CN112761409A

CN112761409A - Auxiliary building system for 5G signal base station

Info

Publication number: CN112761409A
Application number: CN202011630319.4A
Authority: CN
Inventors: 李永东
Original assignee: Individual
Current assignee: Shenzhen Lingchuang Xingtong Technology Co ltd
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2021-05-07
Anticipated expiration: 2040-12-31
Also published as: CN112761409B

Abstract

The invention relates to the technical field of 5G equipment, in particular to an auxiliary building system of a 5G signal base station, which comprises a bearing device, a driving device, a stretching device, a clamping device, a building device, a lifting device, a locking device, a lifting device and a pit digging device, the signal base station support column tamping device comprises a bearing device, a stretching device, a lifting device, a locking device, a lifting device, a signal base station support column and a signal base station support column, wherein the bearing device is fixedly connected with the bearing device, the stretching device is connected to the bearing device in a sliding mode, the stretching device is connected with the driving device in a transmission mode, the clamping device is symmetrically connected to the front end and the rear end of the stretching device, the building device is connected with the two clamping devices, the building device is connected with the lifting device, the lifting device is connected with the stretching device in a sliding mode, the lifting device is connected with the locking device, the lifting device is connected with.

Description

Auxiliary building system for 5G signal base station

Technical Field

The invention relates to the technical field of 5G equipment, in particular to a 5G signal base station auxiliary building system.

Background

The existing patent numbers are: the utility model discloses a CN201520424612.3 on-site monitoring system for building a hydraulic machine information base station by using an Ethernet, which comprises a hydraulic machine monitoring terminal, a programmable controller, a hydraulic machine information base station, a remote terminal computer and an Ethernet communication network; the hydraulic machine monitoring terminal is connected with the programmable controller, the programmable controller is communicated with the hydraulic machine information base station through the Ethernet communication network, the hydraulic machine information base station is communicated with the remote terminal computer through the Ethernet communication network, the state of all hydraulic machines on an industrial field can be accurately monitored in real time in an office, the condition information of the hydraulic machines can be judged by equipment maintainers through industrial field monitoring, the automation degree of on-site hydraulic machine equipment maintenance of users is greatly improved, the machine states of all hydraulic machines on the industrial field can be accurately mastered, and the device is inconvenient to install and tamp a signal base station pillar.

Disclosure of Invention

The invention provides an auxiliary building system for a 5G signal base station, which has the beneficial effect that the auxiliary building system has the function of conveniently installing and tamping a signal base station pillar.

The invention relates to the technical field of 5G equipment, in particular to an auxiliary building system for a 5G signal base station, which comprises a bearing device, a driving device, an extending device, a clamping device, a building device, a lifting device, a locking device, a lifting device and a pit digging device.

Bear fixedly connected with drive arrangement on the device, stretching out device sliding connection bears the device on, stretching out device is connected with the drive arrangement transmission, both ends symmetric connection has clamping device around the stretching out device, builds the device and is connected with two clamping device, builds the device and is connected with the lifting device, lifting device and stretching out device sliding connection, the lifting device is connected with locking device, elevating gear with bear device sliding connection, elevating gear with stretch out device fixed connection, elevating gear is connected with the device of digging a pit.

As further optimization of the technical scheme, the bearing device of the 5G signal base station auxiliary building system comprises a bearing plate, a chute column and a slide bar, wherein the chute column is fixedly connected to the upper part of the bearing plate, and the slide bar is symmetrically and fixedly connected to the front end and the rear end of the upper part of the bearing plate.

As further optimization of the technical scheme, the driving device of the 5G signal base station auxiliary building system comprises a driving motor and a gear I, wherein the gear I is fixedly connected to an output shaft of the driving motor, and the driving motor is fixedly connected with the sliding chute column.

As further optimization of the technical scheme, the extension device of the 5G signal base station auxiliary building system comprises a transverse frame, a tooth groove, a sliding groove, a hinged seat, a hinged plate, limiting blocks and an L-shaped hole frame, wherein the tooth groove is formed in the lower portion of the transverse frame, the sliding groove is formed in the upper portion of the transverse frame, the hinged seat is fixedly connected to the transverse frame, the hinged plate is hinged to the hinged seat, the limiting blocks are fixedly connected to the front end and the rear end of the hinged plate, the two limiting blocks are matched with the hinged seat, the L-shaped hole frame is symmetrically and fixedly connected to the front end and the rear end of the hinged plate, the lower portion of the transverse frame is connected with sliding groove columns in a sliding mode, the tooth groove is in transmission connection with a gear I, and.

According to the technical scheme, the clamping device comprises a clamping block, a moving frame and an electric push rod I, the moving frame is fixedly connected to the clamping block, the electric push rod I is fixedly connected to the moving frame, the movable end of the electric push rod I is fixedly connected to the L-shaped hole frame, the moving frame is in sliding connection with the L-shaped hole frame, and the two clamping devices are symmetrically arranged.

As further optimization of the technical scheme, the building device of the 5G signal base station auxiliary building system comprises a building column, a knocking seat and sliding plates I, wherein the building column is provided with a plurality of building connecting blocks, the building connecting blocks are connected with a signal mechanism, the knocking seat is in sliding connection with the building column, the knocking seat is fixedly connected with a plurality of sliding plates I, the sliding plates I are locked with the building column through studs, the building column is matched with the two clamping blocks, and the side part of the building column is connected with the binding columns I through ropes.

As a further optimization of the technical scheme, the lifting device of the 5G signal base station auxiliary building system comprises a sliding frame, a spring plate, an upper frame, vertical columns, racks, a rotating frame and a lifting attaching plate, wherein the spring plate is fixedly connected to the sliding frame, the vertical columns are fixedly connected to the upper frame, the racks are fixedly connected to the vertical columns, the rotating frame is hinged to the upper frame, the lifting attaching plate is fixedly connected to the upper frame, circular arc attaching grooves are formed in the lifting attaching plate, the circular arc attaching grooves are matched with the building columns, the vertical columns are in sliding connection with the sliding frame, the rotating frame is in threaded transmission connection with the sliding frame, binding columns ii are symmetrically and fixedly connected to the front end and the rear end of the upper frame, the side portions of the building columns are connected with the two binding columns ii through ropes, the sliding frame is in sliding connection with the sliding grooves, and a moving handle is fixedly connected to the.

As a further optimization of the technical scheme, the locking device of the 5G signal base station auxiliary building system comprises a sliding block and a ratchet wheel, the sliding block is connected to the sliding frame in a sliding mode, a spring is sleeved between the sliding block and the spring plate, the ratchet wheel is connected to the sliding block in a hinged mode, and the ratchet wheel is in transmission connection with the rack.

As a further optimization of the technical scheme, the lifting device of the 5G signal base station auxiliary building system comprises a sliding plate II, a connecting frame, a lifting plate, an electric push rod II and a pit digging motor, wherein the connecting frame is symmetrically and fixedly connected to the sliding plate II, the electric push rod II is fixedly connected to the lifting plate, the movable end of the electric push rod II is fixedly connected to the upper portion of the sliding plate II, the sliding plate II is slidably connected to the lifting plate, the pit digging motor is fixedly connected to the lifting plate, a gear II is fixedly connected to an output shaft of the pit digging motor, the front end and the rear end of a hinged seat are respectively fixedly connected to the two connecting frames, and the sliding plate II is slidably connected to the two sliding strips.

As further optimization of the technical scheme, the pit digging device of the 5G signal base station auxiliary building system comprises a pit digging cylinder, a soil inlet and a gear ring, wherein a conical pipe is mounted at the lower part of the pit digging cylinder, the soil inlet is formed in the conical pipe, the gear ring is fixedly connected to the side part of the pit digging cylinder, the gear ring is in transmission connection with a gear II, the pit digging cylinder is hinged with a lifting plate, the lower part of the conical pipe is matched with a sliding plate II, and the lower part of the conical pipe is matched with a bearing plate.

The invention discloses a 5G signal base station auxiliary building system, which has the beneficial effects that:

the hole digging motor is started to rotate, the gear ring can rotate by taking the axis of the gear ring as a shaft, so that the hole digging barrel rotates by taking the axis of the gear ring as the shaft, the soil inlet on the conical pipe is further enabled to continuously dig the soil, the electric push rod II is started to stretch and retract at the moment, the conical pipe can be matched with the digging barrel to dig the pit, the lifting plate slides on the sliding plate II, furthermore, after the pit is dug by the conical pipe, soil can be left in the digging barrel, thereby after installing the post of building, take off the conical tube, pour out earth in the section of thick bamboo that will dig a hole fast, be convenient for tamp the bottom surface of building post department fast, further, articulated seat and two fixed designs together of link can make the device switch the position of building the post and digging a hole section of thick bamboo simultaneously to be convenient for install the back and tamp the operation to building the post.

Drawings

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

Fig. 1 is a schematic structural diagram of an overall 5G signal base station auxiliary building system according to the present invention;

FIG. 2 is a schematic structural diagram of a carrying device and a driving device;

FIG. 3 is a first schematic structural view of the extension device;

FIG. 4 is a second schematic structural view of the extension device;

FIG. 5 is a schematic view of the structure of the clamping device;

figure 6 is a schematic view of the construction apparatus;

FIG. 7 is a schematic view of the lifting device and locking device;

FIG. 8 is a schematic structural view of the lifting device;

fig. 9 is a schematic structural diagram of the earth boring device.

In the figure: a carrier device 1; a carrier plate 1-1; 1-2 of a chute column; 1-3 of a slide bar; a drive device 2; a driving motor 2-1; a gear I2-2; a protruding device 3; 3-1 of a transverse frame; 3-2 of tooth grooves; 3-3 of a chute; 3-4 of a hinge seat; hinge plates 3-5; 3-6 parts of a limiting block; 3-7 of an L-shaped hole frame; a clamping device 4; 4-1 of a clamping block; a moving frame 4-2; 4-3 of an electric push rod; building a device 5; building a column 5-1; 5-2 parts of a knocking seat; 5-3 of a sliding plate; a lifting device 6; a carriage 6-1; 6-2 of a spring plate; 6-3 of upper frame; 6-4 of vertical columns; 6-5 of a rack; 6-6 of a rotating frame; lifting the attaching plate 6-7; a locking device 7; a slider 7-1; a ratchet wheel 7-2; a lifting device 8; a sliding plate II 8-1; a connecting frame 8-2; 8-3 of a lifting plate; an electric push rod II 8-4; a pit digging motor 8-5; a pit digging device 9; digging a pit cylinder 9-1; 9-2 of a soil inlet; ring gear 9-3.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore are not to be construed as limiting the invention, and further, the terms "first", "second", etc., are used only for descriptive purposes and are not intended to indicate or imply relative importance or to implicitly indicate the number of technical features indicated, whereby the features defined as "first", "second", etc., may explicitly or implicitly include one or more of such features, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 9, the invention relates to the technical field of 5G equipment, and more specifically relates to an auxiliary building system for a 5G signal base station, which comprises a bearing device 1, a driving device 2, an extending device 3, a clamping device 4, a building device 5, a lifting device 6, a locking device 7, a lifting device 8 and a pit digging device 9.

The pit digging device is characterized in that a driving device 2 is fixedly connected to the bearing device 1, the extension device 3 is connected to the bearing device 1 in a sliding mode, the extension device 3 is in transmission connection with the driving device 2, the clamping devices 4 are symmetrically connected to the front end and the rear end of the extension device 3, the building device 5 is connected with the two clamping devices 4, the building device 5 is connected with the lifting device 6, the lifting device 6 is in sliding connection with the extension device 3, the lifting device 6 is connected with the locking device 7, the lifting device 8 is in sliding connection with the bearing device 1, the lifting device 8 is fixedly connected with the extension device 3, and the lifting device 8 is connected with the pit digging device; start-up drive arrangement 2 can drive extension device 3 and slide on bearing device 1, thereby adjust the focus position of device, the transportation and the use of the device of being convenient for then, position through adjustment lifting device 6, can drive and build device 5 and overturn on extension device 3, thereby make and build device 5 and can erect, be convenient for then install device 5 of building, accomplish supplementary building to 5G signal base station, locking device 7 provides the function of locking to lifting device 6, thereby prevent building toppling over of device 5, digging device 9 has the function of digging pit, furtherly, digging device 9 has the soil after will digging pit, stay at the function of digging device 9, thereby improving the device and building device 5 after having installed, pour out the earth in digging device 9 fast, tamp building device 5 fast.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 9, and the embodiment further describes the first embodiment, where the bearing device 1 includes a bearing plate 1-1, a chute column 1-2 and a sliding strip 1-3, the upper part of the bearing plate 1-1 is fixedly connected with the chute column 1-2, and the front and rear ends of the upper part of the bearing plate 1-1 are symmetrically and fixedly connected with the sliding strip 1-3; the bearing plate 1-1 is placed at a position where a 5G signal base station needs to be installed, so that the building column can conveniently penetrate into the ground from a round hole in the bearing plate 1-1, installation operation is carried out, the design of the sliding groove column 1-2 provides a supporting effect for the extension device 3, further, a sliding space is provided for the extension device 3, and further, the gravity center of the device can be conveniently adjusted.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 9, and the second embodiment is further described in the present embodiment, where the driving device 2 includes a driving motor 2-1 and a gear i 2-2, the gear i 2-2 is fixedly connected to an output shaft of the driving motor 2-1, and the driving motor 2-1 is fixedly connected to the chute column 1-2; the driving motor 2-1 is started to rotate, so that the gear I2-2 can rotate by taking the axis of the gear I2-2 as the shaft, the stretching device 3 can be conveniently driven to slide on the sliding groove column 1-2, the gravity center position of the adjusting device can be conveniently realized, and the device can be transported and used conveniently finally.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1-9, the extension device 3 includes a cross frame 3-1, a tooth groove 3-2, a sliding groove 3-3, a hinge seat 3-4, a hinge plate 3-5, a limiting block 3-6 and an L-shaped hole frame 3-7, the tooth groove 3-2 is arranged at the lower part of the cross frame 3-1, the sliding groove 3-3 is arranged at the upper part of the cross frame 3-1, the hinge seat 3-4 is fixedly connected to the cross frame 3-1, the hinge plate 3-5 is hinged to the hinge seat 3-4, the limiting blocks 3-6 are fixedly connected to the front and rear ends of the hinge plate 3-5, the two limiting blocks 3-6 are matched with the hinge seat 3-4, the L-shaped hole frames 3-7 are symmetrically and fixedly connected to the front and rear ends of the hinge plate 3-5, the lower part of the transverse frame 3-1 is connected with a sliding groove column 1-2 in a sliding mode, a tooth groove 3-2 is in transmission connection with a gear I2-2, and a plurality of binding columns I are symmetrically and fixedly connected to the front end and the rear end of the transverse frame 3-1; the driving motor 2-1 is started to rotate, so that the gear I2-2 can rotate by taking the axis of the gear I2-2 as a shaft, and then the transverse frame 3-1 is driven to slide on the chute column 1-2, the gravity center position of the device is adjusted, and the device is convenient to transport and use; when the building device 5 is transported, the rope can bypass the binding columns I, so that the building device 5 can be firmly fixed on the transverse frame 3-1, the building device 5 is prevented from falling off in the transportation process, and when the hinged plate 3-5 rotates by taking the axis of the pin shaft at the position of the hinged seat 3-4 as the shaft, the building device 5 can be turned over, so that the building device 5 is convenient to install; the limiting blocks 3-6 play a limiting role.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1-9, wherein the clamping device 4 includes a clamping block 4-1, a moving frame 4-2 and an electric push rod i 4-3, the clamping block 4-1 is fixedly connected with the moving frame 4-2, the moving frame 4-2 is fixedly connected with the electric push rod i 4-3, the movable end of the electric push rod i 4-3 is fixedly connected with an L-shaped hole frame 3-7, the moving frame 4-2 is slidably connected with the L-shaped hole frame 3-7, two clamping devices 4 are provided, and the two clamping devices 4 are symmetrically installed; the movable frame 4-2 can slide on the L-shaped hole frame 3-7 by starting the electric push rod I4-3 to stretch out and draw back, so that the two clamping blocks 4-1 are driven to lock the building device 5 and the hinged plate 3-5, the device is convenient to install a signal column, and when the signal column is installed, the two clamping blocks 4-1 are loosened after the signal column is erected, so that the signal column is pricked into the ground, and the convenience in carrying the signal column is improved.

The sixth specific implementation mode:

the embodiment is described below by combining fig. 1-9, and the fifth embodiment is further described by the embodiment, wherein the building device 5 comprises a building column 5-1, a knocking seat 5-2 and sliding plates I5-3, a plurality of building connection blocks are mounted on the building column 5-1 and connected with a signal mechanism, the knocking seat 5-2 is connected with the building column 5-1 in a sliding manner, the knocking seat 5-2 is fixedly connected with a plurality of sliding plates I5-3, the plurality of sliding plates I5-3 are locked with the building column 5-1 through studs, the building column 5-1 is matched with the two clamping blocks 4-1, and the side part of the building column 5-1 is connected with the plurality of binding columns I through ropes; after the building column 5-1 is clamped by the two clamping blocks 4-1, the building column 5-1 is erected, the two clamping blocks 4-1 are loosened after the building column 5-1 is aligned with the installation position, the building column 5-1 is tied on the ground, in this way, the building column 5-1 is convenient to carry and move, the studs on the sliding plates I5-3 are adjusted at the moment, the knocking seat 5-2 slides on the building column 5-1, then the studs are locked, the building column 5-1 can be knocked into the deep ground by knocking the knocking seat 5-2 at the moment, the building column 5-1 is convenient to install, further, the knocking seat 5-2 has a certain width, and the stabilizing effect of the building column 5-1 in the using process can be improved.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 9, and the embodiment further describes a sixth embodiment, where the lifting device 6 includes a carriage 6-1, a spring plate 6-2, an upper frame 6-3, a vertical column 6-4, a rack 6-5, a rotating frame 6-6 and a lifting attachment plate 6-7, the carriage 6-1 is fixedly connected with the spring plate 6-2, the upper frame 6-3 is fixedly connected with the vertical column 6-4, the vertical column 6-4 is fixedly connected with the rack 6-5, the upper frame 6-3 is hinged with the rotating frame 6-6, the upper frame 6-3 is fixedly connected with the lifting attachment plate 6-7, the lifting attachment plate 6-7 is provided with an arc attachment groove, the arc attachment groove is matched with the construction column 5-1, the vertical column 6-4 is slidably connected with the carriage 6-1, the rotating frame 6-6 is in threaded transmission connection with the sliding frame 6-1, the front end and the rear end of the upper frame 6-3 are symmetrically and fixedly connected with binding posts II, the side part of the building post 5-1 is connected with the two binding posts II through a rope, the sliding frame 6-1 is in sliding connection with the sliding groove 3-3, and the sliding frame 6-1 is fixedly connected with a moving handle; the vertical column 6-4 can slide on the sliding frame 6-1 by rotating the rotating frame 6-6 by taking the axis of the rotating frame as a shaft, so that the lifting attaching plate 6-7 is driven to lift and turn over the construction column 5-1, and the moving handle is pulled at the moment to slide the sliding frame 6-1 on the sliding groove 3-3, so that the turning angle of the construction column 5-1 is increased; the design of the arc fitting groove can enable the building column 5-1 to be completely erected, and at the moment, the two limiting blocks 3-6 are matched with the hinge seats 3-4; and a rope is wound between the side part of the building column 5-1 and the two binding columns II, so that the building column 5-1 is prevented from rotating greatly to cause damage to devices and personnel.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1 to 9, and the seventh embodiment is further described in the embodiment, where the locking device 7 includes a slider 7-1 and a ratchet 7-2, the slider 7-1 is slidably connected to the carriage 6-1, a spring is sleeved between the slider 7-1 and the spring plate 6-2, the slider 7-1 is hinged to the ratchet 7-2, and the ratchet 7-2 is in transmission connection with the rack 6-5; under the action of the spring, the ratchet wheel 7-2 can be always meshed with the rack 6-5, and the ratchet wheel 7-2 rotates in a single direction, so that the effect of preventing the building column 5-1 from toppling over is achieved.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1-9, and the eighth embodiment is further described, wherein the lifting device 8 comprises a sliding plate ii 8-1, a connecting frame 8-2, a lifting plate 8-3, an electric push rod ii 8-4 and a pit digging motor 8-5, the connecting frame 8-2 is symmetrically and fixedly connected to the sliding plate ii 8-1, the electric push rod ii 8-4 is fixedly connected to the lifting plate 8-3, the movable end of the electric push rod ii 8-4 is fixedly connected to the upper portion of the sliding plate ii 8-1, the sliding plate ii 8-1 is slidably connected to the lifting plate 8-3, the pit digging motor 8-5 is fixedly connected to the lifting plate 8-3, a gear ii is fixedly connected to the output shaft of the pit digging motor 8-5, the front end and the rear end of the hinge base 3-4 are respectively and fixedly connected to the two connecting frames 8-2, the sliding plate II 8-1 is in sliding connection with the two sliding strips 1-3; when the hinged seat 3-4 is moved, the sliding plate II 8-1 can be driven to slide on the two sliding strips 1-3, so that the pit digging device 9 can be conveniently dug, and after the pit digging is completed, the building column 5-1 is turned over, so that the mounting operation of the building column 5-1 is carried out.

The detailed implementation mode is ten:

the embodiment is described below with reference to fig. 1-9, and the ninth embodiment is further described, wherein the pit digging device 9 comprises a pit digging cylinder 9-1, a soil inlet 9-2 and a gear ring 9-3, a conical pipe is mounted at the lower part of the pit digging cylinder 9-1, the soil inlet 9-2 is arranged on the conical pipe, the gear ring 9-3 is fixedly connected to the side part of the pit digging cylinder 9-1, the gear ring 9-3 is in transmission connection with a gear II, the pit digging cylinder 9-1 is in hinged connection with a lifting plate 8-3, the lower part of the conical pipe is matched with a sliding plate II 8-1, and the lower part of the conical pipe is matched with a bearing plate 1-1; the digging motor 8-5 is started to rotate, the gear ring 9-3 can rotate by taking the axis of the gear ring as the shaft, the digging barrel 9-1 rotates by taking the axis of the digging barrel as the shaft, the soil inlet 9-2 on the conical pipe continuously digs soil, the electric push rod II 8-4 is started to stretch and retract at the moment, the conical pipe can be matched with the digging barrel 9-1 to dig the pit, the lifting plate 8-3 slides on the sliding plate II 8-1 at the moment, further, after the pit is dug by the conical pipe, the soil can be left in the digging barrel 9-1, so that after the building column 5-1 is installed, the conical pipe is taken down, the soil in the digging barrel 9-1 is quickly poured out, the bottom surface of the building column 5-1 is quickly tamped conveniently, and further, the hinged base 3-4 and the two connecting frames 8-2 are fixed together, the device can simultaneously switch the positions of the construction column 5-1 and the pit digging cylinder 9-1, thereby facilitating the operation of installing and tamping the construction column 5-1.

The invention relates to a working principle of a 5G signal base station auxiliary building system, which comprises the following steps:

the bearing plate 1-1 is placed at a position where a 5G signal base station needs to be installed, so that a building column can be conveniently inserted into the ground from a round hole on the bearing plate 1-1, installation operation is carried out, the design of the chute column 1-2 provides a supporting effect for the extension device 3, further provides a sliding space for the extension device 3, and further facilitates adjustment of the gravity center of the device; the driving motor 2-1 is started to rotate, so that the gear I2-2 can rotate by taking the axis of the gear I2-2 as a shaft, the extending device 3 is conveniently driven to slide on the chute column 1-2, the gravity center position of the device is conveniently adjusted, and finally the device is convenient to transport and use; the driving motor 2-1 is started to rotate, so that the gear I2-2 can rotate by taking the axis of the gear I2-2 as a shaft, and then the transverse frame 3-1 is driven to slide on the chute column 1-2, the gravity center position of the device is adjusted, and the device is convenient to transport and use; when the building device 5 is transported, the rope can bypass the binding columns I, so that the building device 5 can be firmly fixed on the transverse frame 3-1, the building device 5 is prevented from falling off in the transportation process, and when the hinged plate 3-5 rotates by taking the axis of the pin shaft at the position of the hinged seat 3-4 as the shaft, the building device 5 can be turned over, so that the building device 5 is convenient to install; the limiting blocks 3-6 play a limiting role; the electric push rod I4-3 is started to stretch, so that the movable frame 4-2 can slide on the L-shaped hole frame 3-7, the two clamping blocks 4-1 are driven to lock the building device 5 and the hinged plate 3-5, the signal column can be conveniently installed by the device, when the signal column is installed, the two clamping blocks 4-1 are loosened after the signal column is erected, the signal column is inserted into the ground, and the convenience in carrying the signal column is improved; after the building column 5-1 is clamped by the two clamping blocks 4-1, the building column 5-1 is erected, the two clamping blocks 4-1 are loosened after the building column 5-1 is aligned with the installation position, the building column 5-1 is tied on the ground, in this way, the building column 5-1 is convenient to carry and move, the studs on the sliding plates I5-3 are adjusted at the moment, the knocking seat 5-2 slides on the building column 5-1, then the studs are locked, the building column 5-1 can be knocked into the deep ground by knocking the knocking seat 5-2 at the moment, the building column 5-1 is convenient to install, further, the knocking seat 5-2 has a certain width, and the stabilizing effect of the building column 5-1 in the using process can be improved; the vertical column 6-4 can slide on the sliding frame 6-1 by rotating the rotating frame 6-6 by taking the axis of the rotating frame as a shaft, so that the lifting attaching plate 6-7 is driven to lift and turn over the construction column 5-1, and the moving handle is pulled at the moment to slide the sliding frame 6-1 on the sliding groove 3-3, so that the turning angle of the construction column 5-1 is increased; the design of the arc fitting groove can enable the building column 5-1 to be completely erected, and at the moment, the two limiting blocks 3-6 are matched with the hinge seats 3-4; a rope is wound between the side part of the building column 5-1 and the two binding columns II, so that the building column 5-1 is prevented from rotating greatly to cause damage to devices and personnel; under the action of the spring, the ratchet wheel 7-2 can be always meshed with the rack 6-5, and the ratchet wheel 7-2 rotates in a single direction to prevent the building column 5-1 from toppling; when the hinged seat 3-4 is moved, the sliding plate II 8-1 can be driven to slide on the two sliding strips 1-3, so that the pit digging device 9 can be conveniently dug, and after the pit digging is completed, the building column 5-1 is turned over, so that the mounting operation of the building column 5-1 is carried out; the digging motor 8-5 is started to rotate, the gear ring 9-3 can rotate by taking the axis of the gear ring as the shaft, the digging barrel 9-1 rotates by taking the axis of the digging barrel as the shaft, the soil inlet 9-2 on the conical pipe continuously digs soil, the electric push rod II 8-4 is started to stretch and retract at the moment, the conical pipe can be matched with the digging barrel 9-1 to dig the pit, the lifting plate 8-3 slides on the sliding plate II 8-1 at the moment, further, after the pit is dug by the conical pipe, the soil can be left in the digging barrel 9-1, so that after the building column 5-1 is installed, the conical pipe is taken down, the soil in the digging barrel 9-1 is quickly poured out, the bottom surface of the building column 5-1 is quickly tamped conveniently, and further, the hinged base 3-4 and the two connecting frames 8-2 are fixed together, the device can simultaneously switch the positions of the construction column 5-1 and the pit digging cylinder 9-1, thereby facilitating the operation of installing and tamping the construction column 5-1.

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

Claims

1. The utility model provides a supplementary system of building of 5G signal base station, includes and bears device (1), drive arrangement (2), stretches out device (3), clamping device (4), builds device (5), lifting device (6), locking device (7), elevating gear (8) and digging device (9), its characterized in that: fixedly connected with drive arrangement (2) on bearing device (1), stretch out device (3) sliding connection on bearing device (1), stretch out device (3) and be connected with drive arrangement (2) transmission, both ends symmetric connection has clamping device (4) around stretching out device (3), it is connected with two clamping device (4) to build device (5), it is connected with lifting device (6) to build device (5), lifting device (6) and stretching out device (3) sliding connection, lifting device (6) are connected with locking device (7), elevating gear (8) and bearing device (1) sliding connection, elevating gear (8) and stretching out device (3) fixed connection, elevating gear (8) are connected with digging device (9).

2. The 5G signal base station assisted building system according to claim 1, wherein: the bearing device (1) comprises a bearing plate (1-1), chute columns (1-2) and sliding strips (1-3), wherein the chute columns (1-2) are fixedly connected to the upper portion of the bearing plate (1-1), and the sliding strips (1-3) are symmetrically and fixedly connected to the front end and the rear end of the upper portion of the bearing plate (1-1).

3. The 5G signal base station assisted construction system according to claim 2, wherein: the driving device (2) comprises a driving motor (2-1) and a gear I (2-2), the gear I (2-2) is fixedly connected to an output shaft of the driving motor (2-1), and the driving motor (2-1) is fixedly connected with the chute column (1-2).

4. The 5G signal base station assisted building system according to claim 3, wherein: the extension device (3) comprises a transverse frame (3-1), tooth grooves (3-2), sliding grooves (3-3), hinge seats (3-4), hinged plates (3-5), limiting blocks (3-6) and L-shaped hole frames (3-7), the tooth grooves (3-2) are arranged on the lower portion of the transverse frame (3-1), the sliding grooves (3-3) are arranged on the upper portion of the transverse frame (3-1), the hinge seats (3-4) are fixedly connected to the transverse frame (3-1), the hinged plates (3-5) are hinged to the hinge seats (3-4), the limiting blocks (3-6) are fixedly connected to the front end and the rear end of the hinged plates (3-5), the two limiting blocks (3-6) are matched with the hinge seats (3-4), the L-shaped hole frames (3-7) are symmetrically and fixedly connected to the front end and the rear end of the hinged plates (3-5), the lower part of the transverse frame (3-1) is connected with the sliding groove columns (1-2) in a sliding mode, the tooth grooves (3-2) are connected with the gear I (2-2) in a transmission mode, and the front end and the rear end of the transverse frame (3-1) are symmetrically and fixedly connected with the binding columns I.

5. The 5G signal base station assisted construction system according to claim 4, characterized in that: clamping device (4) including pressing from both sides tight piece (4-1), remove frame (4-2) and electric putter I (4-3), press from both sides fixedly connected with on tight piece (4-1) and remove frame (4-2), remove fixedly connected with electric putter I (4-3) on frame (4-2), the expansion end and L type hole frame (3-7) fixed connection of electric putter I (4-3), remove frame (4-2) and L type hole frame (3-7) sliding connection, clamping device (4) be provided with two, two clamping device (4) symmetry installation.

6. The 5G signal base station assisted building system according to claim 5, wherein: the building device (5) comprises a building column (5-1), a knocking seat (5-2) and sliding plates I (5-3), a plurality of building connecting blocks are installed on the building column (5-1) and connected with a signal mechanism, the knocking seat (5-2) is in sliding connection with the building column (5-1), a plurality of sliding plates I (5-3) are fixedly connected to the knocking seat (5-2), the sliding plates I (5-3) are locked with the building column (5-1) through studs, the building column (5-1) is matched with two clamping blocks (4-1), and the side portion of the building column (5-1) is connected with the binding columns I through ropes.

7. The 5G signal base station assisted construction system according to claim 6, characterized in that: the lifting device (6) comprises a sliding frame (6-1), a spring plate (6-2), an upper frame (6-3), vertical columns (6-4), racks (6-5), a rotating frame (6-6) and lifting attaching plates (6-7), wherein the spring plate (6-2) is fixedly connected to the sliding frame (6-1), the vertical columns (6-4) are fixedly connected to the upper frame (6-3), the racks (6-5) are fixedly connected to the vertical columns (6-4), the rotating frame (6-6) is hinged to the upper frame (6-3), the lifting attaching plates (6-7) are fixedly connected to the upper frame (6-3), arc attaching grooves are formed in the lifting attaching plates (6-7) and are matched with the building columns (5-1), the upright post (6-4) is connected with the sliding frame (6-1) in a sliding manner, the rotating frame (6-6) is connected with the sliding frame (6-1) in a threaded transmission manner, the front end and the rear end of the upper frame (6-3) are symmetrically and fixedly connected with the binding posts II, the side part of the building post (5-1) is connected with the two binding posts II through a rope, the sliding frame (6-1) is connected with the sliding groove (3-3) in a sliding manner, and the sliding frame (6-1) is fixedly connected with a moving handle.

8. The 5G signal base station assisted construction system according to claim 7, wherein: the locking device (7) comprises a sliding block (7-1) and a ratchet wheel (7-2), the sliding block (7-1) is connected to the sliding frame (6-1) in a sliding mode, a spring is sleeved between the sliding block (7-1) and the spring plate (6-2), the ratchet wheel (7-2) is connected to the sliding block (7-1) in a hinged mode, and the ratchet wheel (7-2) is in transmission connection with the rack (6-5).

9. The 5G signal base station assisted construction system according to claim 8, wherein: the lifting device (8) comprises a sliding plate II (8-1), a connecting frame (8-2), a lifting plate (8-3), an electric push rod II (8-4) and a pit digging motor (8-5), the sliding plate II (8-1) is symmetrically and fixedly connected with the connecting frame (8-2), the lifting plate (8-3) is fixedly connected with the electric push rod II (8-4), the movable end of the electric push rod II (8-4) is fixedly connected with the upper part of the sliding plate II (8-1), the sliding plate II (8-1) is slidably connected with the lifting plate (8-3), the lifting plate (8-3) is fixedly connected with the pit digging motor (8-5), the output shaft of the pit digging motor (8-5) is fixedly connected with a gear II, the front end and the rear end of a seat (3-4) are respectively and fixedly connected with the two connecting frames (8-2), the sliding plate II (8-1) is connected with the two sliding strips (1-3) in a sliding manner.

10. The 5G signal base station assisted construction system according to claim 9, wherein: the pit digging device (9) comprises a pit digging cylinder (9-1), a soil inlet (9-2) and a gear ring (9-3), wherein a conical pipe is installed on the lower portion of the pit digging cylinder (9-1), the soil inlet (9-2) is formed in the conical pipe, the gear ring (9-3) is fixedly connected to the side portion of the pit digging cylinder (9-1), the gear ring (9-3) is in transmission connection with a gear II, the pit digging cylinder (9-1) is hinged to a lifting plate (8-3), the lower portion of the conical pipe is matched with a sliding plate II (8-1), and the lower portion of the conical pipe is matched with a bearing plate (1-1).