CN112710902B - Probe system for electromagnetic environment monitoring - Google Patents

Abstract

The utility model relates to a probe system for electromagnetic environment monitoring, which relates to the technical field of electromagnetic monitoring. According to the utility model, the adjusting seat is driven by the rotating assembly to drive the monitoring equipment to synchronously rotate around the base so as to monitor electromagnetic radiation signals in different directions in a monitoring area, and the swinging mechanism is utilized to drive the monitoring equipment to move along an arc-shaped path, so that the monitoring equipment can fully receive the electromagnetic radiation signals in a local range of the direction, thereby providing a full reference value for a monitoring result and further improving the accuracy of the monitoring result.

Description

Probe system for electromagnetic environment monitoring

Technical Field

The utility model relates to the technical field of electromagnetic monitoring, in particular to a probe system for electromagnetic environment monitoring.

Background

With the development of science and technology, devices for utilizing and generating electromagnetic radiation such as a mobile communication system, a broadcast television transmitting system and a high-voltage power transmission and transformation system are gradually increased, electromagnetic pollution problems are also derived while various demands of people are met, transformer substations, broadcast transmitting stations and the like are built nearby some residential places, and in order to ensure the health of residents, electromagnetic environment monitoring devices are required to monitor electromagnetic radiation conditions nearby the residential places in real time.

The utility model of China with the authorized bulletin number of CN210347781U discloses a mobile electromagnetic radiation monitoring device, which comprises a bottom frame, wherein a cover body is arranged on the bottom frame, a power interface and a communication interface are arranged on the outer side wall of the cover body, a vertical rod is vertically and upwardly arranged on the bottom frame in an extending manner, the vertical rod is an adjustable telescopic rod, an annular outer cover is arranged at the top end of the vertical rod, and monitoring equipment for detecting electromagnetic radiation conditions is arranged in the annular outer cover; according to the utility model, the monitoring height of the monitoring equipment is adjusted through the length-adjustable vertical rod, and the problem of exposed electric wires is solved.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: after the monitoring device is fixed at a monitoring place, although electromagnetic radiation signals at different heights of a monitoring area are monitored through the height-adjustable vertical rods, electromagnetic radiation signals at different directions cannot be monitored, so that the monitoring equipment cannot fully accept the electromagnetic radiation signals of the monitoring area, and the accuracy of a monitoring result is low.

Disclosure of Invention

In order to solve the problem of low accuracy in electromagnetic radiation monitoring, the utility model provides a probe system for electromagnetic environment monitoring.

The utility model provides a probe system for electromagnetic environment monitoring, which adopts the following technical scheme:

the utility model provides a probe system for electromagnetic environment monitoring, includes the base, sets up pole setting and the monitoring facilities of setting in the pole setting on the base roof, the cover is equipped with the base that is used for bearing monitoring facilities in the pole setting, coaxial rotation is connected with the regulation seat on the lateral wall that the base deviates from pole setting one side, monitoring facilities sets up on the regulation seat, be equipped with the pivoted rotating assembly of drive regulation seat on the base, be equipped with the swing mechanism of drive monitoring facilities along arc path motion on the regulation seat.

By adopting the technical scheme, when electromagnetic radiation signals in a certain area are monitored, the rotating assembly is utilized to drive the adjusting seat to rotate around the base, so that the monitoring equipment synchronously rotates along with the base, and the monitoring equipment monitors the electromagnetic radiation signals in different directions in the monitoring area; when a worker adjusts the monitoring equipment to a certain azimuth, the swinging mechanism is utilized to drive the monitoring equipment to move along an arc-shaped path, so that the monitoring equipment can fully receive electromagnetic radiation signals in a local range of the azimuth, and further, the monitoring equipment can obtain enough data samples, so that enough reference value is provided for a monitoring result, and the accuracy of the monitoring result is improved.

Optionally, swing mechanism is including setting up the fixed block on adjusting seat roof, run through on the lateral wall that the fixed block is close to pole setting one side and rotate and be connected with the axis of rotation, run through in the axis of rotation and be equipped with the dead lever, the dead lever is kept away from the one end setting of axis of rotation on adjusting seat's roof, the dead lever stretches out the one end coaxial fixed with first gear of axis of rotation, the one end cover that the fixed block was stretched out to the axis of rotation is equipped with the connecting plate, be connected with the second gear through the pivot rotation on the connecting plate, the second gear meshes with first gear is perpendicular, be connected with the connecting rod on the week lateral wall of pivot, the one end that the axis of rotation was kept away from to the connecting rod is connected with monitoring facilities, be equipped with drive axis of rotation pivoted actuating assembly on the adjusting seat.

Through adopting above-mentioned technical scheme, utilize drive assembly drive axis of rotation to rotate, the axis of rotation drives the connecting plate and rotates, because first gear is fixed with the dead lever for the second gear rotates around first gear engagement, at this moment, under the drive effect of connecting rod, monitoring facilities swings along the arc route, so that fully receives the electromagnetic radiation signal in this position local scope.

Optionally, the drive assembly includes the coaxial first bevel gear of fixing on the axis of rotation, be equipped with first driving motor on the regulating seat, first driving motor's output shaft has the second bevel gear, second bevel gear and first bevel gear meshing.

Through adopting above-mentioned technical scheme, utilize first driving motor to drive second bevel gear, first bevel gear in order and rotate for first bevel gear drives the axis of rotation and rotates, thereby makes the axis of rotation drive the connecting plate and rotates, simple structure is stable.

Optionally, the extension of being located the top or the below of adjusting seat on the lateral wall that the base deviates from pole setting one side is equipped with the supporting seat, the rotation subassembly is including setting up the second driving motor on the supporting seat, the output shaft of second driving motor has the worm, the worm rotates to be connected on the supporting seat, coaxial being equipped with the worm wheel on the week lateral wall of adjusting seat, worm wheel and worm meshing.

Through adopting above-mentioned technical scheme, utilize second driving motor drive worm to rotate for the worm drives the worm wheel and rotates, and the worm wheel drives the regulation seat and rotates, thereby realizes that monitoring facilities rotate around pole setting 360 degrees, so that monitoring facilities monitor the electromagnetic radiation signal of same high different position departments.

Optionally, the regulation seat includes backup pad and rotation sleeve, run through on the roof of backup pad be equipped with the base grafting complex perforation, the backup pad is with the axle sleeve and is rotated and connect on the perisporium of base, rotation sleeve is around perforating the lateral wall that sets up in backup pad one side, the one end cover that the backup pad was kept away from to rotation sleeve is established on the base and is rotated with the base and be connected, the worm wheel coaxial fixation is on rotation sleeve's periphery wall, enclose between backup pad and the rotation sleeve and close and form anticollision space.

Through adopting above-mentioned technical scheme, in order to reduce swing mechanism, monitoring facilities and rotate the in-process and collide with the subassembly possibility of rotating, play good anticollision guard action to rotating subassembly and monitoring facilities through anticollision space.

Optionally, the pole setting is inside cavity, be equipped with the spout with pole setting inner chamber intercommunication on the lateral wall of pole setting, the one end that the base is close to the pole setting stretches into in the pole setting, be equipped with the reciprocal lift assembly who slides of drive base in the pole setting.

Through adopting above-mentioned technical scheme, utilize lifting unit drive base to slide reciprocally along the length direction of vertical pole, help realizing the monitoring to the electromagnetic radiation signal of the different high departments of monitoring area, further promote the sufficiency of monitoring area data acquisition, and then promote monitoring facilities's monitoring effect.

Optionally, the lifting assembly includes third driving motor, third driving motor sets up on the interior diapire of pole setting, third driving motor's output shaft has the threaded rod, the one end that the third driving motor was kept away from to the threaded rod runs through the base and stretches into the one end in the pole setting and with base threaded connection, the one end that the threaded rod passed the base rotates to be connected on the interior roof of pole setting.

Through adopting above-mentioned technical scheme, utilize third driving motor drive threaded rod to rotate, under the direction effect of spout for the threaded rod drives the base and slides along the spout is reciprocal, thereby realizes the lift of base.

Optionally, be equipped with in the lateral wall of pole setting with the chamber of holding of spout intercommunication, hold the chamber along the base slip direction between the two opposite chamber walls and lie in the both sides of spout and all slide and be connected with flexible subassembly, flexible subassembly and spout closure.

Through adopting above-mentioned technical scheme, because this probe system is in outdoor use, when meetting rainwater or sand and dust weather, rainwater or sand and dust can get into in the pole setting from the spout, leads to the fact the influence to the use of this probe system, so set up flexible subassembly, the in-process that goes up and down at the base for the base drives flexible subassembly and stretches out and draws back in step, thereby makes flexible subassembly and spout keep closed state always, and then reduces the entering of external rainwater or sand and dust, helps promoting the performance of this probe system.

Optionally, the flexible subassembly includes fixed baffle, fixed baffle's one end is fixed on holding the chamber wall in chamber, fixed baffle's the other end slides in order and is connected with a plurality of regulation baffles, and is a plurality of regulation baffles set up along the slip direction of base.

Through adopting above-mentioned technical scheme, because fixed baffle is fixed in holding the intracavity, when the base slipped, the base drove the regulation baffle and slided in step, and the relative motion takes place for regulation baffle and fixed baffle this moment for the regulation baffle remains the closed state with the spout throughout, and then reduces the entering of external rainwater or dust.

Optionally, cover is established and is rotated on the base and is connected with the safety cover that is used for protecting rotation subassembly and swing mechanism, one side that the safety cover is close to monitoring facilities is equipped with the opening, be equipped with coupling assembling on the safety cover, the safety cover passes through coupling assembling and is connected with the base.

By adopting the technical scheme, as the probe system is used outdoors, the possibility of rain or dust contamination exists, and the protective cover is arranged, the probe system is favorable for playing a good role in protecting the rotating assembly and the swinging mechanism on the base from dust and rain; and through coupling assembling, make things convenient for the workman to install and remove the safety cover.

In summary, the present utility model includes at least one of the following beneficial technical effects:

1. the rotating assembly is used for driving the adjusting seat to rotate around the base, so that the adjusting seat synchronously rotates along with the base, and the monitoring equipment monitors electromagnetic radiation signals in different directions of a monitoring area; when a worker adjusts the monitoring equipment to a certain azimuth, the monitoring equipment is driven to move along an arc-shaped path by utilizing the swinging mechanism, so that the monitoring equipment fully receives electromagnetic radiation signals in a local range of the azimuth, and the monitoring equipment obtains enough data samples so as to provide enough reference value for statistics of monitoring results and further improve the accuracy of the monitoring results;

2. the anti-collision space formed by encircling the rotating sleeve and the supporting plate is beneficial to reducing the possibility of collision between the monitoring equipment and the rotating assembly in the rotating process, so that a good anti-collision protection effect is achieved on the rotating assembly and the monitoring equipment;

3. the lifting assembly is used for driving the base to slide back and forth along the length direction of the vertical rod, so that electromagnetic radiation signals at different heights in a certain direction are monitored, the sufficiency and the diversity of data sample collection in a monitoring area are further improved, and the monitoring effect of monitoring equipment is further improved;

4. when the base slides reciprocally along the sliding groove, the adjusting baffle slides synchronously along with the base, so that the adjusting baffle always keeps a closed state with the sliding groove, thereby being beneficial to reducing the entry of external rainwater or dust and further ensuring the usability of the probe system.

Drawings

Fig. 1 is a schematic overall structure of an embodiment of the present utility model.

Fig. 2 is a schematic structural view of the connection relationship among the neutral lever, the base, the adjustment seat, the monitoring device, and the rotating assembly for embodying the embodiment of the present utility model.

Fig. 3 is a schematic structural view showing the connection relationship among a support plate, a first driving motor, a second bevel gear, a first bevel gear, a rotating shaft, a fixed block, a connecting plate, a fixed rod, a first spring, a second gear, a connecting rod, a strut and a monitoring device in an embodiment of the present utility model.

Fig. 4 is a schematic cross-sectional structure for embodying the connection relationship among the third driving motor, the screw rod, the base and the upright in the embodiment of the present utility model.

Fig. 5 is a schematic cross-sectional view showing the connection relationship among the fixed baffle, the adjusting baffle, the base and the upright in the embodiment of the present utility model.

Fig. 6 is a schematic cross-sectional view of the connection relationship among the protective cover, the rotating block, the upright, the base, and the connection assembly for embodying the embodiment of the present utility model.

Fig. 7 is an enlarged view at a in fig. 6.

Reference numerals illustrate: 1. a base; 2. a vertical rod; 21. a chute; 22. a receiving chamber; 3. monitoring equipment; 31. a connecting block; 32. a bolt; 4. a base; 41. an end plate; 411. a clamping groove; 5. an adjusting seat; 50. an anti-collision space; 51. a support plate; 511. perforating; 52. rotating the sleeve; 6. a rotating assembly; 61. a second driving motor; 62. a worm; 63. a worm wheel; 64. a lug; 7. a fixed block; 8. a rotating shaft; 9. a fixed rod; 10. a first gear; 11. a connecting plate; 12. a rotating shaft; 13. a second gear; 14. a connecting rod; 141. a support rod; 15. a drive assembly; 151. a first bevel gear; 152. a first driving motor; 153. a second bevel gear; 16. a support base; 17. a lifting assembly; 171. a third driving motor; 172. a threaded rod; 18. a telescoping assembly; 181. a fixed baffle; 1811. a storage chamber; 182. adjusting a baffle; 19. a protective cover; 191. an opening; 192. a rotating block; 1921. a slide hole; 193. locking the sliding groove; 20. a connection assembly; 201. a locking block; 202. a screw; 203. screwing the cover; 23. a chassis; 24. solar photovoltaic panels.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-7.

The embodiment of the utility model discloses a probe system for electromagnetic environment monitoring. Referring to fig. 1 and 2, a probe system for electromagnetic environment monitoring includes a base 1, fixedly connected with machine case 23 on the roof of base 1 one end, fixedly connected with solar photovoltaic board 24 on the roof of base 1 other end, solar photovoltaic board 24 is connected with machine case 23 electricity, machine case 23 is used for saving the electric energy, so that for this probe system power supply, fixedly connected with pole setting 2 on the roof of base 1, coaxial cover establishes and slide on pole setting 2 and be connected with base 4, rotate on the lateral wall that base 4 deviates from pole setting 2 one side and be connected with regulation seat 5, monitoring facilities 3 set up on regulation seat 5, be equipped with the swing mechanism that drives monitoring facilities 3 along the arc route motion on the regulation seat 5.

Referring to fig. 1 and 2, the adjusting seat 5 includes a supporting plate 51 and a rotating sleeve 52, wherein a through hole 511 for the base 4 to pass through is perforated on the top wall of the supporting plate 51, the supporting plate 51 is coaxially sleeved and rotatably connected on the outer peripheral wall of the base 4, the rotating sleeve 52 is arranged on the bottom wall of the supporting plate 51 around the through hole 511, the rotating sleeve 52 and the supporting plate 51 can be integrally formed, and the bottom end of the rotating sleeve 52 is rotatably connected on the peripheral wall of the bottom end of the base 4.

Referring to fig. 1 and 2, the supporting seat 16 is horizontally extended below the rotating sleeve 52 on the side wall at the bottom end of the base 4, the supporting seat 16 can be integrally formed with the base 4, the top wall of the supporting seat 16 is provided with the rotating assembly 6 for driving the adjusting seat 5 to rotate, an anti-collision space 50 is formed by enclosing between the outer peripheral wall of the rotating sleeve 52 and the bottom wall of the supporting plate 51, the possibility of collision between the swinging mechanism and the driving assembly 6 is reduced, the base 4 is sleeved with the protective cover 19, and the protective cover 19 plays a good role in preventing rain and dust for the rotating assembly 6 and the swinging mechanism.

Referring to fig. 1 and 2, when electromagnetic radiation signals in a certain area are monitored, the rotating assembly 6 is utilized to drive the adjusting seat 5 to rotate around the base 4, so that the monitoring equipment 3 synchronously rotates along with the adjusting seat 5, the monitoring equipment 3 monitors the electromagnetic radiation signals in different directions in the monitoring area, and the sufficiency of monitoring and sampling is improved; when the monitoring device 3 is stopped at a certain position, the swinging mechanism is utilized to drive the monitoring device 3 to move along an arc-shaped path, so that the monitoring device 3 fully receives electromagnetic radiation signals in a local range of the position, and the monitoring device 3 obtains enough data samples so as to provide enough reference value for statistics of monitoring results, and further improve the accuracy of the monitoring results.

Referring to fig. 2, the rotating assembly 6 includes a second driving motor 61, a worm 62 and a worm wheel 63, the second driving motor 61 is fixedly connected to the top wall of the supporting seat 16, the worm 62 is rotatably connected to the top wall of the supporting seat 16 through two lugs 64, one end of the worm 62 is connected to an output shaft of the second driving motor 61, the worm wheel 63 is coaxially and fixedly connected to the outer peripheral wall of the rotating sleeve 52, and the worm wheel 63 is meshed with the worm 62.

Referring to fig. 2, the worm 62 is driven to rotate by the second driving motor 61, the worm 62 drives the worm wheel 63 to rotate, the worm wheel 63 drives the rotating sleeve 52 to rotate, the rotating sleeve 52 drives the supporting plate 51 to rotate, and the monitoring device 3 rotates around the vertical rod 2, so that the monitoring device 3 monitors electromagnetic radiation signals in different directions in a monitoring area.

Referring to fig. 2 and 3, the swing mechanism includes a fixed block 7, a rotating shaft 8, a fixed rod 9, a first gear 10, a connecting plate 11, a second gear 13, a connecting rod 14 and a driving assembly 15 driving the rotating shaft 8 to rotate, the fixed block 7 is fixedly connected to the top wall of the adjusting seat 5, the rotating shaft 8 penetrates through the side wall of the fixed block 7 and is rotatably connected with the fixed block 7, the longitudinal section of the fixed rod 9 is L-shaped, the fixed rod 9 penetrates through the end wall of the rotating shaft 8 along the length direction of the rotating shaft 8 and is rotatably connected with the rotating shaft 8, the horizontal end of the fixed rod 9 extends out of the rotating shaft 8 and is fixedly connected with the first gear 10 coaxially, and the vertical end of the fixed rod 9 is fixedly connected to the top wall of the supporting plate 51.

Referring to fig. 2 and 3, a connection plate 11 is fixedly connected to a peripheral wall of one end of the rotation shaft 8 extending out of the fixing block 7, a longitudinal section of the connection plate 11 is L-shaped, a top wall of a horizontal end of the connection plate 11 is rotatably connected with a second gear 13 through a rotation shaft 12, the second gear 13 is vertically meshed with a first gear 10, a longitudinal section of a connection rod 14 is L-shaped, a horizontal end of the connection rod 14 is fixedly connected with a peripheral side wall of the rotation shaft 12, one end of the connection rod 14 far away from the rotation shaft 12 is fixedly connected with a support rod 141, and the monitoring device 3 is detachably connected with the support rod 141 through cooperation of the connection block 31 and a bolt 32.

Referring to fig. 2 and 3, the driving assembly 15 includes a first bevel gear 151, a first driving motor 152 and a second bevel gear 153, the first bevel gear 151 is coaxially fixed on the outer circumferential wall of the rotation shaft 8, the first driving motor 152 is fixedly connected on the top wall of the adjustment seat 5 through a pad 1521, an output shaft of the first driving motor 152 is connected with the second bevel gear 153, and the second bevel gear 153 is engaged with the first bevel gear 151.

Referring to fig. 2 and 3, the first driving motor 152 is utilized to sequentially drive the second bevel gear 153 and the first bevel gear 151 to rotate, so that the first bevel gear 151 drives the rotating shaft 8 to rotate, the rotating shaft 8 drives the connecting plate 11 to rotate, and the first gear 10 is fixed with the fixing rod 9, so that the second gear 13 is meshed with the first gear 10 to rotate, and at the moment, the monitoring device 3 swings along an arc path under the driving action of the connecting rod 14.

Referring to fig. 2 and 4, the cross section of the upright rod 2 is rectangular, the interior of the upright rod 2 is hollow, a chute 21 communicated with the inner cavity of the upright rod 2 is arranged on the side wall of one side of the upright rod 2, one end of the base 4 close to the upright rod 2 stretches into the upright rod 2, a lifting component 17 for driving the base 4 to slide reciprocally along the chute 21 is arranged in the upright rod 2, the lifting component 17 comprises a third driving motor 171, the third driving motor 171 is arranged on the inner bottom wall of the upright rod 2, an output shaft of the third driving motor 171 is connected with a threaded rod 172, one end of the threaded rod 172 far away from the third driving motor 171 is rotationally connected to the inner top wall of the upright rod 2, and one end of the threaded rod 172 far away from the third driving motor 171 penetrates through the bottom wall of the base 4 and is in threaded connection with the base 4.

Referring to fig. 2 and 4, the third driving motor 171 is utilized to drive the threaded rod 172 to rotate, and under the guiding action of the chute 21, the threaded rod 172 drives the base 4 to slide reciprocally along the length direction of the chute 21, so as to realize lifting of the base 4, so that the monitoring device 3 monitors electromagnetic radiation signals at different heights, and the sufficiency of data acquisition in a monitoring area is facilitated, so that the monitoring effect is improved.

Referring to fig. 2 and 5, a containing cavity 22 communicated with a chute 21 is arranged in the side wall of a vertical rod 2, a telescopic assembly 18 is arranged in the containing cavity 22, the telescopic assembly 18 is used for shielding the chute 21, the telescopic assembly 18 comprises a fixed baffle 181 and a plurality of adjusting baffles 182 which are connected in a sliding manner in sequence, the number of the fixed baffle 181 and the adjusting baffles 182 in the utility model is one, one end of the fixed baffle 181 is fixed on the cavity wall of the containing cavity 22, a containing cavity 1811 is arranged on the end wall of the other end of the fixed baffle 181, one end of the adjusting baffle 182 is connected in the containing cavity 1811 in a sliding manner, and the other end of the adjusting baffle 182 is fixedly connected with a base 4.

Referring to fig. 2 and 5, when the base 4 is lifted, the base 4 drives the adjusting baffle 182 to lift synchronously, so that the adjusting baffle 182 always keeps a closed state with the chute 21, thereby reducing external rainwater or dust from the chute 21 to enter the upright 2, and further ensuring normal use of the probe system.

Referring to fig. 1 and 6, a rotating block 192 is penetrated and rotated on the top wall of the protective cover 19, a sliding hole 1921 matched with the vertical rod 2 in a sliding manner is penetrated and arranged on the top wall of the rotating block 192, an opening 191 is penetrated and arranged on the side wall of the protective cover 19, which is close to one side of the monitoring equipment 3, a connecting component 20 is arranged on the side wall of the bottom end of the protective cover 19, the protective cover 19 is detachably connected with the base 4 through the connecting component 20, an end plate 41 is arranged on the side wall of the bottom end of the base 4, which is located below the supporting seat 16, and the end plate 41 and the base 4 can be integrally formed.

Referring to fig. 6 and 7, two opposite side walls of the end plate 41 are respectively provided with a clamping groove 411, a locking chute 193 is penetrated through the side wall at the bottom end of the protective cover 19, when the protective cover 19 is received on the end plate 41, the locking chute 193 is communicated with the clamping groove 411, the connecting assembly 20 comprises a locking block 201, a screw rod 202 and a spiral cover 203, one end of the locking block 201 is slidingly connected in the locking chute 193, the other end of the locking block 201 is in plug-in fit with the clamping groove 411, the screw rod 202 is rotationally connected in the locking chute 193, one end of the screw rod 202 is in threaded connection with the locking block 201, the other end of the screw rod 202 is fixedly connected with the spiral cover 203 coaxially, and the spiral cover 203 is rotationally connected on the peripheral wall of the protective cover 19.

Referring to fig. 6 and 7, when a worker receives the protection cover 19 on the end plate 41, the cap 203 is screwed, so that the cap 203 drives the screw 202 to rotate, and under the guiding action of the locking chute 193, the screw 202 drives the locking block 201 to slide towards the locking slot 411 to be in plug-in fit with the locking slot 411, thereby realizing the assembly and disassembly of the protection cover 19.

The implementation principle of the probe system for electromagnetic environment monitoring in the embodiment of the utility model is as follows: when monitoring electromagnetic radiation signals in a certain area, the worm 62 and the worm wheel 63 are sequentially driven to rotate by the second driving motor 61, so that the worm wheel 63 drives the rotating sleeve 52 to rotate, the rotating sleeve 52 drives the supporting plate 51 to rotate, and the supporting plate 51 drives the monitoring equipment 3 to synchronously rotate, so that electromagnetic radiation signals with the same height and different directions are monitored; after the monitoring equipment 3 is regulated to a certain fixed azimuth, the first driving motor 152 is utilized to sequentially drive the second bevel gear 153 and the first bevel gear 151 to rotate, so that the first bevel gear 151 drives the rotating shaft 8 to rotate, the rotating shaft 8 drives the connecting plate 11 to rotate, so that the second gear 13 rotates around the first gear 10, and at the moment, the monitoring equipment 3 swings along an arc path under the driving action of the connecting rod 14, so that electromagnetic radiation signals in a local range of the azimuth are further monitored; after monitoring results in different directions and local ranges of different directions of the same height are completed, the threaded rod 172 is driven to rotate by the third motor, and under the guiding action of the chute 21, the threaded rod 172 drives the base 4 to lift, so that the monitoring equipment 3 monitors electromagnetic radiation signals at different heights of a monitoring area; according to the utility model, through the joint coordination of the base 4, the adjusting seat 5, the supporting seat 16, the rotating assembly 6, the lifting assembly 17, the swinging mechanism and the monitoring equipment, the monitoring of electromagnetic radiation signals of different heights, different directions and local ranges of different directions in a monitoring area by the probe system is realized, the sufficiency of monitoring data sample acquisition is facilitated to be improved, so that sufficient reference value is provided for statistics of monitoring results, and the accuracy of the monitoring results is further improved.

The embodiments of the present utility model are all preferred embodiments of the present utility model, and are not intended to limit the scope of the present utility model in this way, therefore: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (6)

1. The utility model provides a probe system for electromagnetic environment monitoring, includes base (1), sets up pole setting (2) on base (1) roof and sets up monitoring facilities (3) on pole setting (2), its characterized in that: the device is characterized in that a base (4) for bearing the monitoring equipment (3) is sleeved on the vertical rod (2), an adjusting seat (5) is coaxially connected to the side wall of one side, away from the vertical rod (2), of the base (4), the monitoring equipment (3) is arranged on the adjusting seat (5), a rotating assembly (6) for driving the adjusting seat (5) to rotate is arranged on the base (4), and a swinging mechanism for driving the monitoring equipment (3) to move along an arc-shaped path is arranged on the adjusting seat (5);

the vertical rod (2) is hollow, a chute (21) communicated with the inner cavity of the vertical rod (2) is arranged on the side wall of the vertical rod (2), one end, close to the vertical rod (2), of the base (4) stretches into the vertical rod (2), and a lifting assembly (17) for driving the base (4) to slide back and forth is arranged in the vertical rod (2);

the lifting assembly (17) comprises a third driving motor (171), the third driving motor (171) is arranged on the inner bottom wall of the vertical rod (2), an output shaft of the third driving motor (171) is connected with a threaded rod (172), one end of the threaded rod (172), far away from the third driving motor (171), penetrates through one end of the base (4) and stretches into the vertical rod (2) and is in threaded connection with the base (4), and one end of the threaded rod (172), penetrating through the base (4), is rotationally connected to the inner top wall of the vertical rod (2);

a containing cavity (22) communicated with the sliding groove (21) is arranged in the side wall of the upright (2), the containing cavity (22) is arranged between two opposite cavity walls along the sliding direction of the base (4) and is positioned at two sides of the sliding groove (21), telescopic components (18) are connected in a sliding manner, and the telescopic components (18) are closed with the sliding groove (21);

the telescopic component (18) comprises a fixed baffle (181), one end of the fixed baffle (181) is fixed on the cavity wall of the accommodating cavity (22), the other end of the fixed baffle (181) is sequentially connected with a plurality of adjusting baffles (182) in a sliding mode, and the adjusting baffles (182) are arranged along the sliding direction of the base (4).

2. The probe system for electromagnetic environment monitoring of claim 1, wherein: the swing mechanism comprises a fixed block (7) arranged on the top wall of an adjusting seat (5), the fixed block (7) penetrates through and rotates on the side wall close to one side of a vertical rod (2) to be connected with a rotating shaft (8), a fixed rod (9) penetrates through and is arranged in the rotating shaft (8), one end of the fixed rod (9), far away from the rotating shaft (8), is arranged on the top wall of the adjusting seat (5), one end of the fixed rod (9), extending out of the rotating shaft (8), is coaxially fixed with a first gear (10), one end of the rotating shaft (8), extending out of the fixed block (7), is sleeved with a connecting plate (11), a second gear (13) is rotationally connected onto the connecting plate (11) through a rotating shaft (12), the second gear (13) is vertically meshed with the first gear (10), a connecting rod (14) is connected onto the peripheral side wall of the rotating shaft (12), one end, far away from the rotating shaft (12), of the connecting rod (14) is connected with a monitoring device (3), and a driving assembly (15) for driving the rotating shaft (8) is arranged on the adjusting seat (5).

3. The probe system for electromagnetic environment monitoring of claim 2, wherein: the driving assembly (15) comprises a first bevel gear (151) coaxially fixed on the rotating shaft (8), a first driving motor (152) is arranged on the adjusting seat (5), an output shaft of the first driving motor (152) is connected with a second bevel gear (153), and the second bevel gear (153) is meshed with the first bevel gear (151).

4. The probe system for electromagnetic environment monitoring of claim 1, wherein: the utility model discloses a support structure for a pole setting (2) of a motor vehicle, including base (4), rotation subassembly (6) are equipped with supporting seat (16) including setting up second driving motor (61) on supporting seat (16) in the extension of the top or below that are located adjusting seat (5) on the lateral wall of base (4) deviating from pole setting (2) one side, the output shaft of second driving motor (61) has worm (62), worm (62) rotate and connect on supporting seat (16), coaxial worm wheel (63) that are equipped with on the week lateral wall of adjusting seat (5), worm wheel (63) and worm (62) meshing.

5. The probe system for electromagnetic environment monitoring of claim 4, wherein: the adjusting seat (5) comprises a supporting plate (51) and a rotating sleeve (52), a through hole (511) which is in plug connection with the base (4) is formed in the top wall of the supporting plate (51), the supporting plate (51) is coaxially sleeved and rotated on the peripheral wall of the base (4), the rotating sleeve (52) is arranged on the side wall of one side of the supporting plate (51) around the through hole (511), one end, far away from the supporting plate (51), of the rotating sleeve (52) is sleeved on the base (4) and is rotationally connected with the base (4), the worm wheel (63) is coaxially fixed on the peripheral wall of the rotating sleeve (52), and an anti-collision space (50) is formed by encircling between the supporting plate (51) and the rotating sleeve (52).

6. The probe system for electromagnetic environment monitoring of claim 1, wherein: the novel anti-theft device is characterized in that a protective cover (19) used for protecting the rotating assembly (6) and the swinging mechanism is sleeved on the base (4) and connected with the base in a rotating mode, an opening (191) is formed in one side, close to the monitoring equipment (3), of the protective cover (19), a connecting assembly (20) is arranged on the protective cover (19), and the protective cover (19) is connected with the base (4) through the connecting assembly (20).