CN109798014B - Small-size adjustable 5G signal reinforcing tower - Google Patents

Abstract

The invention relates to a signal tower, in particular to a small-sized adjustable 5G signal enhancement tower, which comprises a support frame, an adjusting mechanism I, an adjusting frame, an adjusting mechanism II, a bottom support, a mounting support and a top support, wherein the support frame is connected with the adjusting mechanism I; the inclined supporting angle of the upper end of the bottom support is adjusted through the adjusting mechanism I, the inclined supporting angle of the middle end of the bottom support is adjusted through the adjusting mechanism II, mutual linkage between the adjusting mechanism I and the adjusting mechanism II is achieved through a linkage column, a linkage plate, a limiting column and an inserting shaft which are arranged on the adjusting mechanism I, and the mounting area and the supporting angle of the bottom support are adjusted according to different mounting and using requirements.

Description

Small-size adjustable 5G signal reinforcing tower

Technical Field

The invention relates to a signal tower, in particular to a small adjustable 5G signal enhancement tower.

Background

For example, a large signal tower with lightning protection equipment disclosed in publication No. CN205531599U comprises a signal tower column and a lightning protection equipment main body, wherein cross rods are respectively installed at two ends of the middle upper part of the signal tower column, a signal plate is installed at the top end of each cross rod, a first down lead is installed at the left end inside the signal tower column, a high-insulation anti-interference plate is installed at the right end of the first down lead, a second down lead is installed at the right end of the high-insulation anti-interference plate, a safety detector is installed at the left lower end of the signal tower column, a fixed base is installed at the lower end of the signal tower column, a lightning diversion terminal is installed at the middle end of a ground grid, tower plate protective sleeves are installed on the left and right outer surfaces of; the utility model discloses a shortcoming is that can not be according to the installation area of the installation user demand adjustment bottom support of difference.

Disclosure of Invention

The invention aims to provide a small adjustable 5G signal enhancement tower, which can adjust the installation area of a bottom bracket according to different installation and use requirements.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a small-size adjustable 5G signal enhancement tower, includes support frame, guiding mechanism I, alignment jig, guiding mechanism II, bottom support, installing support and top support, be connected with guiding mechanism I on the support frame, the lower extreme fixedly connected with alignment jig of support frame is connected with guiding mechanism II on the alignment jig, and the inclination of bottom support upper end is adjusted to guiding mechanism I, and the inclination of bottom support middle-end is adjusted to guiding mechanism II, installs a plurality of installing supports on the support frame, installs the top support on the installing support.

As a further optimization of the technical scheme, the small-sized adjustable 5G signal enhancement tower comprises a cross support frame I, a support rod II, a connecting frame, a limiting baffle I, a T-shaped groove I, a connecting rod, an installation spigot I and a connecting block I, wherein the four support rods I are fixedly connected to the cross support frame I, the upper ends of the four support rods I are fixedly connected to the connecting frame, the support rods II are fixedly connected to the four corners of the cross support frame I, the upper ends of the four support rods II are fixedly connected to the connecting frame, the limiting baffle I is fixedly connected to the four corners of the cross support frame I, the T-shaped groove I is arranged on each of the four edges of the cross support frame I, the connecting rod is fixedly connected to the four corners of the lower end of the cross support frame I, the four sliding holes are arranged on the cross support frame I, the, all be provided with installation tang I on four angles of linking frame.

As a further optimization of the technical scheme, the small-sized adjustable 5G signal enhancement tower comprises an adjusting screw rod I, an adjusting handle I, a pushing thread block I, a pushing connecting rod I, T-shaped sliding rails I, linkage columns, linkage plates, limiting columns and an inserting shaft, wherein the lower end of the adjusting screw rod I is rotatably connected to the center of a cross-shaped support frame I, the upper end of the adjusting screw rod I is fixedly connected with the adjusting handle I, the pushing thread block I is connected to the adjusting screw rod I through threads, the pushing thread block I is hinged with four pushing connecting rods I, the lower ends of the four pushing connecting rods I are hinged with the T-shaped sliding rails I, the four T-shaped sliding rails I are respectively and slidably connected into four T-shaped grooves I, the linkage columns are slidably connected to the adjusting screw rod I, the lower ends of the linkage columns are fixedly connected with the linkage plates, and the upper ends of the linkage plates are, four spacing posts are respectively in four sliding holes that sliding connection set up on cross support frame I, and four insertion shafts of the lower extreme fixedly connected with of linkage plate all overlap on four spacing posts and are equipped with compression spring, and compression spring is located between cross support frame I and the linkage plate.

As further optimization of the technical scheme, the small adjustable 5G signal enhancement tower comprises an adjusting frame, wherein the adjusting frame comprises a cross support frame II, a limiting baffle II, a T-shaped groove II and support ribs I, four corners of the cross support frame II are respectively and fixedly connected to the lower ends of four connecting rods, the support ribs I are fixedly connected among four edges of the cross support frame II, the limiting baffle II is fixedly connected to the four corners of the cross support frame II, and the T-shaped grooves II are arranged on the four edges of the cross support frame II.

As a further optimization of the technical scheme, the small adjustable 5G signal enhancement tower comprises an adjusting screw rod II, an adjusting handle II, a plug port, a pushing thread block II, a pushing connecting rod II and a T-shaped sliding rail II, wherein the lower end of the adjusting screw rod II is rotatably connected to a cross-shaped support frame II, the upper end of the adjusting screw rod II is fixedly connected with the adjusting handle II, four plug ports are formed in the adjusting handle II, four limiting columns are respectively and slidably connected into the four plug ports, the pushing thread block II is connected to the adjusting screw rod II through threads, four pushing connecting rods II are hinged to the pushing thread block II, the lower ends of the four pushing connecting rods II are respectively hinged to the T-shaped sliding rail II, and the four T-shaped sliding rails II are respectively and slidably connected into the four T-shaped grooves II.

According to the technical scheme, the small adjustable 5G signal enhancement tower comprises a bottom support rod, a sliding waist hole, a hinge block I, a hinge block II, a pre-embedded plate, four ground bolts and nuts, wherein the sliding waist hole is formed in the bottom support rod, the hinge block I is fixedly connected to the bottom support rod, the hinge block II is connected in the sliding waist hole in a sliding mode, the pre-embedded plate is hinged to the lower end of the bottom support rod, the four ground bolts are installed on the pre-embedded plate and are all connected with the nuts through threads, the four hinge blocks I are respectively hinged to the outer ends of the four T-shaped slide rails I, and the four hinge blocks II are respectively hinged to the outer ends of the four T-shaped slide rails II.

As a further optimization of the technical scheme, the invention relates to a small-sized adjustable 5G signal enhancement tower, which comprises an installation bottom frame, a support rib II, a connecting block II, a positioning boss I, a support rod III, a support rib III, an installation top frame, a support rib IV, an installation seam allowance II and a connecting block III, wherein the installation bottom frame is fixedly connected with the support rib II, the installation bottom frame is fixedly connected with four connecting blocks II, the lower end of the installation bottom frame is fixedly connected with four positioning bosses I, four support rods III and four support ribs III are fixedly connected between the installation bottom frame and the installation top frame, the installation top frame is fixedly connected with the support rib IV, the installation top frame is fixedly connected with four connecting blocks III, the installation top frame is provided with four installation seam allowances II, the four positioning bosses I are respectively installed in the four installation seam allowances I, and the four connecting blocks I are respectively fixedly connected with the four connecting blocks II through bolts, the installing support is provided with a plurality ofly, and four location bosss I that set up on the installing support that is located the upper end are installed respectively in four installation tang II that set up on the installing support that is located the lower extreme, and four connecting blocks II that set up on the installing support that is located the upper end are respectively through four connecting block III fixed connection that the bolt set up on the installing support that is located the lower extreme.

As a further optimization of the technical scheme, the top support comprises a top bottom frame, a support rib v, a connecting block iv, a support rod iv, a signal enhancer and a positioning boss ii, the top bottom frame is fixedly connected with the support rib v, the upper end of the top bottom frame is fixedly connected with four support ribs v, the four support ribs v are all fixedly connected to the signal enhancer, the lower end of the top bottom frame is fixedly connected with four positioning bosses ii, the top bottom frame is fixedly connected with four connecting blocks iv, the four positioning bosses ii arranged on the top support are respectively arranged in four mounting spigots ii arranged on the mounting support positioned at the uppermost end, and the four connecting blocks iv arranged on the top support are respectively fixedly connected with the corresponding four connecting blocks iii through bolts.

The small adjustable 5G signal enhancement tower has the beneficial effects that:

according to the small adjustable 5G signal enhancement tower, the inclined support angle at the upper end of the bottom support can be adjusted through the adjusting mechanism I, the inclined support angle at the middle end of the bottom support is adjusted through the adjusting mechanism II, mutual linkage between the adjusting mechanism I and the adjusting mechanism II is realized through the linkage column, the linkage plate, the limiting column and the inserting shaft which are arranged on the adjusting mechanism I, and the mounting area and the support angle of the bottom support are adjusted according to different mounting and using requirements; can accomplish the quick installation between individual installing support through connecting block II, location boss I, installation tang II and the connecting block III that sets up on the installing support, make things convenient for adjusting device's height.

Drawings

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

FIG. 1 is a schematic diagram of the overall structure of a small adjustable 5G signal enhancement tower of the present invention;

FIG. 2 is a schematic diagram of a partial structure of a small adjustable 5G signal enhancement tower according to the present invention;

FIG. 3 is a schematic view of the support frame structure of the present invention;

FIG. 4 is a schematic view of the adjusting mechanism I of the present invention;

FIG. 5 is a schematic cross-sectional view of an adjustment mechanism I of the present invention;

FIG. 6 is a schematic view of the structure of the adjusting bracket of the present invention;

FIG. 7 is a schematic structural diagram of an adjusting mechanism II of the present invention;

FIG. 8 is a schematic view of the bottom bracket configuration of the present invention;

FIG. 9 is a first schematic view of the mounting bracket of the present invention;

FIG. 10 is a second schematic view of the mounting bracket configuration of the present invention;

FIG. 11 is a first schematic view of the top mount configuration of the present invention;

FIG. 12 is a second schematic view of the top bracket structure of the present invention.

In the figure: a support frame 1; 1-1 of a cross support frame; 1-2 of a support rod; 1-3 of a support rod II; connecting frames 1-4; 1-5 of a limiting baffle; t-shaped grooves I1-6; connecting rods 1-7; installing a spigot I1-8; 1-9 parts of a connecting block I; an adjusting mechanism I2; adjusting a screw rod I2-1; adjusting a handle I2-2; pushing the thread block I2-3; pushing a connecting rod I2-4; t-shaped sliding rails I2-5; 2-6 of a linkage column; 2-7 of a linkage plate; 2-8 parts of a limiting column; 2-9 of an inserting shaft; an adjusting frame 3; a cross support II 3-1; a limiting baffle II 3-2; a T-shaped groove II 3-3; 3-4 of support ribs; an adjusting mechanism II 4; adjusting a screw rod II 4-1; adjusting a handle II 4-2; 4-3 of a socket; pushing the thread block II 4-4; pushing a connecting rod II 4-5; a T-shaped sliding rail II 4-6; a bottom bracket 5; a bottom support bar 5-1; 5-2 of a sliding waist hole; the hinge blocks I5-3; the hinge blocks II 5-4; 5-5 of a pre-buried plate; 5-6 parts of foundation bolts; 5-7 parts of a nut; a mounting bracket 6; installing a bottom frame 6-1; support ribs II 6-2; 6-3 of a connecting block II; 6-4 of a positioning boss; 6-5 parts of a support rod III; 6-6 of support ribs III; installing a top frame 6-7; 6-8 of support ribs; installing a spigot II 6-9; 6-10 parts of a connecting block III; a top bracket 7; a top bottom frame 7-1; a support rib V7-2; 7-3 of a connecting block IV; 7-4 parts of a support rod IV; a signal booster 7-5; and positioning bosses II 7-6.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Before describing the embodiments, to avoid repetitive language, it is explained that the "fixed connection" described below may be: the fixing device is fixed through modes such as bolt connection, welding and rivet connection, and technicians in the field can select different fixing and connecting modes according to different application scenes, and the fixing device is mainly used for fixing two parts.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, and a small-sized adjustable 5G signal enhancement tower comprises a support frame 1, an adjusting mechanism i 2, an adjusting frame 3, an adjusting mechanism ii 4, a bottom bracket 5, a mounting bracket 6 and a top bracket 7, wherein the adjusting mechanism i 2 is connected to the support frame 1, the adjusting frame 3 is fixedly connected to the lower end of the support frame 1, the adjusting mechanism ii 4 is connected to the adjusting frame 3, the adjusting mechanism i 2 adjusts the inclination angle of the upper end of the bottom bracket 5, the adjusting mechanism ii 4 adjusts the inclination angle of the middle end of the bottom bracket 5, a plurality of mounting brackets 6 are mounted on the support frame 1, and the top bracket 7 is mounted on the mounting brackets 6; the inclined supporting angle of the upper end of the bottom support 5 can be adjusted through the adjusting mechanism I2, the inclined supporting angle of the middle end of the bottom support 5 can be adjusted through the adjusting mechanism II 4, mutual linkage between the adjusting mechanism I2 and the adjusting mechanism II 4 is achieved through linkage columns 2-6, linkage plates 2-7, limiting columns 2-8 and inserting shafts 2-9 arranged on the adjusting mechanism I2, and the mounting area and the supporting angle of the bottom support 5 are adjusted according to different mounting and using requirements; the quick installation of the installation supports 6 can be completed through the connecting blocks II 6-3, the positioning bosses I6-4, the installation rabbets II 6-9 and the connecting blocks III 6-10 arranged on the installation supports 6, and the height of the device can be conveniently adjusted.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-12, and the embodiment will be further described, wherein the support frame 1 comprises a cross support frame i 1-1, support rods i 1-2, support rods ii 1-3, a connecting frame 1-4, limit baffles i 1-5, T-shaped grooves i 1-6, connecting rods 1-7, mounting spigots i 1-8 and connecting blocks i 1-9, four support rods i 1-2 are fixedly connected to the cross support frame i 1-1, the upper ends of the four support rods i 1-2 are fixedly connected to the connecting frame 1-4, the four corners of the cross support frame i 1-1 are fixedly connected to the support rods ii 1-3, the upper ends of the four support rods ii 1-3 are fixedly connected to the connecting frame 1-4, equal fixedly connected with limit baffle I1-5 on four angles of cross support frame I1-1, four edges of cross support frame I1-1 all are provided with T-slot I1-6, equal fixedly connected with connecting rod 1-7 on four angles of cross support frame I1-1 lower extreme, be provided with four sliding holes on cross support frame I1-1, equal fixedly connected with connecting block I1-9 on four edges of connecting frame 1-4, all be provided with installation tang I1-8 on four angles of connecting frame 1-4.

The third concrete implementation mode:

the second embodiment is further described with reference to fig. 1-12, wherein the adjusting mechanism i 2 includes an adjusting screw rod i 2-1, an adjusting handle i 2-2, a pushing screw block i 2-3, a pushing connecting rod i 2-4, a T-shaped sliding rail i 2-5, a linkage column 2-6, a linkage plate 2-7, a limiting column 2-8 and an inserting shaft 2-9, the lower end of the adjusting screw rod i 2-1 is rotatably connected to the center of the cross-shaped support frame i 1-1, the upper end of the adjusting screw rod i 2-1 is fixedly connected with the adjusting handle i 2-2, the adjusting screw rod i 2-1 is connected with the pushing screw block i 2-3 through a screw thread, the pushing screw block i 2-3 is hinged with four pushing connecting rods i 2-4, the lower ends of four pushing connecting rods I2-4 are hinged with T-shaped sliding rails I2-5, the four T-shaped sliding rails I2-5 are respectively and slidably connected into four T-shaped grooves I1-6, the adjusting screw I2-1 is slidably connected with linkage columns 2-6, the lower ends of the linkage columns 2-6 are fixedly connected with linkage plates 2-7, the upper ends of the linkage plates 2-7 are fixedly connected with four limiting columns 2-8, the four limiting columns 2-8 are respectively and slidably connected into four sliding holes formed in a cross supporting frame I1-1, the lower ends of the linkage plates 2-7 are fixedly connected with four insertion shafts 2-9, compression springs are sleeved on the four limiting columns 2-8, and the compression springs are located between the supporting frame I1-1 and the linkage plates 2-7; when the floor area of the device needs to be adjusted according to different use requirements, the adjusting handle I2-2 is manually rotated to enable the adjusting handle I2-2 to rotate by taking the axis of the adjusting handle I2-2 as the center, the adjusting handle I2-2 drives the adjusting screw rod I2-1 to rotate by taking the axis of the adjusting screw rod I2-1 as the center, the adjusting screw rod I2-1 drives the pushing screw block I2-3 to move in the axis direction of the adjusting screw rod I2-1 through threads, the screw block I2-3 moves downwards to push the inner sides of the four pushing connecting rods I2-4 to move downwards, the outer sides of the four pushing connecting rods I2-4 are mutually far away, the four pushing connecting rods I2-4 respectively push the four hinging blocks I5-3 to be mutually far away, the position of the bottom supporting rod 5-1 is adjusted, and the four inserting shafts 2-9 are respectively inserted into the four The adjusting screw rod I2-1 drives the linkage plate 2-7 to rotate by taking the axis of the linkage plate as a center, the linkage plate 2-7 drives the four inserting shafts 2-9 to rotate by taking the axis of the linkage plate 2-7 as a center, the four inserting shafts 2-9 drive the adjusting handle II 4-2 to rotate by taking the axis of the linkage plate as a center, linkage between the adjusting mechanism I2 and the adjusting mechanism II 4 is realized, the linkage column 2-6 is pulled upwards to extrude a compression spring so that the four inserting shafts 2-9 are not respectively inserted into the four inserting ports 4-3, and the adjusting mechanism I2 and the adjusting mechanism II 4 are separated and can be respectively controlled.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1-12, in which the adjusting frame 3 includes a cross support frame ii 3-1, a limit baffle ii 3-2, a T-shaped groove ii 3-3 and a support rib i 3-4, four corners of the cross support frame ii 3-1 are respectively and fixedly connected to lower ends of four connecting rods 1-7, the support ribs i 3-4 are fixedly connected between four sides of the cross support frame ii 3-1, the limit baffle ii 3-2 is fixedly connected to four corners of the cross support frame ii 3-1, and the T-shaped grooves ii 3-3 are respectively disposed on four sides of the cross support frame ii 3-1.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1-12, wherein the adjusting mechanism ii 4 includes an adjusting screw rod ii 4-1, an adjusting handle ii 4-2, a socket 4-3, a pushing screw block ii 4-4, a pushing connecting rod ii 4-5 and a T-shaped sliding rail ii 4-6, the lower end of the adjusting screw rod ii 4-1 is rotatably connected to a cross support frame ii 3-1, the upper end of the adjusting screw rod ii 4-1 is fixedly connected to the adjusting handle ii 4-2, the adjusting handle ii 4-2 is provided with four sockets 4-3, four limiting columns 2-8 are respectively slidably connected to the four sockets 4-3, the adjusting screw rod ii 4-1 is connected to the pushing screw block ii 4-4 through a screw thread, the pushing screw block ii 4-4 is hinged to four pushing connecting rods ii 4-5, the lower ends of the four pushing connecting rods II 4-5 are hinged with T-shaped sliding rails II 4-6, and the four T-shaped sliding rails II 4-6 are respectively connected in the four T-shaped grooves II 3-3 in a sliding manner; when the adjusting handle II 4-2 rotates, the adjusting handle II 4-2 drives the adjusting screw rod II 4-1 to rotate by taking the axis of the adjusting screw rod II 4-1 as the center, the adjusting screw rod II 4-1 drives the pushing screw block II 4-4 to move in the axis direction of the adjusting screw rod II 4-1 through threads, when the pushing screw block II 4-4 moves downwards, the pushing screw block II 4-4 pushes the inner sides of the four pushing connecting rods II 4-5 to move downwards, the four pushing connecting rods II 4-5 respectively push the four T-shaped sliding rails II 4-6 to be away from each other, the four T-shaped sliding rails II 4-6 respectively push the four hinged blocks II 5-4 to be away from each other, the inclined support angle of the middle end of the bottom supporting rod 5-1 is adjusted, and the inclined degree of the bottom supporting rod 5-1 and the four bottoms are adjusted through the linkage and the control between the adjusting mechanism I2 and the adjusting mechanism The supporting rods 5-1 are enclosed into a circle, the floor area of the device and the supporting angle of the bottom support 5 are adjusted, and the device is pre-embedded and installed through four pre-embedded plates 5-5 after adjustment is completed.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1-12, and the fifth embodiment is further described, wherein the bottom bracket 5 comprises a bottom support rod 5-1, a sliding waist hole 5-2, a hinge block i 5-3, a hinge block ii 5-4, a pre-embedded plate 5-5, an anchor bolt 5-6 and a nut 5-7, the bottom support rod 5-1 is provided with the sliding waist hole 5-2, the bottom support rod 5-1 is fixedly connected with the hinge block i 5-3, the sliding waist hole 5-2 is slidably connected with the hinge block ii 5-4, the lower end of the bottom support rod 5-1 is hinged with the pre-embedded plate 5-5, the pre-embedded plate 5-5 is provided with four anchor bolts 5-6, the four anchor bolts 5-6 are all connected with the nut 5-7 through threads, the bottom support 5 is provided with four hinging blocks I5-3 which are respectively hinged at the outer ends of the four T-shaped sliding rails I2-5, and the four hinging blocks II 5-4 are respectively hinged at the outer ends of the four T-shaped sliding rails II 4-6.

The seventh embodiment:

the following describes the present embodiment with reference to fig. 1-12, and the present embodiment further describes an embodiment six, where the mounting bracket 6 includes a mounting bottom frame 6-1, a support rib ii 6-2, a connecting block ii 6-3, a positioning boss i 6-4, a support rod iii 6-5, a support rib iii 6-6, a mounting top frame 6-7, a support rib iv 6-8, a mounting spigot ii 6-9 and a connecting block iii 6-10, the mounting bottom frame 6-1 is fixedly connected with the support rib ii 6-2, the mounting bottom frame 6-1 is fixedly connected with four connecting blocks ii 6-3, the lower end of the mounting bottom frame 6-1 is fixedly connected with four positioning bosses i 6-4, the mounting bottom frame 6-1 and the mounting top frame 6-7 are fixedly connected with four support rods iii 6-5 and four support ribs iii 6-6, the mounting top frame 6-7 is fixedly connected with a supporting rib IV 6-8, the mounting top frame 6-7 is fixedly connected with four connecting blocks III 6-10, the mounting top frame 6-7 is provided with four mounting rabbets II 6-9, four positioning bosses I6-4 are respectively arranged in the four mounting rabbets I1-8, the four connecting blocks I1-9 are respectively fixedly connected with the four connecting blocks II 6-3 through bolts, the mounting bracket 6 is provided with a plurality of positioning bosses I6-4, the mounting bracket 6 at the upper end is respectively arranged in the four mounting rabbets II 6-9 arranged on the mounting bracket 6 at the lower end, the four connecting blocks II 6-3 arranged on the mounting bracket 6 positioned at the upper end are respectively fixedly connected with the four connecting blocks III 6-10 arranged on the mounting bracket 6 positioned at the lower end through bolts.

The specific implementation mode is eight:

the following describes the present embodiment with reference to fig. 1 to 12, and the seventh embodiment is further described in the present embodiment, where the top support 7 includes a top bottom frame 7-1, support ribs v 7-2, connecting blocks iv 7-3, support rods iv 7-4, a signal enhancer 7-5, and positioning bosses ii 7-6, the top bottom frame 7-1 is fixedly connected with the support ribs v 7-2, the upper end of the top bottom frame 7-1 is fixedly connected with four support ribs v 7-2, the four support ribs v 7-2 are all fixedly connected to the signal enhancer 7-5, the lower end of the top bottom frame 7-1 is fixedly connected with four positioning bosses ii 7-6, the top bottom frame 7-1 is fixedly connected with four connecting blocks iv 7-3, and the four positioning bosses ii 7-6 provided on the top support 7 are respectively mounted on the four mounting brackets 6 provided at the uppermost end In each mounting spigot II 6-9, four connecting blocks IV 7-3 arranged on the top bracket 7 are respectively fixedly connected with four corresponding connecting blocks III 6-10 through bolts.

The invention relates to a small adjustable 5G signal enhancement tower, which has the working principle that:

when the floor area of the device needs to be adjusted according to different use requirements, the adjusting handle I2-2 is manually rotated to enable the adjusting handle I2-2 to rotate by taking the axis of the adjusting handle I2-2 as the center, the adjusting handle I2-2 drives the adjusting screw rod I2-1 to rotate by taking the axis of the adjusting screw rod I2-1 as the center, the adjusting screw rod I2-1 drives the pushing screw block I2-3 to move in the axis direction of the adjusting screw rod I2-1 through threads, the screw block I2-3 moves downwards to push the inner sides of the four pushing connecting rods I2-4 to move downwards, the outer sides of the four pushing connecting rods I2-4 are mutually far away, the four pushing connecting rods I2-4 respectively push the four hinging blocks I5-3 to be mutually far away, the position of the bottom supporting rod 5-1 is adjusted, and the four inserting shafts 2-9 are respectively inserted into the four The adjusting screw rod I2-1 drives the linkage plate 2-7 to rotate by taking the axis of the linkage plate as a center, the linkage plate 2-7 drives the four insertion shafts 2-9 to rotate by taking the axis of the linkage plate 2-7 as a center, the four insertion shafts 2-9 drive the adjusting handle II 4-2 to rotate by taking the axis of the linkage plate 2-7 as a center, linkage between the adjusting mechanism I2 and the adjusting mechanism II 4 is realized, the linkage column 2-6 is pulled upwards to extrude a compression spring so that the four insertion shafts 2-9 are not respectively inserted into the four insertion ports 4-3, and the adjusting mechanism I2 and the adjusting mechanism II 4 are separated and can be respectively controlled; when the adjusting handle II 4-2 rotates, the adjusting handle II 4-2 drives the adjusting screw rod II 4-1 to rotate by taking the axis of the adjusting screw rod II 4-1 as the center, the adjusting screw rod II 4-1 drives the pushing screw block II 4-4 to move in the axis direction of the adjusting screw rod II 4-1 through threads, when the pushing screw block II 4-4 moves downwards, the pushing screw block II 4-4 pushes the inner sides of the four pushing connecting rods II 4-5 to move downwards, the four pushing connecting rods II 4-5 respectively push the four T-shaped sliding rails II 4-6 to be away from each other, the four T-shaped sliding rails II 4-6 respectively push the four hinged blocks II 5-4 to be away from each other, the inclined support angle of the middle end of the bottom supporting rod 5-1 is adjusted, and the inclined degree of the bottom supporting rod 5-1 and the four bottoms are adjusted through the linkage and the control between the adjusting mechanism I2 and the adjusting mechanism The supporting rods 5-1 are encircled into a circle, the floor area of the device and the supporting angle of the bottom bracket 5 are adjusted, and the device is pre-embedded and installed through four pre-embedded plates 5-5 when the adjustment is finished; the quick mounting device is mounted in four mounting rabbets I1-8 through four positioning bosses I6-4 respectively, four connecting blocks I1-9 are fixedly connected with four connecting blocks II 6-3 through bolts respectively, the mounting bracket 6 is provided with a plurality of mounting brackets, four positioning bosses I6-4 arranged on the mounting bracket 6 at the upper end are mounted in four mounting rabbets II 6-9 arranged on the mounting bracket 6 at the lower end respectively, four connecting blocks II 6-3 arranged on the mounting bracket 6 at the upper end are fixedly connected with four connecting blocks III 6-10 arranged on the mounting bracket 6 at the lower end through bolts respectively, the quick mounting device is mounted by mutual stacking among a plurality of mounting brackets 6, and the connecting blocks II 6-3, the positioning bosses I6-4, the connecting blocks II 6-3 arranged on the mounting bracket 6, The installation seam allowances II 6-9 and the connecting blocks III 6-10 can complete quick installation between the installation supports 6, and the height of the device can be conveniently adjusted.

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 (8)

1. The utility model provides a small-size adjustable 5G signal enhancement tower, includes support frame (1), guiding mechanism I (2), alignment jig (3), guiding mechanism II (4), bottom sprag (5), installing support (6) and top sprag (7), its characterized in that: the adjustable lifting device is characterized in that an adjusting mechanism I (2) is connected onto the support frame (1), an adjusting frame (3) is fixedly connected to the lower end of the support frame (1), an adjusting mechanism II (4) is connected onto the adjusting frame (3), the adjusting mechanism I (2) adjusts the inclination angle of the upper end of the bottom support (5), the adjusting mechanism II (4) adjusts the inclination angle of the middle end of the bottom support (5), a plurality of mounting supports (6) are mounted on the support frame (1), and a top support (7) is mounted on each mounting support (6);

the supporting frame (1) comprises a cross supporting frame I (1-1), a supporting rod I (1-2), a supporting rod II (1-3), a connecting frame (1-4), a limiting baffle I (1-5), a T-shaped groove I (1-6), a connecting rod (1-7), an installation spigot I (1-8) and a connecting block I (1-9);

the adjusting mechanism I (2) comprises an adjusting screw rod I (2-1), an adjusting handle I (2-2), a pushing thread block I (2-3), a pushing connecting rod I (2-4), a T-shaped sliding rail I (2-5), a linkage column (2-6), a linkage plate (2-7), limiting columns (2-8) and inserting shafts (2-9), the lower end of the linkage column (2-6) is fixedly connected with the linkage plate (2-7), the upper end of the linkage plate (2-7) is fixedly connected with four limiting columns (2-8), the four limiting columns (2-8) are respectively connected in four sliding holes formed in the cross supporting frame I (1-1) in a sliding mode, the lower end of the linkage plate (2-7) is fixedly connected with four inserting shafts (2-9), and compression springs are sleeved on the four limiting columns (2-8), the compression spring is positioned between the cross support frame I (1-1) and the linkage plate (2-7).

2. The small adjustable 5G signal enhancement tower of claim 1, wherein: four supporting rods I (1-2) are fixedly connected to a cross supporting frame I (1-1), the upper ends of the four supporting rods I (1-2) are fixedly connected to a connecting frame (1-4), four corners of the cross supporting frame I (1-1) are fixedly connected to supporting rods II (1-3), the upper ends of the four supporting rods II (1-3) are fixedly connected to the connecting frame (1-4), four corners of the cross supporting frame I (1-1) are fixedly connected to limit baffles I (1-5), four edges of the cross supporting frame I (1-1) are provided with T-shaped grooves I (1-6), four corners of the lower end of the cross supporting frame I (1-1) are fixedly connected to connecting rods (1-7), and four sliding holes are formed in the cross supporting frame I (1-1), four edges of the connecting frames (1-4) are fixedly connected with connecting blocks I (1-9), and four corners of the connecting frames (1-4) are provided with mounting rabbets I (1-8).

3. The small adjustable 5G signal enhancement tower of claim 2, wherein: the lower end of an adjusting screw rod I (2-1) is rotatably connected to the center of a cross support frame I (1-1), an adjusting handle I (2-2) is fixedly connected to the upper end of the adjusting screw rod I (2-1), a pushing threaded block I (2-3) is connected to the adjusting screw rod I (2-1) through threads, four pushing connecting rods I (2-4) are hinged to the pushing threaded block I (2-3), T-shaped sliding rails I (2-5) are hinged to the lower ends of the four pushing connecting rods I (2-4), the four T-shaped sliding rails I (2-5) are respectively connected to four T-shaped grooves I (1-6) in a sliding mode, and a linkage column (2-6) is connected to the adjusting screw rod I (2-1) in a sliding mode.

4. The small adjustable 5G signal enhancement tower of claim 3, wherein: the adjusting frame (3) comprises a cross support frame II (3-1), a limiting baffle II (3-2), a T-shaped groove II (3-3) and support ribs I (3-4), four corners of the cross support frame II (3-1) are fixedly connected to the lower ends of four connecting rods (1-7) respectively, the support ribs I (3-4) are fixedly connected between four sides of the cross support frame II (3-1), the limiting baffle II (3-2) is fixedly connected to each of the four corners of the cross support frame II (3-1), and the T-shaped groove II (3-3) is arranged on each of the four sides of the cross support frame II (3-1).

5. The small adjustable 5G signal enhancement tower of claim 4, wherein: the adjusting mechanism II (4) comprises an adjusting screw rod II (4-1), an adjusting handle II (4-2), a socket (4-3), a pushing thread block II (4-4), a pushing connecting rod II (4-5) and a T-shaped sliding rail II (4-6), the lower end of the adjusting screw rod II (4-1) is rotatably connected to the cross-shaped supporting frame II (3-1), the upper end of the adjusting screw rod II (4-1) is fixedly connected with the adjusting handle II (4-2), four sockets (4-3) are arranged on the adjusting handle II (4-2), four limiting columns (2-8) are respectively and slidably connected into the four sockets (4-3), the adjusting screw rod II (4-1) is connected with the pushing thread block II (4-4) through threads, and the pushing thread block II (4-4) is hinged with four pushing connecting rods II (4-5), the lower ends of the four pushing connecting rods II (4-5) are hinged with T-shaped sliding rails II (4-6), and the four T-shaped sliding rails II (4-6) are respectively connected in the four T-shaped grooves II (3-3) in a sliding mode.

6. The small adjustable 5G signal enhancement tower of claim 5, wherein: the bottom support (5) comprises a bottom support rod (5-1), sliding waist holes (5-2), hinging blocks I (5-3), hinging blocks II (5-4), embedded plates (5-5), foundation bolts (5-6) and nuts (5-7), the sliding waist holes (5-2) are formed in the bottom support rod (5-1), the hinging blocks I (5-3) are fixedly connected to the bottom support rod (5-1), the hinging blocks II (5-4) are slidably connected to the sliding waist holes (5-2), the embedded plates (5-5) are hinged to the lower end of the bottom support rod (5-1), the four foundation bolts (5-6) are mounted on the embedded plates (5-5), and the nuts (5-7) are connected to the four foundation bolts (5-6) through threads, the bottom support (5) is provided with four hinging blocks I (5-3) which are respectively hinged at the outer ends of the four T-shaped sliding rails I (2-5), and the hinging blocks II (5-4) are respectively hinged at the outer ends of the four T-shaped sliding rails II (4-6).

7. The small adjustable 5G signal enhancement tower of claim 6, wherein: the mounting bracket (6) comprises a mounting bottom frame (6-1), support ribs II (6-2), connecting blocks II (6-3), positioning bosses I (6-4), support rods III (6-5), support ribs III (6-6), a mounting top frame (6-7), support ribs IV (6-8), mounting rabbets II (6-9) and connecting blocks III (6-10), the mounting bottom frame (6-1) is fixedly connected with the support ribs II (6-2), the mounting bottom frame (6-1) is fixedly connected with four connecting blocks II (6-3), the lower end of the mounting bottom frame (6-1) is fixedly connected with four positioning bosses I (6-4), and four support rods III (6-5) and four support ribs III (6-6) are fixedly connected between the mounting bottom frame (6-1) and the mounting top frame (6-7), the mounting top frame (6-7) is fixedly connected with support ribs IV (6-8), the mounting top frame (6-7) is fixedly connected with four connecting blocks III (6-10), the mounting top frame (6-7) is provided with four mounting spigots II (6-9), four positioning bosses I (6-4) are respectively mounted in the four mounting spigots I (1-8), the four connecting blocks I (1-9) are respectively fixedly connected with the four connecting blocks II (6-3) through bolts, the mounting bracket (6) is provided with a plurality of positioning bosses I (6-4), the four positioning bosses I (6-4) arranged on the mounting bracket (6) positioned at the upper end are respectively mounted in the four mounting spigots II (6-9) arranged on the mounting bracket (6) positioned at the lower end, and the four connecting blocks II (6-3) arranged on the mounting bracket (6) positioned at the upper end are respectively mounted on the mounting bracket (6) positioned at the lower end through bolts and the 6) The four connecting blocks III (6-10) are fixedly connected.

8. The small adjustable 5G signal enhancement tower of claim 7, wherein: the top support (7) comprises a top bottom frame (7-1), support ribs V (7-2), connecting blocks IV (7-3), support rods IV (7-4), a signal enhancer (7-5) and positioning bosses II (7-6), the top bottom frame (7-1) is fixedly connected with the support ribs V (7-2), the upper end of the top bottom frame (7-1) is fixedly connected with the four support ribs V (7-2), the four support ribs V (7-2) are fixedly connected to the signal enhancer (7-5), the lower end of the top bottom frame (7-1) is fixedly connected with the four positioning bosses II (7-6), the top bottom frame (7-1) is fixedly connected with the four connecting blocks IV (7-3), and the four positioning bosses II (7-6) arranged on the top support (7) are respectively installed on an installation support (6) located at the uppermost end In the four mounting rabbets II (6-9), four connecting blocks IV (7-3) arranged on the top support (7) are respectively fixedly connected with four corresponding connecting blocks III (6-10) through bolts.

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