CN112630547A - Electromagnetic environment automatic monitoring system - Google Patents

Abstract

The application relates to the field of electromagnetic environment monitoring, discloses an electromagnetic environment automatic monitoring system, and it includes the solar cell of base, monitoring host computer, bracing piece, test probe and monitoring host computer and test probe power supply, and monitoring host computer, bracing piece and solar cell panel all set up on the base, its characterized in that: the utility model discloses a telescopic detection device, including telescopic sleeve, bracing piece, telescopic rod, first screw rod, regulation hole and through-hole, test probe passes through the connecting piece setting on the bracing piece, the bracing piece sets up to the retractable, the bracing piece is established to telescopic link and telescopic sleeve, telescopic sleeve's one end fixed connection is on the base, another pot head is established in the outside of telescopic link, a plurality of regulation holes have been seted up along vertical direction on the telescopic sleeve, the through-hole has been seted up on the telescopic link, wear to be equipped with first screw rod on the telescopic sleeve, regulation hole and through-. This application has reinforcing monitoring system's stability, reduces the strong wind weather monitoring system and takes place to empty and damage possible effect.

Description

Electromagnetic environment automatic monitoring system

Technical Field

The application relates to the field of electromagnetic environment monitoring, in particular to an electromagnetic environment automatic monitoring system.

Background

With the development of economy, the urban scale is continuously enlarged, and some high-voltage power transmission and distribution facilities are gradually surrounded by densely-populated urban areas. In recent years, due to the improvement of environmental awareness, the effect of electromagnetic radiation generated by power frequency electromagnetic radiation problems around power transmission lines and transformer substations on the environment increasingly attracts attention of surrounding residents and local governments, so that complaints of people on the environmental effect of high-voltage power transmission and transformation projects are gradually increased, and disputes are increased. Therefore, analysis of electromagnetic environment around the high-voltage overhead line and the transformer substation is very necessary, and an electromagnetic environment online monitoring system needs to be additionally arranged at specific places such as the periphery of a high-voltage power transmission and transformation facility, a mobile communication base station, a broadcast television transmitting tower and a sensitive point, so that long-term continuous electromagnetic radiation online monitoring is carried out, and data are fed back to citizens in real time.

As shown in fig. 1, in the related art, an electromagnetic environment monitoring system is provided, which includes a base 1, a monitoring host 2, a monitoring probe, a support rod 3, and a solar battery 5 for supplying power to the monitoring host 2 and a detection probe 4, wherein the monitoring host 2, the support rod 3, and the solar battery 5 are all fixedly disposed on the base 1, and the detection probe 4 is fixedly disposed on the support rod 3. During detection, the detection probe 4 detects the electromagnetic environment around the transformer substation, transmits the detected electromagnetic information to the monitoring host 2, and the monitoring host 2 transmits the received electromagnetic information to the display screen and displays the information through the display screen to feed back the information to citizens.

Aiming at the related technologies, the inventor thinks that in windy weather, when the wind is large, the height of the supporting rod is high, so that the base is easy to be driven to topple, and the whole electromagnetic environment monitoring system is damaged.

Disclosure of Invention

In order to improve the defect that the electromagnetic environment monitoring system is easy to topple over and is damaged in the windy weather in the related art, the application provides an electromagnetic environment automatic monitoring system.

The application provides an electromagnetic environment automatic monitoring system adopts following technical scheme to obtain:

the utility model provides an electromagnetic environment automatic monitoring system, includes the solar cell of base, monitoring host computer, bracing piece, test probe and monitoring host computer and the power supply of test probe, monitoring host computer, bracing piece and solar cell panel all set up on the base, test probe passes through the connecting piece setting on the bracing piece, the bracing piece sets up to the retractable, the bracing piece is established to telescopic link and telescope tube, telescope tube's one end fixed connection is on the base, and another pot head is established in the outside of telescopic link, a plurality of regulation holes have been seted up along vertical direction on the telescope tube, the through-hole has been seted up on the telescopic link, wear to be equipped with first screw rod on the telescope tube, regulation hole and through-hole have been worn to establish simultaneously by first screw rod, the equal threaded connection in telescope tube's the outside at the both ends of first screw.

Through above-mentioned technical scheme, during the strong wind weather, the operator unscrews the nut from first screw rod to take off first screw rod from telescopic link and telescope tube, and stretch into flexible with the telescopic link in, make the whole height of bracing piece reduce, then wear to establish corresponding position's regulation hole and through-hole with first screw rod, and screw up the nut on first screw rod again, make telescopic link and telescope tube rigidity. The arrangement is beneficial to reducing the height gravity center of the monitoring system, thereby being beneficial to reducing the possibility that the monitoring system topples over in windy weather.

Preferably: one side of the base, which faces the ground, is hinged with a cushion block, and the cushion block is abutted to the ground.

Through above-mentioned technical scheme, when the ground is uneven, the cushion is rotatory around the articulated department between cushion and the base, and the cushion offsets with ground to make the steady support of base subaerial.

Preferably: the connecting piece includes the installation piece, the test probe links to each other with the installation piece, the installation piece is worn to establish by the telescopic link, the spliced eye has been seted up on the installation piece, peg graft and threaded connection has the peg graft pole in the peg graft, the peg graft pole rotates towards the one end of telescopic link and is connected with the piece that supports tightly, support the piece and support tightly in the outside of telescopic link.

Through above-mentioned technical scheme, when the operator need adjust the high position of test probe on the telescopic link, the operator twists and moves the grafting pole for the telescopic link is kept away from to the tight piece, thereby makes and removes fixedly between installation piece and the telescopic link, then the operator will install the piece and slide to required position along the telescopic link, twist the grafting pole after that, until support the tight piece and support the outside at the telescopic link tightly, thereby make the high position of installation piece and test probe fixed.

Preferably: one side of the detection probe facing the installation block is connected with a second connection block, one side of the installation block is provided with a threaded hole, the outer side of the second connection block is connected with a second screw rod, the second screw rod is in threaded connection with the installation block through the threaded hole, and the installation block is provided with a positioning assembly for limiting the position of the detection probe.

Through above-mentioned technical scheme, when needs adjust test probe's angle, the operator is through making the second screw rod at the screw hole internal rotation to make the second connecting block drive test probe and take place the rotation, until rotating test probe to required angle, then restrict the location to test probe through locating component. The angle of the detection probe can be conveniently adjusted by an operator according to the detection requirement, and the detection range of the detection probe is enlarged.

Preferably: the locating component comprises a locating rod, a fixed frame and a locating piece, the fixed frame is fixedly connected to the outer side of the mounting block, the locating rod penetrates through the fixed frame, a locating block is connected to the locating rod in the two sides of the fixed frame in a threaded mode, the locating rod faces towards one end of the second connecting block and is fixedly connected with the locating piece, a plurality of clamping grooves are formed in the outer side of the second connecting block along the periphery, and the locating piece is provided with a plurality of protruding edges towards one side of the second connecting block and is limited in one clamping groove in a corresponding mode.

Through above-mentioned technical scheme, when limiting the location to test probe's position, the operator twists the locating piece orientation and moves away from the direction of fixed frame to promote the locating lever, the locating lever drives the spacer and moves towards the second connecting block, make bead and draw-in groove correspond the restriction, then twist the locating piece towards fixed frame again and move, make the rigidity of locating plate and spacer, thereby realize prescribing a limit to the position of second connecting block, be favorable to strengthening the stability of test probe position.

Preferably: the mounting block is internally provided with a limiting groove, the limiting groove is communicated with the threaded hole, the inner diameter of the limiting groove is larger than that of the threaded hole, one end, far away from the second connecting block, of the second screw rod is connected with a limiting ball, and the limiting ball is limited in the limiting groove.

Through above-mentioned technical scheme, spacing ball restricts all the time at the spacing inslot, has reduced the operator and has twisted the second screw rod, and the possibility that the second screw rod breaks away from the threaded hole is favorable to strengthening the stability of being connected between second screw rod and the installation piece.

Preferably: the rain shield assembly is arranged above the detection probe on the telescopic rod and comprises a first connecting block, a rain shield and an opening rod, the telescopic rod is fixedly connected with the first connecting block, the rain shield is hinged and connected to the outer side of the first connecting block, the opening rod is hinged and connected to one side, facing the base, of the rain shield, an insertion groove is formed in the outer side of the telescopic rod, and one end, far away from the rain shield, of the opening rod is inserted into the insertion groove.

Through above-mentioned technical scheme, when raining, through propping up the weather shield, realize keeping off the rain to test probe and monitoring host computer, reduce the rainwater and directly drench test probe and monitoring host computer on, and lead to test probe and monitoring host computer to break down easily probably, be favorable to prolonging test probe and monitoring host computer's life.

Preferably: the rain baffle is made of transparent polyethylene.

By the technical scheme, the weight of the polyethylene is light, and the possibility that the supporting rod collapses due to heavy load on the supporting rod is reduced; meanwhile, the rain shield is set to be transparent, so that the possibility that the sun is shielded by the rain shield and the solar panel is influenced by absorption of solar energy is reduced.

Preferably: one side of the rain baffle towards the opening rod is provided with a holding tank, and the wall of the holding tank is fixedly provided with an elastic bulge.

Through above-mentioned technical scheme, when needs are folded up the flashing, the operator will stretch out the pole earlier and rotate along the articulated department between stretching out the pole and the flashing, cross elastic bulge and fold and deposit in the holding tank until stretching out the pole, then will the flashing is rotatory along the articulated department between flashing and the first connecting block for the flashing is folded up and is deposited, and easy operation is convenient.

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

1. in windy weather, an operator can lower the height of the supporting rod to lower the height gravity center of the whole monitoring system, so that the stability of the whole monitoring system is enhanced, and the possibility of damage caused by toppling of the monitoring system is reduced;

2. the setting of rain-proof subassembly can keep off the rain to monitoring host computer and test probe when raining, has reduced the monitoring host computer and has taken place the possibility of damaging after test probe drenches with rain.

Drawings

Fig. 1 is an overall structural diagram of the related art.

Fig. 2 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 3 is a schematic view for showing a connection structure between a connection member and a support rod according to an embodiment of the present application.

Fig. 4 is an enlarged view of a portion a in fig. 2.

Fig. 5 is a schematic structural diagram for showing a connection relationship between the telescopic rod and the telescopic sleeve in the embodiment of the present application.

Fig. 6 is a schematic structural diagram for embodying a rain shield assembly according to an embodiment of the present application.

Reference numerals: 1. a base; 11. cushion blocks; 2. monitoring the host; 3. a support bar; 31. a telescopic rod; 311. a through hole; 312. inserting grooves; 32. a telescopic sleeve; 321. an adjustment hole; 33. a first screw; 34. a nut; 4. detecting a probe; 41. a second connecting block; 411. a second screw; 412. a limiting ball; 413. a card slot; 5. a solar cell; 6. a connecting member; 61. mounting blocks; 611. inserting holes; 612. a plug rod; 613. a propping sheet; 614. a threaded hole; 615. a limiting groove; 616. perforating; 7. a positioning assembly; 71. positioning a rod; 72. a fixing frame; 73. positioning plates; 731. a rib; 74. positioning blocks; 8. a rain shield assembly; 81. a first connection block; 82. a rain shield; 821. accommodating grooves; 822. an elastic bulge; 83. an opening bar.

Detailed Description

The present application is described in further detail below with reference to figures 2-6.

The embodiment of the application discloses an electromagnetic environment automatic monitoring system.

Referring to fig. 2, electromagnetic environment automatic monitoring system includes base 1, the monitoring host computer 2, bracing piece 3, test probe 4 and the monitoring host computer 2 of setting on base 1 and the solar cell 5 of the 4 power supplies of test probe, and monitoring host computer 2, bracing piece 3 and solar cell 5 board all set up on base 1, and base 1 articulates towards one side on ground and is provided with cushion 11, and cushion 11 is inconsistent with ground. When ground unevenness, cushion 11 is rotatory around the articulated department between cushion 11 and the base 1 for cushion 11 contradicts on unevenness's subaerial, thereby carries out the outrigger to base 1. During monitoring, the detection probe 4 detects the electromagnetic environment around the transformer substation, transmits the detected electromagnetic information to the monitoring host 2, and the monitoring host 2 transmits the received electromagnetic information to the display screen and displays the information through the display screen to feed back to citizens.

Referring to fig. 2 and 3, the detection probe 4 is disposed on the supporting rod 3 through the connecting member 6, the connecting member 6 includes a mounting block 61, a through hole 616 is formed in the mounting block 61, the supporting rod 3 penetrates through the mounting block 61 through the through hole 616, an insertion hole 611 is formed in the mounting block 61, the insertion hole 611 is communicated with the through hole 616, an insertion rod 612 is inserted into the insertion hole 611 and is in threaded connection with the through hole 616, a abutting piece 613 is disposed on an inner ring of the through hole 616, one end of the insertion rod 612, facing the supporting rod 3, is rotatably connected with the abutting piece 613, and the abutting piece 613 abuts against the outer side of the supporting rod 3.

Referring to fig. 2 and 3, the detection probe 4 is connected to the mounting block 61, a threaded hole 614 and a limiting groove 615 which are communicated with each other are formed in one side of the mounting block 61 facing the detection probe 4, the inner diameter of the limiting groove 615 is larger than that of the threaded hole 614, and the limiting groove 615 is located at one end of the threaded hole 614, which faces away from the detection probe 4. One side of the detection probe 4 facing the mounting block 61 is connected with a second connecting block 41, one side of the second connecting block 41 facing the threaded hole 614 is welded with a second screw 411, one end of the second screw 411 far away from the second connecting block 41 is provided with a limiting ball 412, the limiting ball 412 and the second screw 411 are integrally formed, the limiting ball 412 is limited in a limiting groove 615, and the second screw 411 is in threaded connection and matching with the threaded hole 614.

Referring to fig. 4, the mounting block 61 is provided with a positioning assembly 7 for limiting the position of the detection probe 4, the positioning assembly 7 includes a positioning rod 71, a fixed frame 72 and a positioning plate 73, the fixed frame 72 is fixedly connected to the outer side of the mounting block 61, the positioning rod 71 penetrates through the fixed frame 72, a positioning block 74 is screwed on both sides of the fixed frame 72 on the positioning rod 71, and the two positioning blocks 74 respectively contact both sides of the fixed frame 72. One end of the positioning rod 71 facing the second connecting block 41 is fixedly connected with the positioning plate 73, a plurality of clamping grooves 413 are formed in the outer side edge of the second connecting block 41, and a plurality of protruding ribs 731 matched with the clamping grooves 413 are arranged on one side of the positioning plate 73 facing the second connecting block 41.

Before the detection, the operator can be through twisting grafting pole 612 for the piece 613 keeps away from bracing piece 3, then will install the piece 61 and remove to corresponding high back, fixes the position of installing piece 61 again, thereby makes things convenient for the operator to adjust the high position of detecting probe 4, so that the high focus of bracing piece 3 changes. Moreover, an operator can change the angle of the detection probe 4 by screwing the second screw 411, so that the detection probe 4 can perform multi-angle measurement, and then the operator can screw the positioning block 74 towards the direction away from the fixing frame 72 and push the positioning rod 71, so that the positioning plate 73 moves towards the second connecting block 41, the convex rib 731 on the positioning plate 73 is in insertion fit with the clamping groove 413 on the second connecting block 41, and the second connecting block 41 is limited, so that the position of the detection probe 4 is limited.

Referring to fig. 5, the supporting rod 3 is retractable, the supporting rod 3 is set to be a retractable rod 31 and a retractable sleeve 32, the retractable rod 31 is located above the retractable sleeve 32, one end of the retractable sleeve 32 is welded and fixed on the base 1, and the other end of the retractable sleeve is sleeved outside the retractable rod 31. A plurality of regulation holes 321 have been seted up along vertical direction on the telescopic sleeve 32, through-hole 311 has been seted up on telescopic link 31, set up like this, be convenient for the operator when adjusting the whole height of bracing piece 3, move telescopic link 31 along telescopic sleeve 32's vertical direction, until with the altitude mixture control to required height of bracing piece 3, then finely tune telescopic link 31's position, make through-hole 311 on the telescopic link 31 and the regulation hole 321 intercommunication of the last relevant position of telescopic sleeve 32, after that through wearing to establish regulation hole 321 and through-hole 311 with first screw rod 33 simultaneously, and make the both ends of first screw rod 33 extend to the outside of telescopic sleeve 32, and at the equal threaded connection nut 34 in the both ends of first screw rod 33, thereby make telescopic link 31 and telescopic sleeve 32 rigidity, make the height of bracing piece 3 obtain adjusting. Set up like this, the operator of being convenient for reduces the height of bracing piece 3 at strong wind weather to make the holistic high focus of monitoring system reduce, reduce the whole possibility of empting and taking place the damage of strong wind weather monitoring system.

Referring to fig. 6, be equipped with rain-proof subassembly 8 in the top of test probe 4 on telescopic link 31, rain-proof subassembly 8 includes first link 81, weather shield 82 and struts pole 83, and first link 81 fixed connection is in the one end that telescopic sleeve 32 was kept away from to telescopic link 31, and weather shield 82 chooses for use transparent polyethylene material to make, and weather shield 82 is equipped with two altogether, and two weather shields 82 articulate respectively on the both sides of first link 81. The opening rod 83 is hinged to one side of the rain shield 82 facing the base 1, the insertion groove 312 is formed in the outer side of the telescopic rod 31, and one end, far away from the rain shield 82, of the opening rod 83 is inserted into the insertion groove 312. The rain blocking plate 82 has a receiving groove 821 on one side facing the spreading rod 83, an elastic protrusion 822 is adhered to the wall of the receiving groove 821, and the elastic protrusion 822 may be made of rubber.

Referring to fig. 6, the rain shield 82 is arranged to shield rain for the monitoring host 2 and the detecting probe 4 in rainy days, so that the possibility that the monitoring host 2 and the detecting probe 4 are damaged due to direct rain on the monitoring host 2 and the detecting probe 4 is reduced. When the rain shield 82 needs to be folded, the operator turns the rain shield 82 towards the direction far away from the support rod 3 around the hinge between the rain shield 82 and the first connecting block 81, so that the opening rod 83 is separated from the insertion groove 312, then the opening rod 83 rotates around the hinge between the opening rod 83 and the accommodating groove 821, so that the opening rod 83 crosses the elastic protrusion 822 and is limited in the accommodating groove 821, so that the opening rod 83 is folded, and then the rain shield 82 is folded.

The implementation principle of the electromagnetic environment automatic monitoring system in the embodiment of the application is as follows: in windy weather, the operator adjusts the length of the supporting rod 3, so that the height center of gravity of the supporting rod 3 is reduced, the windy weather is reduced, the monitoring system is toppled over and the damage is likely to occur, and the overall stability of the monitoring system is favorably improved. The operator can adjust the angle of the detection probe 4 according to the need of detection so that the detection probe 4 can detect from a plurality of angles. In rainy days, the monitoring host 2 and the detection probe 4 can be shielded from rain through the rain shielding plate 82.

The present embodiment is only for explaining the present application, and it is not limited to the present application, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present application.

Claims (9)

1. The utility model provides an electromagnetic environment automatic monitoring system, includes solar cell (5) of base (1), monitoring host computer (2), bracing piece (3), test probe (4) and monitoring host computer (2) and test probe (4) power supply, monitoring host computer (2), bracing piece (3) and solar cell (5) board all set up on base (1), its characterized in that: detecting probe (4) set up on bracing piece (3) through connecting piece (6), bracing piece (3) set up to the retractable, establish to telescopic link (31) and telescope tube (32) bracing piece (3), the one end fixed connection of telescope tube (32) is on base (1), and another pot head is established in the outside of telescopic link (31), a plurality of regulation holes (321) have been seted up along vertical direction on telescope tube (32), through-hole (311) have been seted up on telescopic link (31), wear to be equipped with first screw rod (33) on telescope tube (32), regulation hole (321) and through-hole (311) are worn to establish simultaneously in first screw rod (33), the equal threaded connection in the outside of telescope tube (32) in the both ends of first screw rod (33) has nut (34).

2. An electromagnetic environment automatic monitoring system according to claim 1, characterized in that: one side of the base (1) facing the ground is hinged with a cushion block (11), and the cushion block (11) is abutted to the ground.

3. An electromagnetic environment automatic monitoring system according to claim 1, characterized in that: the connecting piece (6) comprises an installation block (61), the detection probe (4) is connected with the installation block (61), the installation block (61) is penetrated through by the telescopic rod (31), an insertion hole (611) is formed in the installation block (61), an insertion rod (612) is inserted into the insertion hole (611) and connected with the insertion rod in a threaded manner, the insertion rod (612) rotates towards one end of the telescopic rod (31) to be connected with a abutting piece (613), and the abutting piece (613) abuts against the outer side of the telescopic rod (31).

4. An electromagnetic environment automatic monitoring system according to claim 3, characterized in that: one side that detecting probe (4) were installed piece (61) towards is connected with second connecting block (41), threaded hole (614) have been seted up to one side of installation piece (61), second screw rod (411) are connected in the outside of second connecting block (41), second screw rod (411) pass through threaded hole (614) and installation piece (61) threaded connection, be equipped with locating component (7) that are used for restricting the position of detecting probe (4) on installation piece (61).

5. An electromagnetic environment automatic monitoring system according to claim 4, characterized in that: locating component (7) are including locating lever (71), fixed frame (72) and spacer (73), fixed frame (72) fixed connection is in the outside of installation piece (61), fixed frame (72) are worn to establish in locating lever (71), just there is locating piece (74) at the equal threaded connection in both sides of fixed frame (72) on locating lever (71), locating lever (71) one end and spacer (73) fixed connection towards second connecting block (41), a plurality of draw-in grooves (413) have been seted up along the periphery in the outside of second connecting block (41), spacer (73) are equipped with a plurality of fins (731) towards one side of second connecting block (41), one fin (731) correspond the restriction in a draw-in groove (413).

6. An electromagnetic environment automatic monitoring system according to claim 4, characterized in that: a limiting groove (615) is formed in the mounting block (61), the limiting groove (615) is communicated with the threaded hole (614), the inner diameter of the limiting groove (615) is larger than that of the threaded hole (614), one end, far away from the second connecting block (41), of the second screw (411) is connected with a limiting ball (412), and the limiting ball (412) is limited in the limiting groove (615).

7. An electromagnetic environment automatic monitoring system according to claim 1, characterized in that: be equipped with rain-shielding component (8) in the top of detecting probe (4) on telescopic link (31), rain-shielding component (8) include first connecting block (81), weather shield (82) and prop open pole (83), telescopic link (31) and first connecting block (81) fixed connection, weather shield (82) articulated connection is in the outside of first connecting block (81), prop open pole (83) articulated connection in one side of weather shield (82) towards base (1), inserting groove (312) have been seted up in the outside of telescopic link (31), the one end that weather shield (82) were kept away from in propping open pole (83) is pegged graft in inserting groove (312).

8. An electromagnetic environment automatic monitoring system according to claim 7, characterized in that: the rain baffle (82) is made of transparent polyethylene.

9. An electromagnetic environment automatic monitoring system according to claim 7, characterized in that: one side of the rain baffle (82) facing the opening rod (83) is provided with an accommodating groove (821), and an elastic bulge (822) is fixedly arranged on the wall of the accommodating groove (821).

Images