CN113390331B - Portable integrated GNSS deformation monitoring pier - Google Patents
Portable integrated GNSS deformation monitoring pier Download PDFInfo
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- CN113390331B CN113390331B CN202110496564.9A CN202110496564A CN113390331B CN 113390331 B CN113390331 B CN 113390331B CN 202110496564 A CN202110496564 A CN 202110496564A CN 113390331 B CN113390331 B CN 113390331B
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- 238000012544 monitoring process Methods 0.000 title claims abstract description 126
- 238000004891 communication Methods 0.000 claims description 28
- 210000001503 joint Anatomy 0.000 claims description 20
- 230000001681 protective effect Effects 0.000 claims description 9
- 238000013461 design Methods 0.000 abstract description 3
- 239000000203 mixture Substances 0.000 description 7
- 238000005516 engineering process Methods 0.000 description 3
- 239000002184 metal Substances 0.000 description 3
- 238000004519 manufacturing process Methods 0.000 description 2
- 239000004033 plastic Substances 0.000 description 2
- 235000017166 Bambusa arundinacea Nutrition 0.000 description 1
- 235000017491 Bambusa tulda Nutrition 0.000 description 1
- 241001330002 Bambuseae Species 0.000 description 1
- 235000015334 Phyllostachys viridis Nutrition 0.000 description 1
- 238000004026 adhesive bonding Methods 0.000 description 1
- 239000011425 bamboo Substances 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
- 238000003032 molecular docking Methods 0.000 description 1
- 238000007789 sealing Methods 0.000 description 1
- 238000003466 welding Methods 0.000 description 1
Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B7/00—Measuring arrangements characterised by the use of electric or magnetic techniques
- G01B7/16—Measuring arrangements characterised by the use of electric or magnetic techniques for measuring the deformation in a solid, e.g. by resistance strain gauge
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S19/00—Satellite radio beacon positioning systems; Determining position, velocity or attitude using signals transmitted by such systems
- G01S19/01—Satellite radio beacon positioning systems transmitting time-stamped messages, e.g. GPS [Global Positioning System], GLONASS [Global Orbiting Navigation Satellite System] or GALILEO
- G01S19/13—Receivers
- G01S19/14—Receivers specially adapted for specific applications
Landscapes
- Engineering & Computer Science (AREA)
- Radar, Positioning & Navigation (AREA)
- Remote Sensing (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Computer Networks & Wireless Communication (AREA)
- Bridges Or Land Bridges (AREA)
Abstract
The invention provides a portable integrated GNSS deformation monitoring pier, which comprises a monitoring pier body and a GNSS monitoring module, wherein the GNSS monitoring module can be installed on the monitoring pier body; the monitoring pier body comprises a mounting pier, and a mounting panel which can be mounted at the upper end of the mounting pier; the mounting pier is of an assembled structure and comprises a mounting bottom plate, a height adjusting piece and a mounting body; the mounting panel comprises a panel body which can be clamped at the upper end of the mounting body, and a mounting rod which can be movably mounted on the panel body; the invention has reasonable overall structure design, is convenient for assembly and disassembly, can be transported separately, and effectively reduces the trouble caused by volume and weight; the problem that the integrated GNSS deformation monitoring pier is not easy to carry can be effectively solved by utilizing the mounting pier of the assembled structure, and the integrated GNSS deformation monitoring pier is more suitable for mounting the regions where the human track is rare.
Description
Technical Field
The invention relates to the technical field of GNSS monitoring equipment, in particular to a portable integrated GNSS deformation monitoring pier.
Background
The satellite navigation positioning technology has basically replaced the ground-based radio navigation, traditional geodetic and astronomical measurement navigation positioning technology at present, and has promoted the brand new development in the field of geodetic and navigation positioning. Today, GNSS systems are not only national security and economic infrastructure, but are also important markers embodying the status of the modernized nations and the comprehensive national power of the countries. Because of its important significance in politics, economy, military, etc., major military nations and economies of the world are competing to develop independent autonomous satellite navigation systems.
The monitoring pier is a metal pillar formed by welding metal pipes and is mainly used as a carrier of a GNSS terminal, and is generally used as one of main integrated equipment of a data acquisition terminal during GNSS deformation monitoring. However, since the main objects of deformation monitoring, such as landslide, dam, etc., are mostly located in mountain areas, and are affected by traffic conditions, equipment size, etc., the transportation of the equipment has always become a big pain point in implementation of GNSS deformation monitoring technology. At present, many areas are affected by environment, no power, no communication, no traffic and no living supply exist, and the implementation of dam monitoring projects faces great difficulties.
Therefore, the design and implementation of the portable integrated GNSS deformation monitoring pier are significant.
Disclosure of Invention
In view of the above-mentioned problems, the present invention provides a portable integrated GNSS deformation monitoring pier.
The technical scheme of the invention is as follows: a portable integrated GNSS deformation monitoring pier comprises a monitoring pier body, and a GNSS monitoring module which can be installed on the monitoring pier body; the monitoring pier body comprises a mounting pier, and a mounting panel which can be mounted at the upper end of the mounting pier; the GNSS monitoring module comprises a monitoring module body, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body, a network cable assembly used for connecting the monitoring module body and the communication module, and a power supply line assembly used for connecting the monitoring module body and the power module;
The mounting pier is of an assembled structure, and particularly comprises a mounting bottom plate, a height adjusting piece which can be mounted on the mounting bottom plate, and a mounting body which can be mounted at the upper end of the height adjusting piece and is used for mounting a mounting panel;
The mounting panel comprises a panel body which can be clamped at the upper end of the mounting body, and a mounting rod which can be movably mounted on the panel body;
The monitoring module body comprises a GNSS receiver which can be installed on a mounting rod, and an antenna network bridge which can be installed on the height adjusting piece and is connected with the GNSS receiver;
The panel body is provided with a through hole through which the net wire component and the power supply wire component can pass.
Further, the height adjusting piece adopts a first assembled height adjusting piece; the first assembly type height adjusting piece comprises a first adjusting cylinder capable of being movably mounted on the mounting base plate through a mounting foot seat, and a first mounting cylinder capable of being movably mounted on the first adjusting cylinder;
The first adjusting cylinder comprises a plurality of adjusting support cylinders with the same structure;
the bottom of the inner wall of the adjusting support cylinder and the bottom of the inner wall of the first mounting cylinder are respectively provided with a mounting notch, and the top of the adjusting support cylinder is provided with a butt joint ring; the first adjusting cylinders and the first adjusting cylinders are movably connected with each other through the mounting notch and the butt joint ring, and the joints of the mounting notch and the butt joint ring are fastened through bolts;
the top end of the inner wall of the first mounting cylinder is provided with a clamping groove for clamping the panel body; the height can be selected according to the actual environment, and the number of the supporting cylinders can be selected and adjusted according to the height; the whole equipment can be disassembled and assembled, so that the equipment can be transported more conveniently in actual use.
Further, 3 to 6 mounting foot seats are arranged, one end of each of the 3 to 6 mounting foot seats in the circumferential direction is movably mounted on the mounting bottom plate, and the other end of each of the 3 to 6 mounting foot seats is mounted on the adjusting support cylinder contacted with the mounting bottom plate; the support cylinder and the mounting bottom plate can be further fixedly adjusted through the mounting foot seat, so that stability can be effectively enhanced.
Further, a butt joint ring is also arranged on the mounting bottom plate; not only can utilize the quick affirmation of docking collar to adjust the mounted position of a section of thick bamboo to can further improve stability.
Further, a slot is formed in the mounting bottom plate, and the lower end of the adjusting support cylinder can be inserted into the slot; the mounting position of the support cylinder can be quickly confirmed and adjusted by the slots, and the space can be effectively saved during transportation.
Further, the height adjusting piece adopts a second assembled height adjusting piece; the second assembly type height adjusting piece comprises a plurality of groups of support rods which can be movably connected between the mounting bottom plate and the mounting body, and a protective cover which can be wrapped outside the support rods; the support rod is additionally arranged on the mounting bottom plate, and the net wire component and the power supply wire component are arranged in the protective cover to further protect the circuit.
Furthermore, the plurality of groups of support rods are circumferentially and uniformly arranged between the mounting bottom plates and the mounting body.
Further, the support rod includes a plurality of adjustment struts for connecting the ferrules between the adjustment struts.
Furthermore, threaded interfaces are arranged at the upper end and the lower end of the adjusting support rod; the mounting baseplate, the mounting body and the two ends of the sleeve pipe are respectively provided with a mounting threaded hole corresponding to the threaded interface.
Further, the protection cover comprises a protection cover body, and a clamping ring which is arranged on the protection cover body and used for connecting the adjusting support rod.
Compared with the prior art, the invention has the beneficial effects that: the invention has reasonable overall structure design, is convenient for assembly and disassembly, can be transported separately, and effectively reduces the trouble caused by volume and weight; the problem that the integrated GNSS deformation monitoring pier is not easy to carry can be effectively solved by utilizing the mounting pier of the assembled structure, and the integrated GNSS deformation monitoring pier is more suitable for mounting in the rare areas of the human track; the invention has simple integral structure and lower manufacturing cost, is suitable for mass production, and can meet the implementation of a large number of dam monitoring projects at present.
Drawings
FIG. 1 is an exploded view of the structure of embodiment 1 of the present invention;
FIG. 2 is an exploded view of the structure of embodiment 2 of the present invention;
FIG. 3 is an exploded view of the structure of embodiment 3 of the present invention;
FIG. 4 is an exploded view of the structure of embodiment 4 of the present invention;
FIG. 5 is an exploded view of the structure of embodiment 5 of the present invention;
FIG. 6 is an exploded view of the structure of embodiment 6 of the present invention;
FIG. 7 is an exploded view of the structure of embodiment 7 of the present invention;
The device comprises a 1-mounting pier, a 11-mounting bottom plate, a 110-slot, a 12-height adjusting piece, a 13-mounting body, a 14-mounting foot seat, a 2-mounting panel, a 21-panel body, a 22-mounting rod, a 3-monitoring module body, a 31-GNSS receiver, a 32-antenna bridge, a 4-first assembly type height adjusting piece, a 41-first adjusting barrel, a 410-adjusting support barrel, a 42-first mounting barrel, a 5-second assembly type height adjusting piece, a 51-supporting rod, a 511-adjusting support rod, a 512-sleeve pipe and a 52-protecting cover.
Detailed Description
Example 1: the portable integrated GNSS deformation monitoring pier as shown in FIG. 1 comprises a monitoring pier body and a GNSS monitoring module which can be installed on the monitoring pier body; the monitoring pier body comprises a mounting pier 1, and a mounting panel 2 which can be mounted at the upper end of the mounting pier 1; the GNSS monitoring module comprises a monitoring module body 3, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body 3, a network cable assembly used for connecting the monitoring module body 3 and the communication module, and a power supply line assembly used for connecting the monitoring module body 3 and the power module;
The mounting pier 1 is of an assembled structure, and particularly comprises a mounting bottom plate 11, a height adjusting piece 12 which can be mounted on the mounting bottom plate 11, and a mounting body 13 which can be mounted at the upper end of the height adjusting piece 12 and is used for mounting the mounting panel 2; wherein, the height adjusting piece 12 and the mounting body 13 are all made of metal pipes, and the height adjusting piece 12 and the mounting body 13 are connected through flanges;
The mounting panel 2 comprises a panel body 21 which can be clamped at the upper end of the mounting body 13, and a mounting rod 22 which can be movably mounted on the panel body 21;
The monitoring module body 3 comprises a GNSS receiver 31 mountable on a mounting bar 22, an antenna bridge 32 mountable on the altitude mixture adjustment piece 12 and connected to the GNSS receiver 31;
the panel body 21 is provided with a through hole through which the wire assembly and the power supply wire assembly can pass.
It should be noted that, in this embodiment, the solar panel assembly adopted by the power module is not described herein.
Example 2: a portable integrated GNSS deformation monitoring pier as shown in fig. 2, comprising a monitoring pier body, a GNSS monitoring module capable of being mounted on the monitoring pier body; the monitoring pier body comprises a mounting pier 1, and a mounting panel 2 which can be mounted at the upper end of the mounting pier 1; the GNSS monitoring module comprises a monitoring module body 3, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body 3, a network cable assembly used for connecting the monitoring module body 3 and the communication module, and a power supply line assembly used for connecting the monitoring module body 3 and the power module;
The mounting pier 1 is of an assembled structure, and particularly comprises a mounting bottom plate 11, a height adjusting piece 12 which can be mounted on the mounting bottom plate 11, and a mounting body 13 which can be mounted at the upper end of the height adjusting piece 12 and is used for mounting the mounting panel 2;
The mounting panel 2 comprises a panel body 21 which can be clamped at the upper end of the mounting body 13, and a mounting rod 22 which can be movably mounted on the panel body 21;
The monitoring module body 3 comprises a GNSS receiver 31 mountable on a mounting bar 22, an antenna bridge 32 mountable on the altitude mixture adjustment piece 12 and connected to the GNSS receiver 31;
The panel body 21 is provided with a through hole through which the net wire component and the power supply wire component can pass;
The height adjusting piece 12 adopts a first assembled height adjusting piece 4; the first assembled height adjusting piece 4 comprises a first adjusting cylinder 41 which can be movably mounted on the mounting base plate 11 through the mounting foot seat 14, and a first mounting cylinder 42 which can be movably mounted on the first adjusting cylinder 41;
The first adjusting cylinder 41 comprises a plurality of adjusting support cylinders 410 with the same structure;
Mounting notches are formed in the bottom of the inner wall of the adjusting support cylinder 410 and the bottom of the inner wall of the first mounting cylinder 42, and a butt joint ring is arranged at the top of the adjusting support cylinder 410; the first adjusting cylinders 41 and the first mounting cylinder 42 are movably connected through mounting notches and the butt joint rings, and the connecting parts of the mounting notches and the butt joint rings are fastened through bolts;
The top end of the inner wall of the first mounting cylinder 42 is provided with a clamping groove for clamping the panel body 21; the number of the mounting feet 14 is 3, one end of the 3 mounting feet 14 in the circumferential direction is movably mounted on the mounting base plate 11, and the other end of the 3 mounting feet 14 is mounted on the adjusting support cylinder 410 contacted with the mounting base plate 11.
It should be noted that, in this embodiment, the solar panel assembly adopted by the power module is not described herein.
Example 3: a portable integrated GNSS deformation monitoring pier as shown in fig. 3, comprising a monitoring pier body, a GNSS monitoring module capable of being mounted on the monitoring pier body; the monitoring pier body comprises a mounting pier 1, and a mounting panel 2 which can be mounted at the upper end of the mounting pier 1; the GNSS monitoring module comprises a monitoring module body 3, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body 3, a network cable assembly used for connecting the monitoring module body 3 and the communication module, and a power supply line assembly used for connecting the monitoring module body 3 and the power module;
The mounting pier 1 is of an assembled structure, and particularly comprises a mounting bottom plate 11, a height adjusting piece 12 which can be mounted on the mounting bottom plate 11, and a mounting body 13 which can be mounted at the upper end of the height adjusting piece 12 and is used for mounting the mounting panel 2;
The mounting panel 2 comprises a panel body 21 which can be clamped at the upper end of the mounting body 13, and a mounting rod 22 which can be movably mounted on the panel body 21;
The monitoring module body 3 comprises a GNSS receiver 31 mountable on a mounting bar 22, an antenna bridge 32 mountable on the altitude mixture adjustment piece 12 and connected to the GNSS receiver 31;
The panel body 21 is provided with a through hole through which the net wire component and the power supply wire component can pass;
The height adjusting piece 12 adopts a first assembled height adjusting piece 4; the first assembled height adjusting piece 4 comprises a first adjusting cylinder 41 which can be movably mounted on the mounting base plate 11 through the mounting foot seat 14, and a first mounting cylinder 42 which can be movably mounted on the first adjusting cylinder 41;
The first adjusting cylinder 41 comprises a plurality of adjusting support cylinders 410 with the same structure;
Mounting notches are formed in the bottom of the inner wall of the adjusting support cylinder 410 and the bottom of the inner wall of the first mounting cylinder 42, and a butt joint ring is arranged at the top of the adjusting support cylinder 410; the first adjusting cylinders 41 and the first mounting cylinder 42 are movably connected through mounting notches and the butt joint rings, and the connecting parts of the mounting notches and the butt joint rings are fastened through bolts;
The top end of the inner wall of the first mounting cylinder 42 is provided with a clamping groove for clamping the panel body 21; the number of the mounting feet 14 is 3, one end of the 3 mounting feet 14 in the circumferential direction is movably mounted on the mounting base plate 11, and the other end of the 3 mounting feet 14 is mounted on the adjusting support cylinder 410 contacted with the mounting base plate 11.
Wherein, the mounting baseplate 11 is also provided with a butt joint ring.
It should be noted that, in this embodiment, the solar panel assembly adopted by the power module is not described herein.
Example 4: the portable integrated GNSS deformation monitoring pier as shown in FIG. 4 comprises a monitoring pier body and a GNSS monitoring module which can be installed on the monitoring pier body; the monitoring pier body comprises a mounting pier 1, and a mounting panel 2 which can be mounted at the upper end of the mounting pier 1; the GNSS monitoring module comprises a monitoring module body 3, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body 3, a network cable assembly used for connecting the monitoring module body 3 and the communication module, and a power supply line assembly used for connecting the monitoring module body 3 and the power module;
The mounting pier 1 is of an assembled structure, and particularly comprises a mounting bottom plate 11, a height adjusting piece 12 which can be mounted on the mounting bottom plate 11, and a mounting body 13 which can be mounted at the upper end of the height adjusting piece 12 and is used for mounting the mounting panel 2;
The mounting panel 2 comprises a panel body 21 which can be clamped at the upper end of the mounting body 13, and a mounting rod 22 which can be movably mounted on the panel body 21;
The monitoring module body 3 comprises a GNSS receiver 31 mountable on a mounting bar 22, an antenna bridge 32 mountable on the altitude mixture adjustment piece 12 and connected to the GNSS receiver 31;
The panel body 21 is provided with a through hole through which the net wire component and the power supply wire component can pass;
The height adjusting piece 12 adopts a first assembled height adjusting piece 4; the first assembled height adjusting piece 4 comprises a first adjusting cylinder 41 which can be movably mounted on the mounting base plate 11 through the mounting foot seat 14, and a first mounting cylinder 42 which can be movably mounted on the first adjusting cylinder 41;
The first adjusting cylinder 41 comprises a plurality of adjusting support cylinders 410 with the same structure;
Mounting notches are formed in the bottom of the inner wall of the adjusting support cylinder 410 and the bottom of the inner wall of the first mounting cylinder 42, and a butt joint ring is arranged at the top of the adjusting support cylinder 410; the first adjusting cylinders 41 and the first mounting cylinder 42 are movably connected through mounting notches and the butt joint rings, and the connecting parts of the mounting notches and the butt joint rings are fastened through bolts;
the mounting base plate 11 is provided with a slot 110, and the lower end of the adjusting support cylinder 410 can be inserted into the slot 110;
The top end of the inner wall of the first mounting cylinder 42 is provided with a clamping groove for clamping the panel body 21; the number of the mounting feet 14 is 3, one end of the 3 mounting feet 14 in the circumferential direction is movably mounted on the mounting base plate 11, and the other end of the 3 mounting feet 14 is mounted on the adjusting support cylinder 410 contacted with the mounting base plate 11.
It should be noted that, in this embodiment, the solar panel assembly adopted by the power module is not described herein.
Example 5: the portable integrated GNSS deformation monitoring pier as shown in FIG. 5 comprises a monitoring pier body, and a GNSS monitoring module capable of being installed on the monitoring pier body; the monitoring pier body comprises a mounting pier 1, and a mounting panel 2 which can be mounted at the upper end of the mounting pier 1; the GNSS monitoring module comprises a monitoring module body 3, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body 3, a network cable assembly used for connecting the monitoring module body 3 and the communication module, and a power supply line assembly used for connecting the monitoring module body 3 and the power module;
The mounting pier 1 is of an assembled structure, and particularly comprises a mounting bottom plate 11, a height adjusting piece 12 which can be mounted on the mounting bottom plate 11, and a mounting body 13 which can be mounted at the upper end of the height adjusting piece 12 and is used for mounting the mounting panel 2;
The mounting panel 2 comprises a panel body 21 which can be clamped at the upper end of the mounting body 13, and a mounting rod 22 which can be movably mounted on the panel body 21;
The monitoring module body 3 comprises a GNSS receiver 31 mountable on a mounting bar 22, an antenna bridge 32 mountable on the altitude mixture adjustment piece 12 and connected to the GNSS receiver 31;
The panel body 21 is provided with a through hole through which the net wire component and the power supply wire component can pass;
The height adjusting piece 12 adopts a second assembled height adjusting piece 5; the second assembled height adjusting piece 5 comprises a plurality of groups of support rods 51 which can be movably connected between the mounting bottom plate 11 and the mounting body 13, and a protective cover 52 which can be wrapped outside the support rods 51; wherein, the protection cover 52 adopts a rubber hose.
Wherein, a plurality of groups of supporting rods 51 are uniformly arranged between the mounting bottom plate 11 and the mounting body 13 in the circumferential direction.
It should be noted that, in this embodiment, the solar panel assembly adopted by the power module is not described herein.
Example 6: FIG. 6 shows a portable integrated GNSS deformation monitoring pier comprising a monitoring pier body, a GNSS monitoring module capable of being mounted on the monitoring pier body; the monitoring pier body comprises a mounting pier 1, and a mounting panel 2 which can be mounted at the upper end of the mounting pier 1; the GNSS monitoring module comprises a monitoring module body 3, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body 3, a network cable assembly used for connecting the monitoring module body 3 and the communication module, and a power supply line assembly used for connecting the monitoring module body 3 and the power module;
The mounting pier 1 is of an assembled structure, and particularly comprises a mounting bottom plate 11, a height adjusting piece 12 which can be mounted on the mounting bottom plate 11, and a mounting body 13 which can be mounted at the upper end of the height adjusting piece 12 and is used for mounting the mounting panel 2;
The mounting panel 2 comprises a panel body 21 which can be clamped at the upper end of the mounting body 13, and a mounting rod 22 which can be movably mounted on the panel body 21;
The monitoring module body 3 comprises a GNSS receiver 31 mountable on a mounting bar 22, an antenna bridge 32 mountable on the altitude mixture adjustment piece 12 and connected to the GNSS receiver 31;
The panel body 21 is provided with a through hole through which the net wire component and the power supply wire component can pass;
the height adjusting piece 12 adopts a second assembled height adjusting piece 5; the second assembled height adjusting piece 5 comprises a plurality of groups of support rods 51 which can be movably connected between the mounting bottom plate 11 and the mounting body 13, and a protective cover 52 which can be wrapped outside the support rods 51; the support rod 51 includes a plurality of adjustment struts 511 for connecting the ferrules 512 between the adjustment struts 511; ; wherein each set of support rods 51 in this embodiment includes 3 adjustment struts 511 and 2 ferrules 512;
threaded interfaces are arranged at the upper end and the lower end of the adjusting strut 511; mounting screw holes corresponding to the screw interfaces are formed at both ends of the mounting base plate 11, the mounting body 13 and the sleeve 512;
The protection cover 52 adopts rubber and plastic sponge rubber strips, and when in use: the rubber and plastic sponge rubber strips are wound on the outer sides of the plurality of groups of supporting rods 51 sequentially and evenly from bottom to top, and all the supporting rods 51 are wrapped inside.
Wherein, a plurality of groups of supporting rods 51 are uniformly arranged between the mounting bottom plate 11 and the mounting body 13 in the circumferential direction.
It should be noted that, in this embodiment, the solar panel assembly adopted by the power module is not described herein.
Example 7: a portable integrated GNSS deformation monitoring pier as shown in fig. 7, comprising a monitoring pier body, a GNSS monitoring module capable of being mounted on the monitoring pier body; the monitoring pier body comprises a mounting pier 1, and a mounting panel 2 which can be mounted at the upper end of the mounting pier 1; the GNSS monitoring module comprises a monitoring module body 3, a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body 3, a network cable assembly used for connecting the monitoring module body 3 and the communication module, and a power supply line assembly used for connecting the monitoring module body 3 and the power module;
The mounting pier 1 is of an assembled structure, and particularly comprises a mounting bottom plate 11, a height adjusting piece 12 which can be mounted on the mounting bottom plate 11, and a mounting body 13 which can be mounted at the upper end of the height adjusting piece 12 and is used for mounting the mounting panel 2;
The mounting panel 2 comprises a panel body 21 which can be clamped at the upper end of the mounting body 13, and a mounting rod 22 which can be movably mounted on the panel body 21;
The monitoring module body 3 comprises a GNSS receiver 31 mountable on a mounting bar 22, an antenna bridge 32 mountable on the altitude mixture adjustment piece 12 and connected to the GNSS receiver 31;
The panel body 21 is provided with a through hole through which the net wire component and the power supply wire component can pass;
the height adjusting piece 12 adopts a second assembled height adjusting piece 5; the second assembled height adjusting piece 5 comprises a plurality of groups of support rods 51 which can be movably connected between the mounting bottom plate 11 and the mounting body 13, and a protective cover 52 which can be wrapped outside the support rods 51; the support rod 51 includes a plurality of adjustment struts 511 for connecting the ferrules 512 between the adjustment struts 511; ; wherein each set of support rods 51 in this embodiment includes 2 adjustment struts 511 and 1 ferrule 512;
threaded interfaces are arranged at the upper end and the lower end of the adjusting strut 511; mounting screw holes corresponding to the screw interfaces are formed at both ends of the mounting base plate 11, the mounting body 13 and the sleeve 512;
The protection cover 52 includes a protection cover body 521, and a clasp mounted on the protection cover body 521 for connecting the adjustment struts 511; wherein, the protection cover body 521 adopts the insulating rubber plate, cuts the insulating rubber plate when in use, fixes the insulating rubber plate on the adjusting support rod 511 through the clamping ring, and then carries out gluing sealing treatment on the port of the insulating rubber plate.
Wherein, a plurality of groups of supporting rods 51 are uniformly arranged between the mounting bottom plate 11 and the mounting body 13 in the circumferential direction.
It should be noted that, in this embodiment, the solar panel assembly adopted by the power module is not described herein.
Claims (5)
1. A portable integrated GNSS deformation monitoring pier comprises a monitoring pier body, and a GNSS monitoring module which can be installed on the monitoring pier body; the monitoring pier body comprises a mounting pier (1), and a mounting panel (2) which can be mounted at the upper end of the mounting pier (1); the GNSS monitoring module comprises a monitoring module body (3), a communication module and a power module, wherein the communication module and the power module can be respectively connected with the monitoring module body (3), the network cable assembly is used for connecting the monitoring module body (3) and the communication module, and the power supply line assembly is used for connecting the monitoring module body (3) and the power module;
The mounting pier (1) is of an assembled structure, and particularly comprises a mounting bottom plate (11), a height adjusting piece (12) which can be mounted on the mounting bottom plate (11), and a mounting body (13) which can be mounted at the upper end of the height adjusting piece (12) and is used for mounting a mounting panel (2);
The mounting panel (2) comprises a panel body (21) which can be clamped at the upper end of the mounting body (13), and a mounting rod (22) which can be movably mounted on the panel body (21);
The monitoring module body (3) comprises a GNSS receiver (31) which can be mounted on a mounting rod (22), an antenna bridge (32) which can be mounted on the height adjusting piece (12) and is connected with the GNSS receiver (31);
the panel body (21) is provided with a through hole through which the net wire component and the power supply wire component can pass;
The height adjusting piece (12) adopts a first assembled height adjusting piece (4); the first assembly type height adjusting piece (4) comprises a first adjusting cylinder (41) which can be movably mounted on the mounting base plate (11) through a mounting foot seat (14), and a first mounting cylinder (42) which can be movably mounted on the first adjusting cylinder (41);
the first adjusting cylinder (41) comprises a plurality of adjusting support cylinders (410) with the same structure;
The bottom of the inner wall of the adjusting support cylinder (410) and the bottom of the inner wall of the first mounting cylinder (42) are respectively provided with a mounting notch, and the top of the adjusting support cylinder (410) is provided with a butt joint ring; the first adjusting cylinders (41) and the first mounting cylinder (42) are movably connected through mounting notch and the butt joint ring, and the joints of the mounting notch and the butt joint ring are fastened through bolts;
A clamping groove for clamping the panel body (21) is formed in the top end of the inner wall of the first mounting cylinder (42);
3-6 mounting foot seats (14) are arranged, one end of each of the 3-6 mounting foot seats (14) in the circumferential direction is movably mounted on the mounting base plate (11), and the other end of each of the 3-6 mounting foot seats is mounted on the adjusting support cylinder (410) contacted with the mounting base plate (11);
a butt joint ring is also arranged on the mounting bottom plate (11);
The mounting bottom plate (11) is provided with a slot (110), and the lower end of the adjusting support cylinder (410) can be inserted into the slot (110);
The height adjusting piece (12) adopts a second assembled height adjusting piece (5); the second assembled height adjusting piece (5) comprises a plurality of groups of supporting rods (51) which can be movably connected between the mounting bottom plate (11) and the mounting body (13), and a protective cover (52) which can be wrapped outside the supporting rods (51).
2. The portable integrated GNSS deformation monitoring pier of claim 1, wherein the plurality of sets of support bars (51) are circumferentially and uniformly disposed between the mounting base plate (11) and the mounting body (13).
3. A portable integrated GNSS deformation monitoring pier according to claim 2 characterized in that the support bar (51) comprises a plurality of adjustment struts (511) for connecting the ferrules (512) between the adjustment struts (511).
4. A portable integrated GNSS deformation monitoring pier according to claim 3, characterized in that the adjusting struts (511) are provided with threaded interfaces at both the upper and lower ends; the mounting baseplate (11), the mounting body (13) and the two ends of the sleeve pipe (512) are respectively provided with a mounting threaded hole corresponding to the threaded interface.
5. The portable integrated GNSS deformation monitoring pier of claim 1, wherein the protective cover (52) comprises a protective cover body (521), a snap ring mounted on the protective cover body (521) for connecting the adjustment struts (511).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202110496564.9A CN113390331B (en) | 2021-05-07 | 2021-05-07 | Portable integrated GNSS deformation monitoring pier |
Applications Claiming Priority (1)
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