the output shaft of the motor I (4) is fixedly connected with the lead screws (4-2), the front end and the back end of each lead screw (4-2) are respectively rotatably connected to the two convex plates (4-1), and the lead screws (4-2) are matched with the convex blocks (3-4) through threads.

4. The 5G distributed network architecture communication tower erection device of claim 3, wherein: the fixed underframe (5) comprises a front hack lever and a rear hack lever (5-1), a left hack lever, a right hack lever (5-2), a trapezoidal convex strip (5-3) and a pin (5-4), wherein the front hack lever and the rear hack lever (5-1) are provided with two numbers, the left ends of the two front hack levers and the rear hack lever (5-1) and the right ends of the two front hack levers and the rear hack lever (5-1) are fixedly connected with the left hack lever and the right hack lever (5-2), the upper sides of the two left hack levers and the right hack lever (5-2) are provided with the trapezoidal convex strip (5-3), the left ends and the right ends of the lower sides of the two front hack levers and the rear hack levers (5-1) are fixedly connected with the pin (5-4), the front ends and the rear, the lower ends of the two convex plates (4-1) are respectively fixedly connected to the two front and rear frame rods (5-1).

5. The 5G distributed network architecture communication tower erection device of claim 4, wherein: the rope pulling device (6) comprises a rotating wheel (6-1), an annular groove (6-2), a rope pulling block (6-3), a vertical sliding rod (6-4), a hand screw (6-5), a flat rod (6-6) and a tie ring (6-7), wherein the annular groove (6-2) is formed in the rotating wheel (6-1), the flat rod (6-6) is fixedly connected to the rotating wheel (6-1), the outer end of the flat rod (6-6) is fixedly connected with the vertical sliding rod (6-4), a rope pulling block (6-3) is slidably connected to the flat rod (6-6), one end of the hand screw (6-5) is rotatably connected to the vertical sliding rod (6-4), and the other end of the hand screw (6-5) is matched with the rope pulling block (6-3) through threads, the upper end of the pull rope block (6-3) is fixedly connected with a tie ring (6-7); the four rotating wheels (6-1) are respectively connected to the four round rods (3-3) in a rotating manner, and the circular rings (1-1) are inserted into the four annular grooves (6-2) on the four rotating wheels (6-1).

6. The 5G distributed network architecture communication tower erection device of claim 5, wherein: the 5G distributed network architecture communication tower erection device further comprises arc-shaped slide ways (7), the number of the arc-shaped slide ways (7) is two, the two arc-shaped slide ways (7) located at the front end are connected through connecting center pillars (7-1), the two arc-shaped slide ways (7) located at the rear end are connected through connecting center pillars (7-1), and the front end and the rear end of each batten (2-1) are fixedly connected to the two connecting center pillars (7-1) respectively.

7. The 5G distributed network architecture communication tower erection device of claim 6, wherein: the 5G distributed network architecture communication tower erection device further comprises a manual adjustment sliding block (8), wherein a vertical blind hole (8-1), a fastening screw II (8-2) and a pulley (8-3) are formed in the manual adjustment sliding block (8), the vertical blind hole (8-1) is formed in the upper end of the manual adjustment sliding block (8), the lower end of the manual adjustment sliding block (8) is rotatably connected with the two pulleys (8-3), and the lower end of the manual adjustment sliding block (8) is connected with the fastening screw II (8-2) through threads; the number of the hand adjusting sliding blocks (8) is four, the four hand adjusting sliding blocks (8) are respectively connected to the four arc-shaped sliding ways (7) in a sliding mode, two pulleys (8-3) on the same hand adjusting sliding block (8) are respectively located on two sides of the corresponding arc-shaped sliding way (7), and the four fastening screws II (8-2) are respectively abutted to the outer sides of the four arc-shaped sliding ways (7).

Images