CN112350048B - Miniaturized 5G signal multiplier antenna base - Google Patents

Abstract

The invention relates to the technical field of 5G signal devices, in particular to a miniaturized 5G signal multiplier antenna base which comprises a base mechanism, a supporting mechanism, a signal transmitting mechanism, an adjusting mechanism, a counterweight mechanism, a fixing mechanism and a pre-embedding mechanism.

Description

Miniaturized 5G signal multiplier antenna base

Technical Field

The invention relates to the technical field of 5G signal devices, in particular to a miniaturized 5G signal multiplier antenna base.

Background

For example, publication number CN109025455a discloses an anti-seismic buffer type lightning protection signal tower device, which comprises a supporting base, a supporting sleeve, an arc-shaped clamping block, a current-limiting lightning rod and a signal tower body, wherein the bottom end of the signal tower body is fixedly welded and connected with a mounting base; support columns arranged in the vertical direction are fixedly welded at the tops of the two ends of the support base, and support sleeves arranged in the horizontal direction are fixedly welded at the tops of the two support columns; the inner cavity of the supporting sleeve is respectively provided with a first sliding block and a second sliding block in a horizontal sliding mode, and the first sliding block is connected with the second sliding block through a spring; a fixed seat is fixedly arranged on one side of the supporting sleeve, and the fixed seat is sleeved on the screw rod in a threaded connection mode; the screw rod is arranged at one end of the inner cavity and is rotationally connected with the first sliding block, a through hole is formed in one end, far away from the fixed seat, of the supporting sleeve, a pressing rod is arranged in the through hole in a sliding penetrating mode, and one end, arranged at the inner cavity of the supporting sleeve, of the pressing rod is fixedly arranged on the second sliding block; an arc-shaped clamping block which is used for clamping the signal tower body is fixedly arranged at one end of the pressure rod, which is far away from the supporting sleeve; a supporting vertical rod arranged in the vertical direction is fixedly arranged at the top end of the signal tower body, and a current-limiting lightning rod is arranged at the top end of the supporting vertical rod; because the working environment of the device is often influenced by wind power, the device can topple over loudly when the device is subjected to strong wind weather, and economic loss is caused.

Disclosure of Invention

The invention aims to provide a miniaturized 5G signal multiplier antenna base which can automatically re-weight in strong wind weather and enhance the stability of a device.

The aim of the invention is achieved by the following technical scheme:

the utility model provides a miniaturized 5G signal multiplier antenna base, includes base mechanism, supporting mechanism, signal transmission mechanism, adjustment mechanism, counter weight mechanism, fixed establishment and pre-buried mechanism, base mechanism's top sliding connection has supporting mechanism, and signal transmission mechanism connects in supporting mechanism's upper end, and supporting mechanism's below is connected with three adjustment mechanism, and three adjustment mechanism all is connected on base mechanism, is connected with three counter weight mechanism on the base mechanism, and three fixed establishment's lower extreme is connected with pre-buried mechanism respectively, and three fixed establishment all is connected at base mechanism's lower extreme.

As a further optimization of the technical scheme, the miniaturized 5G signal multiplier antenna base comprises a base, support columns I, sliding rails, sliding grooves I, sliding grooves II, connecting bolts and fixing holes, wherein the support columns I are fixedly connected to the middle of the base, the sliding grooves I are uniformly arranged around the base, the sliding rails are arranged on two sides of each sliding groove I, three sliding grooves II are uniformly arranged around the support columns I, the three connecting bolts are uniformly distributed at the bottom of the base, and the fixing holes are uniformly formed in each connecting bolt.

As a further optimization of the technical scheme, the antenna base of the miniaturized 5G signal multiplier comprises a support column II, a rotating seat, a worm and a handle I, wherein the support column II is connected to the support column I in a sliding manner, the rotating seat is fixedly connected to the upper end of the support column II, the worm is connected to the rotating seat in a rotating manner, and one end of the worm is fixedly connected with the handle I.

As a further optimization of the technical scheme, the miniaturized 5G signal multiplier antenna base comprises a support column III, supports I, signal transmitters, piston cylinders I, a rotating disc and worm wheels, wherein the lower end of the support column III is fixedly connected with the rotating disc, the worm wheels are fixedly connected with the lower end of the rotating disc, three supports I are uniformly arranged around the support column III, each support I is slidably connected onto the support column III, each support I is fixedly connected with the signal transmitter, one end of each piston cylinder I is respectively and fixedly connected onto each support I, the other end of each support I is fixedly connected onto the support column III, and the worm wheels are in transmission connection with a worm.

As a further optimization of the technical scheme, the miniaturized 5G signal multiplier antenna base comprises a movable block, a screw rod, a handle II and a connecting rod, wherein the movable block is connected to a sliding rail in a sliding mode, one end of the screw rod is connected to the movable block in a rotating mode, the handle II is fixedly connected to the other end of the screw rod, the screw rod is connected to the base in a threaded mode, one end of the connecting rod is connected to the movable block in a rotating mode, and the other end of the connecting rod is connected to the supporting column II in a rotating mode.

As a further optimization of the technical scheme, the antenna base of the miniaturized 5G signal multiplier comprises a bracket II, a connecting rod, a balancing weight, a spring I and a piston cylinder II, wherein the bracket II is connected to the base in a sliding mode, one end of the connecting rod is fixedly connected to the bracket II, the other end of the connecting rod is fixedly connected to the balancing weight, the spring I is sleeved on the connecting rod, one end of the spring I is fixedly connected to the bracket II, the other end of the spring I is fixedly connected to the base, one end of the piston cylinder II is fixedly connected to the bracket II, and the other section of the piston cylinder II is fixedly connected to the base.

As a further optimization of the technical scheme, the antenna base of the miniaturized 5G signal multiplier is characterized in that the piston cylinder I is connected with the piston cylinder II through a conduit, and the piston cylinder I, the piston cylinder II and the conduit form a communicating vessel.

As a further optimization of the technical scheme, the antenna base of the miniaturized 5G signal multiplier comprises a support III, telescopic rods I, fixing blocks, springs II, telescopic rods II, locking blocks and springs III, wherein the fixing blocks are arranged on two sides of the support III, two telescopic rods I are arranged between each fixing block and the support III, springs II are arranged between each fixing block and the support III, locking blocks are arranged on two sides of the support III, two telescopic rods II are arranged between each locking block and the support III, and springs III are arranged between each locking block and the support III.

As a further optimization of the technical scheme, the antenna base of the miniaturized 5G signal multiplier comprises a jacking block, a push rod, supports IV, a connecting rod II, support rods and a connecting rod III, wherein the lower end of the jacking block is fixedly connected with the push rod, the push rod is slidably connected to the middle of the support III, the supports IV are arranged on two sides of the push rod, each support IV is fixedly connected to the support III, three support rods are rotatably connected to each support IV, each support rod is connected with the push rod through the connecting rod II, and the jacking block is connected with the two fixing blocks through the connecting rod III.

The miniaturized 5G signal multiplier antenna base has the beneficial effects that:

according to the miniaturized 5G signal multiplier antenna base, the angle of the signal transmitting mechanism can be adjusted according to different terrains through the arrangement of the supporting mechanism, the height of the device can be adjusted through the arranged adjusting mechanism, so that the signal transmission effect is better, the user experience can be improved, when the device receives larger wind force through the cooperation between the signal transmitting mechanism and the counterweight mechanism, the counterweight is carried out on the periphery of the device again by utilizing the principle of the communicating vessel, the pit wind effect of the device can be improved, the stability of the device is improved, the fixing mechanism and the embedding mechanism are embedded during installation, the quick installation of the base mechanism can be realized, the gravity of the base mechanism is utilized for carrying out self-locking twice after the installation is completed, and the external force resistance effect of the device can be effectively improved through forming the barb structure under soil.

Drawings

The invention will be described in further detail with reference to the accompanying drawings and detailed description.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and "upright", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly stated and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, may be directly connected, or indirectly connected through an intermediary, or may be in communication with the inside of two members. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Furthermore, in the description of the present invention, unless otherwise indicated, the meaning of "a plurality", "a plurality of groups", "a plurality of roots" is two or more.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of the base mechanism of the present invention;

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

FIG. 4 is a schematic diagram of the structure of the signal transmitting mechanism of the present invention;

FIG. 5 is a schematic view of the structure of the adjustment mechanism of the present invention;

FIG. 6 is a schematic view of the construction of the weighting mechanism of the present invention;

FIG. 7 is a schematic view of the structure of the fixing mechanism of the present invention;

fig. 8 is a schematic structural view of the embedding mechanism of the present invention.

In the figure: a base mechanism 1; a base 101; support column I102; a slide rail 103; chute I104; chute II 105; a connecting pin 106; a fixing hole 107; a support mechanism 2; support column II 201; a rotating base 202; a worm 203; handle I204; a signal transmitting mechanism 3; support column III 301; a bracket I302; a signal transmitter 303; piston cylinder I304; a rotating disc 305; a worm wheel 306; an adjusting mechanism 4; a movable block 401; a screw 402; handle ii 403; a link 404; a counterweight mechanism 5; a bracket II 501; a connecting rod 502; a weight 503; spring I504; piston cylinder ii 505; a fixing mechanism 6; a support III 601; telescoping rod I602; a fixed block 603; spring II 604; telescoping rod ii 605; a locking block 606; spring III 607; a pre-burying mechanism 7; a top block 701; a push rod 702; a bracket IV 703; a connecting rod II 704; a strut 705; link iii 706.

Detailed Description

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

The first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 8, a miniaturized 5G signal multiplier antenna base, including a base mechanism 1, a supporting mechanism 2, a signal transmitting mechanism 3, an adjusting mechanism 4, a weight balancing mechanism 5, a fixing mechanism 6 and a pre-embedding mechanism 7, wherein the supporting mechanism 2 is slidingly connected above the base mechanism 1, the signal transmitting mechanism 3 is connected to the upper end of the supporting mechanism 2, three adjusting mechanisms 4 are connected below the supporting mechanism 2, the three adjusting mechanisms 4 are all connected to the base mechanism 1, the base mechanism 1 is connected with three weight balancing mechanisms, the lower ends of the three fixing mechanisms 6 are respectively connected to the pre-embedding mechanism 7, and the three fixing mechanisms 6 are all connected to the lower end of the base mechanism 1; through the setting of supporting mechanism 2, can adjust signal emission mechanism 3's angle according to the topography of difference, can adjust the height of device through the adjustment mechanism 4 that sets up, make the signal transmission effect better, can improve user experience, through the cooperation between signal emission mechanism 3 and the counter weight mechanism 5, when the device receives great wind-force, utilize the communicating vessel principle to carry out the counter weight again around the device, the wind effect of pit of multiplicable device, improve the stability of device, pre-buried fixed establishment 6 and pre-buried mechanism 7 when the installation, can realize the quick installation to base mechanism 1, utilize the gravity of base mechanism 1 to carry out twice auto-lock after the installation, through forming barb structure under soil, the effect of the anti external force of effectual improvement device.

The second embodiment is as follows:

in the following description of the present embodiment with reference to fig. 1 to 8, the first embodiment is further described, where the base mechanism 1 includes a base 101, a support column i 102, a slide rail 103, a slide slot i 104, a slide slot ii 105, a connecting bolt 106, and a fixing hole 107, the support column i 102 is fixedly connected to the middle of the base 101, the slide slots i 104 are uniformly arranged around the base 101, the slide rails 103 are arranged on two sides of each slide slot i 104, three slide slots ii 105 are uniformly arranged around the support column i 102, the three connecting bolts 106 are uniformly distributed at the bottom of the base 101, and the fixing hole 107 is formed on each connecting bolt 106; the base mechanism 1 can provide a supporting function for the whole device, so that the devices are more compact, and a supporting force is provided for the devices.

And a third specific embodiment:

referring to fig. 1-8, a second embodiment is further described, where the support mechanism 2 includes a support column ii 201, a rotating seat 202, a worm 203, and a handle i 204, the support column ii 201 is slidably connected to the support column i 102, the rotating seat 202 is fixedly connected to an upper end of the support column ii 201, the worm 203 is rotatably connected to the rotating seat 202, and one end of the worm 203 is fixedly connected to the handle i 204; the worm 203 is driven to rotate by the rotating handle I204, the signal transmitting mechanism 3 is pushed to rotate by the rotation of the worm 203, the transmitting direction of the signal transmitting mechanism 3 can be adjusted according to the terrain, and the working efficiency of the device is improved.

The specific embodiment IV is as follows:

in the following description of the present embodiment with reference to fig. 1-8, the third embodiment is further described, where the signal transmitting mechanism 3 includes a support column iii 301, a support frame i 302, a signal transmitter 303, a piston cylinder i 304, a rotating disc 305, and a worm wheel 306, the lower end of the support column iii 301 is fixedly connected with the rotating disc 305, the lower end of the rotating disc 305 is fixedly connected with the worm wheel 306, three support frames i 302 are uniformly disposed around the support column iii 301, each support frame i 302 is slidably connected to the support column iii 301, a signal transmitter 303 is fixedly connected to each support frame i 302, one ends of the three piston cylinders i 304 are respectively fixedly connected to the three support frames i 302, the other ends of the support frames i 302 are fixedly connected to the support column iii 301, and the worm wheel 306 is in transmission connection with the worm 203; when the signal transmitter 303 is affected by wind power, the bracket I302 is pushed to slide on the supporting column III 301 due to the effect of wind power, the piston cylinder I304 is compressed when the bracket I302 moves under the effect of wind power, the rotating disc 305 ensures that the signal transmitting mechanism 3 rotates stably, and the worm wheel 306 is meshed with the worm 203, so that the worm 203 drives the worm wheel 306 to rotate, and the worm wheel 306 rotates to drive the signal transmitting mechanism 3 to rotate.

Fifth embodiment:

in the following description of the present embodiment with reference to fig. 1 to 8, the fourth embodiment is further described, where the adjusting mechanism 4 includes a movable block 401, a screw rod 402, a handle ii 403, and a connecting rod 404, the movable block 401 is slidably connected to the slide rail 103, one end of the screw rod 402 is rotatably connected to the movable block 401, the other end of the screw rod 402 is fixedly connected to the handle ii 403, the screw rod 402 is threadedly connected to the base 101, one end of the connecting rod 404 is rotatably connected to the movable block 401, and the other end of the connecting rod 404 is rotatably connected to the support column ii 201; the screw rod 402 is driven to rotate by rotating the handle II 403, and the screw rod 402 is connected to the base 101 in a threaded manner, so that the movable block 401 is pushed to move by the rotation of the screw rod 402, and the support column II 201 is pushed to move by the movable block 401 through the connecting rod 404.

Specific embodiment six:

in the following description of the present embodiment with reference to fig. 1 to 8, the fifth embodiment is further described, where the weight mechanism 5 includes a bracket ii 501, a connecting rod 502, a counterweight 503, a spring i 504, and a piston cylinder ii 505, the bracket ii 501 is slidably connected to the base 101, one end of the connecting rod 502 is fixedly connected to the bracket ii 501, the other end of the connecting rod 502 is fixedly connected to the counterweight 503, the spring i 504 is sleeved on the connecting rod 502, one end of the spring i 504 is fixedly connected to the bracket ii 501, the other end of the spring i 504 is fixedly connected to the base 101, one end of the piston cylinder ii 505 is fixedly connected to the bracket ii 501, and the other end of the piston cylinder ii 505 is fixedly connected to the base 101; the movement of the piston cylinder II 505 will push the support II 501 to move, the support II 501 will push the connecting rod 502 and the balancing weight 503 to move, the balancing weight 503 is arranged to re-balance the device, the wind resistance of the device is strong, and when the device is not subjected to wind power, the support II 501 is pushed to restore to the original position due to the action of the spring I504.

Seventh embodiment:

in the following, referring to fig. 1-8, this embodiment will be further described as a sixth embodiment, where the piston cylinder i 304 is connected to the piston cylinder ii 505 by a conduit, and the piston cylinder i 304, the piston cylinder ii 505, and the conduit form a communicating vessel; piston cylinder I304, piston cylinder II 505 and the conduit form a communicating vessel, and the piston cylinder I304 is compressed to push the piston cylinder II 505 to extend through the conduit.

Eighth embodiment:

in the following description of the present embodiment with reference to fig. 1-8, the present embodiment further describes a seventh embodiment, where the fixing mechanism 6 includes a support iii 601, a telescopic rod i 602, a fixing block 603, a spring ii 604, a telescopic rod ii 605, a locking block 606, and a spring iii 607, two sides of the support iii 601 are provided with fixing blocks 603, two telescopic rods i 602 are provided between each fixing block 603 and the support iii 601, a spring ii 604 is provided between each fixing block 603 and the support iii 601, two sides of the support iii 601 are provided with locking blocks 606, each locking block 606 and the support iii 601 are provided with two telescopic rods ii 605, and each locking block 606 and the support iii 601 are provided with a spring iii 607; when the fixing mechanism 6 is used, the fixing mechanism 6 is pre-buried in soil, when the base mechanism 1 is installed, the connecting bolts 106 push the locking blocks 606 on two sides to move to two sides, the spring III 607 is compressed, when the connecting bolts 106 are inserted into the lowest end, the two locking blocks 606 restore to the original positions under the action of the spring III 607, the connecting bolts 106 are locked, when the connecting bolts 106 are inserted into the opposite lower ends, the connecting bolts 106 push the pre-buried mechanism 7 to push the fixing blocks 603 on two sides to move to the middle, and the two fixing blocks 603 are inserted into the fixing holes 107, so that the connecting bolts 106 are secondarily locked.

Detailed description nine:

in the following description of the present embodiment with reference to fig. 1 to 8, the eighth embodiment is further described, where the pre-embedding mechanism 7 includes a top block 701, a push rod 702, a support iv 703, a link ii 704, a support bar 705 and a link iii 706, the lower end of the top block 701 is fixedly connected with the push rod 702, the push rod 702 is slidably connected to the middle of the support iii 601, two sides of the push rod 702 are respectively provided with a support iv 703, each support iv 703 is fixedly connected to the support iii 601, each support iv 703 is rotationally connected with three support bars 705, each support 705 is connected with the push rod 702 through the link ii 704, and the top block 701 is connected with two fixing blocks 603 through the link iii 706; because the connection bolt 106 pushes the top block 701 and the push rod 702 to move downwards, and because the push rod 702 is connected with the support rod 705 through the connecting rod II 704, the push rod 702 pushes the support rod 705 to extend to two sides when moving downwards, barbs are formed, and the fixing mechanism 6 and the embedding mechanism 7 of the device are prevented from moving under the condition of being stressed.

The invention relates to a miniaturized 5G signal multiplier antenna base, which has the following working principle:

when the fixing mechanism 6 is used, firstly, the fixing mechanism 6 is pre-buried in soil, when the base mechanism 1 is installed, the connecting bolt 106 pushes the locking blocks 606 at two sides to move to two sides, the spring III 607 is compressed, when the connecting bolt 106 is inserted to the lowest end, the two locking blocks 606 are restored to the original positions under the action of the spring III 607, the connecting bolt 106 is locked, when the connecting bolt 106 is inserted to the lower end, the connecting bolt 106 pushes the top block 701 and the push rod 702 to move downwards, when the push rod 702 is connected with the support rod 705 through the connecting rod II, the push rod 702 pushes the support rod 705 to extend to two sides to form barbs when moving downwards, the fixing mechanism 6 and the pre-buried mechanism 7 are prevented from moving under the condition of being stressed, the connecting bolt 106 pushes the pre-buried mechanism 7 to pull the fixing blocks 603 at two sides to move to the middle, the two fixing blocks 603 are inserted into the fixing holes 107, the connecting bolt 106 is locked secondarily, the screw rod 402 is driven to rotate by rotating the handle II 403, the screw rod 402 is in threaded connection with the base 101, the movable block 401 is driven to move by the rotation of the screw rod 402, the support column II 201 is driven to move by the movement of the movable block 401 through the connecting rod 404, the worm 203 is driven to rotate by the rotating handle I204, the signal transmitting mechanism 3 is driven to rotate by the rotation of the worm 203, the transmitting direction of the signal transmitting mechanism 3 can be regulated according to the terrain, the working efficiency of the device is improved, when the signal transmitter 303 is influenced by wind power, the bracket I302 is driven to slide on the support column III 301 due to the effect of wind power, the piston cylinder I304 is compressed when the bracket I302 moves due to the wind power, the arrangement of the rotating disc 305 ensures the stable rotation of the signal transmitting mechanism 3, and the meshed connection between the worm wheel 306 and the worm 203, the rotation of worm 203 will promote worm wheel 306 and rotate, worm wheel 306's rotation will drive signal emission mechanism 3 and rotate, piston cylinder I304, piston cylinder II 505 and pipe constitution fluid communication ware, receive the compression at piston cylinder I304 and make will promote piston cylinder II 505 extension through the pipe, the removal of piston cylinder II 505 will promote support II 501 and remove, support II 501 will promote connecting rod 502 and balancing weight 503 and move, carry out the counter weight again to the device through balancing weight 503 that sets up, the wind-resistant ability of true strong device, when not having the device to receive the wind-force, because the effect of spring I504, promote support II 501 and resume original position, the device can be adjusted according to the angle of signal emission mechanism 3 through setting up of supporting mechanism 2, can adjust the height of device through adjustment mechanism 4 that sets up, make the signal transmission effect better, can improve user experience, through the cooperation between signal emission mechanism 3 and counter weight mechanism 5, when the device receives great wind-force, utilize the fluid communication ware hole again, carry out counter weight around the device, can increase the stability of device, the stability of device is improved, install mechanism 7 and can be installed at the quick-mounting mechanism 1 at the bottom of the base of the device, the quick-mounting mechanism 1 can be realized, the soil self-locking effect is achieved through the quick-locking mechanism is realized, the device is realized, the soil self-locking mechanism is installed down at the base 1.

Of course, the above description is not intended to limit the invention, but rather the invention is not limited to the above examples, and variations, modifications, additions or substitutions within the spirit and scope of the invention will be within the scope of the invention.

Claims (4)

1. The utility model provides a miniaturized 5G signal multiplier antenna base, includes base mechanism (1), supporting mechanism (2), signal transmission mechanism (3), adjustment mechanism (4), counter weight mechanism (5), fixed establishment (6) and pre-buried mechanism (7), its characterized in that: the upper part of the base mechanism (1) is connected with a supporting mechanism (2) in a sliding manner, the signal transmitting mechanism (3) is connected to the upper end of the supporting mechanism (2), three adjusting mechanisms (4) are connected to the lower part of the supporting mechanism (2), the three adjusting mechanisms (4) are all connected to the base mechanism (1), the base mechanism (1) is connected with three counterweight mechanisms, the lower ends of the three fixing mechanisms (6) are respectively connected with a pre-buried mechanism (7), and the three fixing mechanisms (6) are all connected to the lower end of the base mechanism (1);

the base mechanism (1) comprises a base (101), support columns I (102), sliding rails (103), sliding grooves I (104), sliding grooves II (105), connecting bolts (106) and fixing holes (107), wherein the middle part of the base (101) is fixedly connected with the support columns I (102), the sliding grooves I (104) are uniformly arranged around the base (101), the sliding rails (103) are arranged on two sides of each sliding groove I (104), three sliding grooves II (105) are uniformly arranged around the support columns I (102), the three connecting bolts (106) are uniformly distributed at the bottom of the base (101), and the fixing holes (107) are uniformly formed in each connecting bolt (106);

the supporting mechanism (2) comprises a supporting column II (201), a rotating seat (202), a worm (203) and a handle I (204), wherein the supporting column II (201) is connected to the supporting column I (102) in a sliding mode, the rotating seat (202) is fixedly connected to the upper end of the supporting column II (201), the worm (203) is connected to the rotating seat (202) in a rotating mode, and one end of the worm (203) is fixedly connected with the handle I (204);

the signal transmitting mechanism (3) comprises a support column III (301), supports I (302), a signal transmitter (303), piston cylinders I (304), a rotating disc (305) and worm wheels (306), wherein the lower end of the support column III (301) is fixedly connected with the rotating disc (305), the lower end of the rotating disc (305) is fixedly connected with the worm wheels (306), three supports I (302) are uniformly arranged around the support column III (301), each support I (302) is slidably connected to the support column III (301), the signal transmitter (303) is fixedly connected to each support I (302), one end of each piston cylinder I (304) is fixedly connected to each support I (302), the other end of each support I (302) is fixedly connected to the support column III (301), and the worm wheels (306) are in transmission connection with the worm wheels (203);

the adjusting mechanism (4) comprises a movable block (401), a screw rod (402), a handle II (403) and a connecting rod (404), wherein the movable block (401) is connected to the sliding rail (103) in a sliding mode, one end of the screw rod (402) is connected to the movable block (401) in a rotating mode, the handle II (403) is fixedly connected to the other end of the screw rod (402), the screw rod (402) is connected to the base (101) in a threaded mode, one end of the connecting rod (404) is connected to the movable block (401) in a rotating mode, and the other end of the connecting rod (404) is connected to the supporting column II (201) in a rotating mode;

the counterweight mechanism (5) comprises a support II (501), a connecting rod (502), a counterweight (503), a spring I (504) and a piston cylinder II (505), wherein the support II (501) is slidably connected to the base (101), one end of the connecting rod (502) is fixedly connected to the support II (501), the other end of the connecting rod (502) is fixedly connected to the counterweight (503), the spring I (504) is sleeved on the connecting rod (502), one end of the spring I (504) is fixedly connected to the support II (501), the other end of the spring I (504) is fixedly connected to the base (101), one end of the piston cylinder II (505) is fixedly connected to the support II (501), and the other section of the piston cylinder II (505) is fixedly connected to the base (101).

2. A miniaturized 5G signal multiplier antenna base according to claim 1, wherein: the piston cylinder I (304) is connected with the piston cylinder II (505) through a conduit, and the piston cylinder I (304), the piston cylinder II (505) and the conduit form a communicating vessel.

3. A miniaturized 5G signal multiplier antenna base according to claim 1, wherein: fixed establishment (6) are including support III (601), telescopic link I (602), fixed block (603), spring II (604), telescopic link II (605), locking piece (606) and spring III (607), both sides of support III (601) all are provided with fixed block (603), all be provided with two telescopic link I (602) between every fixed block (603) and support III (601), all be provided with spring II (604) between every fixed block (603) and support III (601), both sides of support III (601) all are provided with locking piece (606), every locking piece (606) all are provided with two telescopic link II (605) with support III (601), every locking piece (606) all are provided with spring III (607) with support III (601).

4. A miniaturized 5G signal multiplier antenna base according to claim 3, wherein: the embedded mechanism (7) comprises a jacking block (701), a pushing rod (702), a support IV (703), a connecting rod II (704), a supporting rod (705) and a connecting rod III (706), wherein the pushing rod (702) is fixedly connected to the lower end of the jacking block (701), the pushing rod (702) is slidably connected to the middle of the support III (601), the supports IV (703) are arranged on two sides of the pushing rod (702), each support IV (703) is fixedly connected to the support III (601), three supporting rods (705) are rotatably connected to each support IV (703), each supporting rod (705) is connected with the pushing rod (702) through the connecting rod II (704), and the jacking block (701) is connected with the two fixing blocks (603) through the connecting rod III (706).