CN113187305A

CN113187305A - Electronic information engineering communication tower connecting device

Info

Publication number: CN113187305A
Application number: CN202110580487.5A
Authority: CN
Inventors: 王卿
Original assignee: Xinyu University
Current assignee: Xinyu University
Priority date: 2021-05-26
Filing date: 2021-05-26
Publication date: 2021-07-30

Abstract

The invention discloses a communication tower connecting device for electronic information engineering, and belongs to the technical field of communication equipment. This electronic information engineering communication tower connecting device includes: the top of the base is fixedly connected with the communication tower; a box body; the first height adjusting mechanism is hinged with one side edge of the base and is connected with a first power device, and the first height adjusting mechanism is also provided with a first stress sensor; the other end of the first connecting rod is hinged to one side edge of the base, which is far away from the first height adjusting mechanism, and a second stress sensor is arranged on the first connecting rod; a concrete block; and the controller is electrically connected with the first power device, the first stress sensor and the second stress sensor. The electronic information engineering communication tower connecting device can correct the communication tower in time when the communication tower slightly inclines due to foundation settlement, so that the communication tower is effectively prevented from further inclining and from collapsing due to serious inclination.

Description

Electronic information engineering communication tower connecting device

Technical Field

The invention relates to the technical field of communication equipment, in particular to a connecting device of an electronic information engineering communication tower.

Background

Modern communication engineering needs to construct a large number of communication towers for signal transmission, and the communication towers need to use connecting devices in the construction process so as to fix the communication towers on the ground.

The existing communication tower connecting device can not correct the communication tower in time when the foundation subsides to cause the weak inclination of the communication tower, thereby being incapable of avoiding the further inclination of the communication tower and further being incapable of avoiding the inclination and the collapse of the communication tower.

Disclosure of Invention

The invention aims to overcome the problems in the prior art and provides an electronic information engineering communication tower connecting device which can correct a communication tower in time when the communication tower slightly inclines due to foundation settlement, so that the communication tower is effectively prevented from further inclining and from collapsing due to serious inclination.

The invention provides a connecting device of an electronic information engineering communication tower, which comprises:

the top of the base is fixedly connected with the communication tower;

the box body is arranged on the lower side of the base;

the first height adjusting mechanism is connected with the box body bearing, is hinged with one side edge of the base and is connected with a first power device, and the first height adjusting mechanism is also provided with a first stress sensor;

one end of the first connecting rod is fixedly connected with the box body, the other end of the first connecting rod is hinged to one side edge of the base, which is far away from the first height adjusting mechanism, and a second stress sensor is arranged on the first connecting rod;

the concrete block is arranged in the ground, and the box body is fixedly connected with the concrete block through an anchor;

the controller is electrically connected with the first power device, the first stress sensor and the second stress sensor, the first stress sensor detects the stress borne by the first height adjusting mechanism in real time and transmits a stress value signal of the first height adjusting mechanism to the controller, the second stress sensor detects the stress borne by the first connecting rod in real time and transmits a stress value signal of the first connecting rod to the controller, the controller compares the stress value of the first height adjusting mechanism with the stress value of the first connecting rod, the controller controls the first power device to act in real time according to the comparison result, and the controller is electrically connected with a power supply device.

Preferably, the device also comprises a second height adjusting mechanism and a second connecting rod, the second height adjusting mechanism is connected with the box body bearing, the second height adjusting mechanism is hinged on one side edge of the base, which is not collinear with the first height adjusting mechanism and the first connecting rod, the second height adjusting mechanism is connected with a second power device, the second height adjusting mechanism is also provided with a third stress sensor, one end of the second connecting rod is fixedly connected with the box body, the other end of the second connecting rod is hinged on one side edge of the base, which is far away from the second height adjusting mechanism, the second connecting rod is provided with a fourth stress sensor, the controller is electrically connected with the second power device, the third stress sensor and the fourth stress sensor, the third stress sensor detects the stress borne by the second height adjusting mechanism in real time and transmits a stress value signal of the second height adjusting mechanism to the controller, the fourth stress sensor detects the stress borne by the second connecting rod in real time and transmits a stress value signal of the second connecting rod to the controller, the controller compares the stress value of the second height adjusting mechanism with the stress value of the second connecting rod, and the controller controls the second power device to act in real time according to the comparison result.

Preferably, first height adjustment mechanism and second height adjustment mechanism all include sleeve and lifter, the sleeve passes through the bearing with the box and is connected, and the sleeve inner wall is equipped with the transmission internal thread, lifter one end is equipped with the transmission external screw thread, and the lifter passes through transmission internal thread and sleeve threaded connection, and the lifter other end is articulated with the base, the sleeve outer wall is equipped with the teeth of a cogwheel, the teeth of a cogwheel and first power device or second power device toothing.

Preferably, a first sliding block is arranged between the first connecting rod and the base, a second sliding block is arranged between the second connecting rod and the base, a first sliding groove and a second sliding groove are formed in the base, the first connecting rod is connected with the first sliding block, the first sliding block is connected with the first sliding groove in a sliding mode, the second connecting rod is connected with the second sliding block, and the second sliding block is connected with the second sliding groove in a sliding mode.

Preferably, supports are arranged between the first height adjusting mechanism and the base, between the second height adjusting mechanism and the base, between the first connecting rod and the first slider, and between the second connecting rod and the second slider, the supports are provided with a first sliding hole and a second sliding hole, axes of the first sliding hole and the second sliding hole are perpendicular to each other, the supports are hinged with the base, the first slider or the second slider through the first sliding hole, and the supports are hinged with the first height adjusting mechanism, the second height adjusting mechanism, the first connecting rod or the second connecting rod through the second sliding hole.

Preferably, the first height adjusting mechanism and the first power device are in transmission through a worm and gear.

Preferably, the controller is also electrically connected with a display.

Compared with the prior art, the invention has the beneficial effects that: the electronic information engineering communication tower connecting device can correct the communication tower in time when the communication tower slightly inclines due to foundation settlement, so that the communication tower is effectively prevented from further inclining and from collapsing due to serious inclination. Including second height control mechanism and second connecting rod through the setting, the gesture of communication tower can be corrected to the omnidirectional. Through the transmission of transmission internal thread and transmission external screw thread, the screw thread transmission has great reduction ratio, consequently even there is rotation error in power device, under the effect of screw thread transmission's big reduction ratio, can greatly reduced error. Through setting up first slider and first spout, effectively prevent that the lifter from taking place the dead phenomenon of card when going up and down. The worm gear has a large reduction ratio, and can transmit large torque, so that the performance requirement of the first power device is reduced.

Drawings

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

FIG. 2 is a schematic cross-sectional view of the A-A plane of the present invention;

FIG. 3 is a schematic structural view of a first height adjustment mechanism and a second height adjustment mechanism of the present invention;

fig. 4 is a schematic structural view of the base of the present invention after being straightened.

Description of reference numerals:

101. the device comprises a base, 102, a communication tower, 103, a box body, 104, a first power device, 105, a first stress sensor, 106, a first connecting rod, 107, a second stress sensor, 108, a concrete block, 109, an anchor bolt, 110, a first height adjusting mechanism, 201, a second height adjusting mechanism, 202, a second power device, 203, a third stress sensor, 301, a sleeve, 302, a lifting rod, 303, a gear tooth, 401, a first sliding block, 402, a second sliding block, 403, a first sliding groove, 404, a second sliding groove and 5 a support.

Detailed Description

Detailed description of the preferred embodimentsthe following detailed description of the present invention will be given with reference to the accompanying drawings 1-4, but it should be understood that the scope of the present invention is not limited to the specific embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Example 1:

as shown in fig. 1, 2 and 4, the present invention provides an electronic information engineering communication tower connection device, including: the device comprises a base 101, a box body 103, a first height adjusting mechanism 110, a first connecting rod 106, a concrete block 108 and a controller, wherein the top of the base 101 is fixedly connected with a communication tower 102; the box body 103 is arranged at the lower side of the base 101; the first height adjusting mechanism 110 is in bearing connection with the box body 103, the first height adjusting mechanism 110 is hinged with one side edge of the base 101, the first height adjusting mechanism 110 is connected with the first power device 104, and the first height adjusting mechanism 110 is further provided with a first stress sensor 105; one end of a first connecting rod 106 is fixedly connected with the box body 103, the other end of the first connecting rod 106 is hinged to one side edge of the base 101, which is far away from the first height adjusting mechanism 110, and a second stress sensor 107 is arranged on the first connecting rod 106; the concrete block 108 is arranged in the ground, and the box body 103 is fixedly connected with the concrete block 108 through the anchor 109; the controller is electrically connected with the first power device 104, the first stress sensor 105 and the second stress sensor 107, the first stress sensor 105 detects the stress borne by the first height adjusting mechanism 110 in real time and transmits a stress value signal of the first height adjusting mechanism 110 to the controller, the second stress sensor 107 detects the stress borne by the first connecting rod 106 in real time and transmits a stress value signal of the first connecting rod 106 to the controller, the controller compares the stress value of the first height adjusting mechanism 110 with the stress value of the first connecting rod 106, the controller controls the first power device 104 to act in real time according to the comparison result, and the controller is electrically connected with a power supply device.

The working principle of example 1 is now briefly described:

after the installation of the device is completed, the communication tower 102 is erected. When the communication tower 102 is not tilted, the stress values detected by the first stress sensor 105 located on the first height adjustment mechanism 110 and the second stress sensor 107 located on the first connecting rod 106 are equal. When the foundation where the communication tower 102 is located is settled, so that the base 101 is inclined, and further the communication tower 102 is inclined, if the stress value detected by the first stress sensor 105 is greater than the stress value detected by the second stress sensor 107, it indicates that the pressure applied to the first height adjusting mechanism 110 is greater than the pressure applied to the first connecting rod 106, and it indicates that the communication tower 102 is inclined toward the side where the first height adjusting mechanism 110 is located, at this time, the controller controls the first power device 104 to rotate forward, and the first height adjusting mechanism 110 is lifted, because the length of the first connecting rod 106 is fixed, and the first connecting rod 106 is hinged to the base 101, the base 101 rotates forward, and until the pressure applied to the first height adjusting mechanism 110 is equal to the pressure applied to the first connecting rod 106, the controller controls the first power device 104 to be closed, so that the communication tower 102 is corrected. If the stress value detected by the first stress sensor 105 is smaller than the stress value detected by the second stress sensor 107, it indicates that the pressure applied to the first height adjusting mechanism 110 is smaller than the pressure applied to the first connecting rod 106, and indicates that the communication tower 102 inclines to the side where the first connecting rod 106 is located, at this time, the controller controls the first power device 104 to rotate reversely, the first height adjusting mechanism 110 rises and falls, and the communication tower 102 is corrected in the same manner.

The electronic information engineering communication tower connecting device can correct the communication tower 102 in time when the communication tower 102 slightly inclines due to foundation settlement, so that the communication tower 102 is effectively prevented from further inclining, and the communication tower 102 is prevented from collapsing due to serious inclination.

Example 2:

on the basis of embodiment 1, since the direction in which the communication tower 102 is inclined may be any direction, the posture of the communication tower 102 can be corrected in all directions.

As shown in fig. 1, 2 and 4, the system further comprises a second height adjusting mechanism 201 and a second connecting rod, the second height adjusting mechanism 201 is in bearing connection with the box body 103, the second height adjusting mechanism 201 is hinged to one side edge of the base 101, which is not collinear with the first height adjusting mechanism 110 and the first connecting rod 106, the second height adjusting mechanism 201 is connected with a second power device 202, the second height adjusting mechanism 201 is further provided with a third stress sensor 203, one end of the second connecting rod is fixedly connected with the box body 103, the other end of the second connecting rod is hinged to one side edge of the base 101, which is far away from the second height adjusting mechanism 201, the second connecting rod is provided with a fourth stress sensor, the controller is electrically connected with the second power device 202, the third stress sensor 203 and the fourth stress sensor, the third stress sensor 203 detects the stress applied to the second height adjusting mechanism 201 in real time and transmits a stress value signal of the second height adjusting mechanism 201 to the controller, the fourth stress sensor detects the stress borne by the second connecting rod in real time and transmits a stress value signal of the second connecting rod to the controller, the controller compares the stress value of the second height adjusting mechanism 201 with the stress value of the second connecting rod, and the controller controls the second power device 202 to act in real time according to the comparison result.

When the inclination direction of the communication tower 102 is not collinear with the first height adjusting mechanism 110 and the first connecting rod 106, the component of the inclination amount of the communication tower 102 along the collinear direction of the second height adjusting mechanism 201 and the second connecting rod is adjusted by the lifting of the second height adjusting mechanism 201, and therefore, even if the inclination direction of the communication tower 102 is not collinear with the first height adjusting mechanism 110 and the first connecting rod 106, the communication tower 102 can be effectively corrected, and the posture of the communication tower 102 can be corrected in all directions.

Example 3:

in addition to embodiment 2, the elevating amount of the first height adjusting mechanism 110 and the second height adjusting mechanism 201 can be accurately controlled.

As shown in fig. 3, each of the first height adjusting mechanism 110 and the second height adjusting mechanism 201 includes a sleeve 301 and a lifting rod 302, the sleeve 301 is connected to the box 103 through a bearing, a transmission internal thread is disposed on an inner wall of the sleeve 301, a transmission external thread is disposed at one end of the lifting rod 302, the lifting rod 302 is in threaded connection with the sleeve 301 through the transmission internal thread, the other end of the lifting rod 302 is hinged to the base 101, gear teeth 303 are disposed on an outer wall of the sleeve 301, and the gear teeth 303 are in toothed connection with the first power device 104 or the second power device 202.

The sleeve 301 is driven to rotate by the first power device 104 or the second power device 202, the lifting rod 302 and the sleeve 301 rotate relatively, and as the lifting rod 302 and the sleeve 301 are connected through threads, the lifting rod 302 is lifted or lowered under the drive of the threads, so that the hinged side of the base 101 and the lifting rod 302 is driven to be lifted or lowered. Because lifter 302 and sleeve 301 carry out the transmission through transmission internal thread and transmission external screw thread, screw thread transmission has great reduction ratio, consequently even power device has rotation error, under the effect of screw thread transmission's big reduction ratio, can greatly reduced error.

Example 4:

in addition to embodiment 3, the occurrence of the seizing phenomenon is prevented when the susceptor 101 is corrected.

As shown in fig. 2, a first slider 401 is disposed between the first connecting rod 106 and the base 101, a second slider 402 is disposed between the second connecting rod and the base 101, a first sliding slot 403 and a second sliding slot 404 are disposed on the base 101, the first connecting rod 106 is connected to the first slider 401, the first slider 401 is slidably connected to the first sliding slot 403, the second connecting rod is connected to the second slider 402, and the second slider 402 is slidably connected to the second sliding slot 404.

When the first height adjusting mechanism 110 is used for leveling and returning the base 101, the lifting rod 302 rises or falls, so that the horizontal distances between the connecting end of the lifting rod 302 and the base 101 and between the connecting end of the first connecting rod 106 and the base 101 change, therefore, by arranging the first slider 401 and the first sliding groove 403, when the horizontal distances between the connecting end of the lifting rod 302 and the base 101 and between the connecting end of the first connecting rod 106 and the base 101 change, the first slider 401 connected with the first connecting rod 106 can slide in the first sliding groove 403, thereby effectively preventing the lifting rod 302 from being stuck during lifting, and similarly, when the second height adjusting mechanism 201 is used for leveling and returning the base 101.

Example 5:

in addition to embodiment 4, in order to prevent the second height adjustment mechanism 201 and the second link lever from obstructing the rotation of the base 101 when the base 101 is levelly returned by the first height adjustment mechanism 110, or to prevent the first height adjustment mechanism 110 and the first link lever 106 from obstructing the rotation of the base 101 when the base 101 is levelly returned by the second height adjustment mechanism 201.

As shown in fig. 1, 3 and 4, the support 5 is disposed between the first height adjusting mechanism 110 and the base 101, between the second height adjusting mechanism 201 and the base 101, between the first connecting rod 106 and the first slider 401, and between the second connecting rod and the second slider 402, the support 5 is provided with a first sliding hole and a second sliding hole, axes of the first sliding hole and the second sliding hole are perpendicular to each other, the support 5 is hinged to the base 101, the first slider 401, or the second slider 402 through the first sliding hole, and the support 5 is hinged to the first height adjusting mechanism 110, the second height adjusting mechanism 201, the first connecting rod 106, or the second connecting rod through the second sliding hole.

When the base 101 is leveled and returned by using the first height adjusting mechanism 110, by arranging the support 5 between the second height adjusting mechanism 201 and the base 101 and between the second connecting rod and the second slider 402, since the axes of the first sliding hole and the second sliding hole of the support 5 are perpendicular to each other, the support 5 is hinged to the base 101 or the second slider 402 through the first sliding hole, and the support 5 is hinged to the second height adjusting mechanism 201 or the second connecting rod through the second sliding hole, when the first height adjusting mechanism 110 lifts one side of the base 101, the base 101 can rotate around the axes of the support 5 hinged to the second height adjusting mechanism 201 and the second sliding hole of the support 5 hinged to the second connecting rod, thereby preventing the second height adjusting mechanism 201 and the second connecting rod from hinging and blocking the rotation of the base 101. The same applies to leveling and returning the base 101 by the second height adjustment mechanism 201. By providing the support 5, it is possible to prevent the second height adjustment mechanism 201 and the second connecting rod from obstructing the rotation of the base 101 when the base 101 is leveled and returned by the first height adjustment mechanism 110, or to prevent the first height adjustment mechanism 110 and the first connecting rod 106 from obstructing the rotation of the base 101 when the base 101 is leveled and returned by the second height adjustment mechanism 201.

As shown in fig. 1, 3 and 4, it is preferable that the first height adjusting mechanism 110 and the first power device 104 are driven by a worm gear. The worm gear has a large reduction ratio and can transmit a large torque, thereby reducing the performance requirements of the first power device 104.

Preferably, the controller is electrically connected with a display. After the device is installed, the concrete block 108 is embedded into the ground, a vertical downward force is applied to the base 101 of the device, the real-time stress values of the first stress sensor 105 and the second stress sensor 107 are observed through the display, so that the pressure values of the first height adjusting mechanism 110 and the first connecting rod 106 are known, when the pressure values of the first height adjusting mechanism 110 and the first connecting rod 106 are not equal, the concrete block 108 is not placed in balance, and the posture of the concrete block 108 is adjusted so that the concrete block 108 is placed flat, so that the problem that the communication tower 102 is inclined due to the fact that the concrete is not placed flat is effectively solved.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. An electronic information engineering communication tower connecting device, comprising:

the top of the base (101) is fixedly connected with a communication tower (102);

a box body (103) arranged below the base (101);

the first height adjusting mechanism (110) is connected with the box body (103) through a bearing, the first height adjusting mechanism (110) is hinged to one side edge of the base (101), the first height adjusting mechanism (110) is connected with a first power device (104), and the first height adjusting mechanism (110) is further provided with a first stress sensor (105);

one end of a first connecting rod (106) is fixedly connected with the box body (103), the other end of the first connecting rod (106) is hinged to the edge of one side of the base (101) far away from the first height adjusting mechanism (110), and a second stress sensor (107) is arranged on the first connecting rod (106);

the concrete block (108) is arranged in the ground, and the box body (103) is fixedly connected with the concrete block (108) through an anchor (109);

the controller is electrically connected with the first power device (104), the first stress sensor (105) and the second stress sensor (107), the first stress sensor (105) detects the stress borne by the first height adjusting mechanism (110) in real time and transmits a stress value signal of the first height adjusting mechanism (110) to the controller, the second stress sensor (107) detects the stress borne by the first connecting rod (106) in real time and transmits a stress value signal of the first connecting rod (106) to the controller, the controller compares the stress value of the first height adjusting mechanism (110) with the stress value of the first connecting rod (106), the controller controls the first power device (104) to act in real time according to a comparison result, and the controller is electrically connected with a power supply device.

2. The electronic information engineering communication tower connecting device as claimed in claim 1, further comprising a second height adjusting mechanism (201) and a second connecting rod, wherein the second height adjusting mechanism (201) is in bearing connection with the box body (103), the second height adjusting mechanism (201) is hinged to a side edge of the base (101) which is not collinear with the first height adjusting mechanism (110) and the first connecting rod (106), the second height adjusting mechanism (201) is connected with a second power device (202), the second height adjusting mechanism (201) is further provided with a third stress sensor (203), one end of the second connecting rod is fixedly connected with the box body (103), the other end of the second connecting rod is hinged to a side edge of the base (101) which is far away from the second height adjusting mechanism (201), a fourth stress sensor is arranged on the second connecting rod, and the controller is connected with the second power device (202), The third stress sensor (203) and the fourth stress sensor are electrically connected, the third stress sensor (203) detects the stress borne by the second height adjusting mechanism (201) in real time and transmits a stress value signal of the second height adjusting mechanism (201) to the controller, the fourth stress sensor detects the stress borne by the second connecting rod in real time and transmits a stress value signal of the second connecting rod to the controller, the controller compares the stress value of the second height adjusting mechanism (201) with the stress value of the second connecting rod, and the controller controls the second power device (202) to act in real time according to the comparison result.

3. The electronic information engineering communication tower connecting device as claimed in claim 2, wherein the first height adjusting mechanism (110) and the second height adjusting mechanism (201) each comprise a sleeve (301) and a lifting rod (302), the sleeve (301) is connected with the box body (103) through a bearing, a transmission internal thread is arranged on the inner wall of the sleeve (301), a transmission external thread is arranged at one end of the lifting rod (302), the lifting rod (302) is in threaded connection with the sleeve (301) through the transmission internal thread, the other end of the lifting rod (302) is hinged to the base (101), gear teeth (303) are arranged on the outer wall of the sleeve (301), and the gear teeth (303) are in toothed connection with the first power device (104) or the second power device (202).

4. The communication tower connection device for electronic information engineering according to claim 3, wherein a first sliding block (401) is disposed between the first connecting rod (106) and the base (101), a second sliding block (402) is disposed between the second connecting rod and the base (101), a first sliding slot (403) and a second sliding slot (404) are disposed on the base (101), the first connecting rod (106) is connected to the first sliding block (401), the first sliding block (401) is slidably connected to the first sliding slot (403), the second connecting rod is connected to the second sliding block (402), and the second sliding block (402) is slidably connected to the second sliding slot (404).

5. The electronic information engineering communication tower connecting device according to claim 2, wherein a support (5) is disposed between the first height adjusting mechanism (110) and the base (101), between the second height adjusting mechanism (201) and the base (101), between the first connecting rod (106) and the first slider (401), and between the second connecting rod and the second slider (402), the support (5) is provided with a first sliding hole and a second sliding hole, axes of the first sliding hole and the second sliding hole are perpendicular to each other, the support (5) is hinged to the base (101), the first slider (401) or the second slider (402) through the first sliding hole, and the support (5) is hinged to the first height adjusting mechanism (110), the second height adjusting mechanism (201), the first connecting rod (106) or the second connecting rod through the second sliding hole.

6. An electronic information engineering communication tower attachment as claimed in claim 1, wherein said first height adjustment mechanism (110) is worm-geared with said first power means (104).

7. The electrical information engineering communication tower attachment of claim 1 wherein said controller is further electrically connected to a display.