CN216690119U - Floor tower with anti-seismic function - Google Patents
Floor tower with anti-seismic function Download PDFInfo
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- CN216690119U CN216690119U CN202122641006.5U CN202122641006U CN216690119U CN 216690119 U CN216690119 U CN 216690119U CN 202122641006 U CN202122641006 U CN 202122641006U CN 216690119 U CN216690119 U CN 216690119U
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Abstract
The utility model discloses a floor tower with an anti-seismic function, which comprises a roof, a wind power measuring instrument, a single chip microcomputer, a telescopic communication tower body and a fixing mechanism for fixing the communication tower body, wherein the telescopic communication tower body is fixed with the roof through the fixing mechanism, the wind power measuring instrument is arranged at the top of the telescopic communication tower body and used for measuring a wind power signal and transmitting the wind power signal to the single chip microcomputer, and the single chip microcomputer controls the telescopic communication tower body to reduce the height, so that the situation that the roof is damaged by vibration between the communication tower body and the roof due to overlarge wind power is avoided. The communication tower body is driven by the first telescopic mechanism, the second telescopic mechanism and the third telescopic mechanism to reduce the height, so that the wind power effect is reduced, the communication tower body is prevented from swinging left and right under the action of strong wind when being overhigh, the safety accident caused by vibration and looseness between the communication tower body and a roof is prevented, the communication tower body can be controlled to reduce the height for overhauling during overhauling, and the accident caused by falling when a worker climbs the tower for overhauling is avoided.
Description
Technical Field
The utility model relates to the technical field of floor towers, in particular to a floor tower with an anti-seismic function.
Background
Along with the rapid development of economy and rapid progress of science and technology in China, communication tower equipment is widely applied to multiple industries, belongs to one type of signal transmitting tower, is also called a signal transmitting tower or a signal tower, mainly supports signal transmission, provides great convenience for life of people, and is usually built on a roof to facilitate signal transmission and reception, wherein the common signal tower is a steel structure, and a signal receiver is arranged at the top of the common signal tower.
When the communication signal tower is used, when the tower body is acted by external strong wind, the tower body can incline or even collapse with the roof due to vibration, at the moment, accidents can be caused, the life safety of civilian is threatened, and meanwhile, the safety of workers during maintenance can not be guaranteed.
SUMMERY OF THE UTILITY MODEL
The present invention is directed to solving the above problems and providing a floor tower having an earthquake-resistant function.
The utility model achieves the above purpose through the following technical scheme:
the utility model provides a floor tower with antidetonation function, includes roof, wind-force measuring instrument, singlechip, flexible communication tower body and the fixed establishment of fixed communication tower body, flexible communication tower body passes through fixed establishment and roof fixed, wind-force measuring instrument installs in the top of flexible communication tower body for measure wind-force signal and transmit the singlechip, singlechip control flexible communication tower body reduces the height, avoids too big vibrations between communication tower body and roof of causing of wind-force to damage the roof surface.
Preferably, the communication tower body comprises a supporting rod, a first telescopic mechanism, a second telescopic mechanism and a third telescopic mechanism, one end of the supporting rod is fixed with the roof through a fixing mechanism, and the other end of the supporting rod is sequentially connected with the third telescopic mechanism, the second telescopic mechanism and the first telescopic mechanism and used for reducing the height of the telescopic communication tower body.
Preferably, the first telescopic mechanism comprises a first antenna, a first telescopic rod, a first sleeve, a first telescopic motor and a first telescopic shaft, the first telescopic motor is arranged at the bottom in the hollow structure of the first sleeve, the first telescopic motor is connected with one end of the first telescopic rod through the first telescopic shaft, the first telescopic motor drives the first telescopic rod to slide in the first sleeve through the first telescopic shaft, the other end of the first telescopic rod is connected with the wind power measuring instrument, and the outer wall of the first sleeve is provided with the first antenna.
Preferably, the second telescopic mechanism comprises a second antenna, a second telescopic rod, a second sleeve, a second telescopic motor and a second telescopic shaft, the second telescopic motor is arranged at the bottom in the hollow structure of the second sleeve, the second telescopic motor is connected with one end of the second telescopic rod through the second telescopic shaft, the second telescopic motor drives the second telescopic rod to slide in the second sleeve through the second telescopic shaft, the other end of the second telescopic rod is connected with the bottom of the first sleeve, and the outer wall of the second sleeve is provided with the second antenna.
Preferably, the third telescopic mechanism comprises a third antenna, a third telescopic rod, a third sleeve, a third telescopic motor and a third telescopic shaft, the third telescopic motor is arranged at the bottom in the hollow structure of the third sleeve, the third telescopic motor is connected with one end of the third telescopic rod through the third telescopic shaft, the third telescopic motor drives the third telescopic rod to slide in the third sleeve through the third telescopic shaft, the other end of the third telescopic rod is connected with the bottom of the second sleeve, the bottom of the third sleeve is connected with the supporting rod, and the outer wall of the third sleeve is provided with the third antenna.
Preferably, the fixing mechanism comprises a fixing component and a reinforcing component, the supporting rod is fixed with the roof through the fixing component, and the stability of the supporting rod and the roof is reinforced through the reinforcing component.
Preferably, the fixing assembly comprises a fixing piece and a bolt, one end of the fixing piece is connected with the bottom of the supporting rod, and the fixing piece is fixed with the roof through the bolt.
Preferably, the fixing piece is of a convex structure and is embedded in the roof cement cast-in-place, nuts are embedded below two ends of the fixing piece, and two ends of the fixing piece are embedded in the roof after being in threaded connection with the nuts through bolts.
Preferably, the reinforcing assembly comprises a first reinforcing rod, a second reinforcing rod and a third reinforcing rod, one end of the first reinforcing rod is connected with the supporting rod, the other end of the first reinforcing rod is respectively connected with one end of the second reinforcing rod and one end of the third reinforcing rod, the other end of the second reinforcing rod is connected with the connecting position of the supporting rod and the fixing piece, the other end of the third reinforcing rod is fixed with the roof to form two groups of triangular structures, and the stability of the supporting rod and the roof is enhanced.
Preferably, the wind power measuring instrument is connected with the first telescopic rod through a measuring instrument seat.
The utility model has the beneficial effects that:
the communication tower body is driven by the first telescopic mechanism, the second telescopic mechanism and the third telescopic mechanism to reduce the height, so that the wind force effect is reduced, the communication tower body is prevented from swinging left and right under the action of strong wind when being overhigh, the safety accident caused by vibration and looseness between the communication tower body and a roof is prevented, the communication tower body can be controlled to reduce the height for overhauling during overhauling, and the accident caused by falling when a worker climbs the tower for overhauling is avoided; the utility model has the advantages of simple structure, stable performance and longer service life.
Drawings
FIG. 1 is a schematic view of an unfolded structure of a tower with earthquake-resistant features according to the present invention;
FIG. 2 is a schematic view of a retracted configuration of a seismic tower according to the present invention;
fig. 3 is a schematic structural diagram of a system of a ground tower with an earthquake-proof function according to the utility model.
Detailed Description
The utility model is further described below with reference to the accompanying drawings:
as shown in fig. 1-3: the utility model provides a floor tower with antidetonation function, including roof 8, wind-force measuring apparatu 11, the singlechip, the fixed establishment of flexible communication tower body and fixed communication tower body, flexible communication tower body passes through fixed establishment and roof 8 is fixed, wind-force measuring apparatu 11 is installed in the top of flexible communication tower body for measure wind-force signal and transmit the singlechip, the flexible communication tower body of single chip microcomputer control reduces height, avoid wind-force too big to cause vibrations between communication tower body and the roof 11 to damage the roof face.
As shown in fig. 1 and 2, the communication tower body comprises a support rod 5, a first telescopic mechanism, a second telescopic mechanism and a third telescopic mechanism, one end of the support rod 5 is fixed with a roof 8 through a fixing mechanism, and the other end of the support rod 5 is sequentially connected with the third telescopic mechanism, the second telescopic mechanism and the first telescopic mechanism for reducing the height of the telescopic communication tower body.
As shown in fig. 1 and fig. 2, the first telescopic mechanism includes a first antenna 21, a first telescopic rod 22, a first sleeve 25, a first telescopic motor 24 and a first telescopic shaft 23, the first telescopic motor 24 is disposed at the bottom of the hollow structure of the first sleeve 25, the first telescopic motor 24 is connected with one end of the first telescopic rod 22 through the first telescopic shaft 23, the first telescopic motor 24 drives the first telescopic rod 22 to slide in the first sleeve 25 through the first telescopic shaft 23, the other end of the first telescopic rod 22 is connected with the wind power measuring instrument 11, and the outer wall of the first sleeve 25 is provided with the first antenna 21.
As shown in fig. 1 and fig. 2, the second telescopic mechanism includes a second antenna 31, a second telescopic rod 32, a second sleeve 35, a second telescopic motor 34 and a second telescopic shaft 33, the second telescopic motor 34 is disposed at the bottom of the hollow structure of the second sleeve 35, the second telescopic motor 34 is connected with one end of the second telescopic rod 32 through the second telescopic shaft 33, the second telescopic motor 34 drives the second telescopic rod 32 to slide in the second sleeve 35 through the second telescopic shaft 33, the other end of the second telescopic rod 32 is connected with the bottom of the first sleeve 25, and the second antenna 31 is disposed on the outer wall of the second sleeve 35.
As shown in fig. 1 and fig. 2, the third telescopic mechanism includes a third antenna 41, a third telescopic rod 42, a third sleeve 45, a third telescopic motor 44 and a third telescopic shaft 43, the third telescopic motor 44 is disposed at the bottom of the hollow structure of the third sleeve 45, the third telescopic motor 44 is connected with one end of the third telescopic rod 42 through the third telescopic shaft 43, the third telescopic motor 44 drives the third telescopic rod 42 to slide in the third sleeve 45 through the third telescopic shaft 43, the other end of the third telescopic rod 42 is connected with the bottom of the second sleeve 35, the bottom of the third sleeve 45 is connected with the supporting rod 5, and the outer wall of the third sleeve 45 is provided with the third antenna 41.
As shown in fig. 1 and 2, the fixing mechanism includes a fixing assembly and a reinforcing assembly, the support rod 5 is fixed with the roof through the fixing assembly, and the stability of the support rod with the roof 8 is reinforced through the reinforcing assembly.
As shown in fig. 1 and 2, the fixing assembly includes a fixing member 7 and a bolt 92, one end of the fixing member 7 is connected to the bottom of the support rod 5, and the fixing member 7 is fixed to the roof 8 by the bolt 92.
As shown in fig. 1 and 2, the fixing member 7 is of a "convex" structure and is embedded in the roof 8 in a cement cast-in-place manner, nuts 91 are embedded below two ends of the fixing member 7, and two ends of the fixing member 7 are embedded in the roof 8 after being connected with the nuts 91 through bolts 92 and threads 93.
As shown in fig. 1 and 2, the reinforcing component comprises a first reinforcing rod 61, a second reinforcing rod 62 and a third reinforcing rod 63, one end of the first reinforcing rod 61 is connected with the supporting rod 5, the other end of the first reinforcing rod is respectively connected with one end of the second reinforcing rod 62 and one end of the third reinforcing rod 63, the other end of the second reinforcing rod 62 is connected with the connecting position of the supporting rod 5 and the fixing part 7, the other end of the third reinforcing rod 63 is fixed with the roof 8, two groups of triangular structures are formed, and the stability of the supporting rod 5 and the roof 8 is enhanced.
As shown in fig. 1-3, the wind power measuring instrument 11 is connected to the first telescopic rod 22 through a measuring instrument base 12, wherein the model of the single chip microcomputer is 1215C.
The working principle of the utility model is as follows:
as shown in fig. 1-3, in the using process, the wind power measuring instrument 11 measures an air wind power value, when the wind power is greater than or equal to a predetermined wind power value, the wind power measuring instrument 11 sends a signal to the single chip, the single chip controls the first telescopic motor 24, the second telescopic motor 34, and the third telescopic motor 44 to work, the first telescopic motor 24 drives the first telescopic rod 22 to slide downward in the first sleeve 25 through the first telescopic shaft 23 to reduce the distance between the first antenna 21 and the second antenna 31 to a minimum value, the second telescopic motor 34 drives the second telescopic rod 32 to slide downward in the second sleeve 35 through the second telescopic shaft 33 to reduce the distance between the second antenna 31 and the third antenna 41 to a minimum value, the third telescopic motor 44 drives the third telescopic rod 42 to slide downward in the third sleeve 45 through the third telescopic shaft 43 to reduce the distance between the third antenna 41 and the roof 8 to a minimum value, the communication tower body is prevented from swinging left and right under the action of strong wind when being too high, so that the communication tower body and the roof 8 are vibrated and loosened to cause safety accidents, when the wind power measuring instrument 11 measures an air power value which is smaller than a preset wind power value, the wind power measuring instrument 11 sends a signal to the single chip microcomputer, and the single chip microcomputer controls the first telescopic motor 24, the second telescopic motor 34 and the third telescopic motor 44 to work to expand the telescopic communication tower body.
On the other hand, when the communication tower body is overhauled manually, the communication tower body can be controlled to reduce the height through the control single chip microcomputer, and the falling accidents are prevented when the working personnel climb the tower for maintenance.
In conclusion, the communication tower body is driven by the first telescopic mechanism, the second telescopic mechanism and the third telescopic mechanism to reduce the height, so that the wind force effect is reduced, the communication tower body is prevented from swinging left and right under the action of strong wind when being overhigh, the communication tower body and the roof are prevented from vibrating and loosening to cause safety accidents, the communication tower body can be controlled to reduce the height for overhauling during overhauling, and the falling accidents are prevented from happening when workers climb the tower for overhauling; the utility model has the advantages of simple structure, stable performance and longer service life.
As will be apparent to those skilled in the art, many modifications can be made to the utility model without departing from the spirit and scope thereof, and it is intended that the present invention cover all modifications and equivalents of the embodiments of the utility model covered by the appended claims.
Claims (10)
1. The utility model provides a floor tower with antidetonation function, its characterized in that, includes roof, wind-force measuring instrument, singlechip, flexible communication tower body and the fixed establishment of fixed communication tower body, flexible communication tower body passes through fixed establishment and roof fixed, wind-force measuring instrument installs in the top of flexible communication tower body for measure wind-force signal and transmit the singlechip, singlechip control flexible communication tower body reduces height, avoids too big vibrations between communication tower body and roof to damage the roof face of wind-force.
2. The floor tower with an earthquake-resistant function according to claim 1, wherein the communication tower body comprises a support rod, a first telescopic mechanism, a second telescopic mechanism and a third telescopic mechanism, one end of the support rod is fixed with a roof through a fixing mechanism, and the other end of the support rod is sequentially connected with the third telescopic mechanism, the second telescopic mechanism and the first telescopic mechanism and used for reducing the height of the telescopic communication tower body.
3. The floor tower with an earthquake-proof function according to claim 2, wherein the first telescopic mechanism comprises a first antenna, a first telescopic rod, a first sleeve, a first telescopic motor and a first telescopic shaft, the first telescopic motor is arranged at the bottom in the hollow structure of the first sleeve, the first telescopic motor is connected with one end of the first telescopic rod through the first telescopic shaft, the first telescopic motor drives the first telescopic rod to slide in the first sleeve through the first telescopic shaft, the other end of the first telescopic rod is connected with the wind power measuring instrument, and the first antenna is arranged on the outer wall of the first sleeve.
4. The floor tower with an earthquake-proof function according to claim 3, wherein the second telescopic mechanism comprises a second antenna, a second telescopic rod, a second sleeve, a second telescopic motor and a second telescopic shaft, the second telescopic motor is arranged at the bottom in the hollow structure of the second sleeve, the second telescopic motor is connected with one end of the second telescopic rod through the second telescopic shaft, the second telescopic motor drives the second telescopic rod to slide in the second sleeve through the second telescopic shaft, the other end of the second telescopic rod is connected with the bottom of the first sleeve, and the second antenna is arranged on the outer wall of the second sleeve.
5. The floor tower with the earthquake-resistant function according to claim 4, wherein the third telescopic mechanism comprises a third antenna, a third telescopic rod, a third sleeve, a third telescopic motor and a third telescopic shaft, the third telescopic motor is arranged at the bottom in the hollow structure of the third sleeve, the third telescopic motor is connected with one end of the third telescopic rod through the third telescopic shaft, the third telescopic motor drives the third telescopic rod to slide in the third sleeve through the third telescopic shaft, the other end of the third telescopic rod is connected with the bottom of the second sleeve, the bottom of the third sleeve is connected with the supporting rod, and the outer wall of the third sleeve is provided with the third antenna.
6. An earthquake-resistant ground tower according to claim 2, characterized in that the fixing means comprise fixing elements and reinforcing elements, the supporting rods being fixed to the roof by means of the fixing elements and the stability of the supporting rods to the roof being reinforced by means of the reinforcing elements.
7. An earthquake-resistant floor tower according to claim 6, wherein the fixing assembly comprises a fixing member and a bolt, one end of the fixing member is connected with the bottom of the supporting rod, and the fixing member is fixed with the roof through the bolt.
8. The floor tower with the earthquake-resistant function as claimed in claim 7, wherein the fixing member is of a convex structure and is embedded in a roof cement cast-in-place structure, nuts are embedded below two ends of the fixing member, and two ends of the fixing member are embedded in the roof after being in threaded connection with the nuts through bolts.
9. An earthquake-resistant floor tower according to claim 8, wherein the reinforcing component comprises a first reinforcing rod, a second reinforcing rod and a third reinforcing rod, one end of the first reinforcing rod is connected with the supporting rod, the other end of the first reinforcing rod is respectively connected with one end of the second reinforcing rod and one end of the third reinforcing rod, the other end of the second reinforcing rod is connected with the connecting position of the supporting rod and the fixing part, the other end of the third reinforcing rod is fixed with the roof to form two groups of triangular structures, and the stability of the supporting rod and the roof is enhanced.
10. An earthquake-resistant floor tower according to claim 3, wherein the wind power measuring instrument is connected with the first telescopic rod through a measuring instrument base.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202122641006.5U CN216690119U (en) | 2021-11-01 | 2021-11-01 | Floor tower with anti-seismic function |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202122641006.5U CN216690119U (en) | 2021-11-01 | 2021-11-01 | Floor tower with anti-seismic function |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN216690119U true CN216690119U (en) | 2022-06-07 |
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ID=81829343
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202122641006.5U Active CN216690119U (en) | 2021-11-01 | 2021-11-01 | Floor tower with anti-seismic function |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN216690119U (en) |
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2021
- 2021-11-01 CN CN202122641006.5U patent/CN216690119U/en active Active
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| Date | Code | Title | Description |
|---|---|---|---|
| GR01 | Patent grant | ||
| GR01 | Patent grant | ||
| CP01 | Change in the name or title of a patent holder |
Address after: 710061 Xi'an innovation design center, No. 69, west section of South Second Ring Road, Beilin District, Xi'an City, Shaanxi Province 1519 Patentee after: Zhongta Construction Technology Co.,Ltd. Address before: 710061 Xi'an innovation design center, No. 69, west section of South Second Ring Road, Beilin District, Xi'an City, Shaanxi Province 1519 Patentee before: Shaanxi Zhongta Construction Technology Co.,Ltd. |
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| CP01 | Change in the name or title of a patent holder |