CN110850181B

CN110850181B - Mobile monitoring device for electromagnetic radiation environment of base station

Info

Publication number: CN110850181B
Application number: CN201911091121.0A
Authority: CN
Inventors: 覃扬; 谭双双
Original assignee: Chongqing Radiation Technology Service Center Co ltd
Current assignee: Chongqing Radiation Technology Service Center Co ltd
Priority date: 2019-11-09
Filing date: 2019-11-09
Publication date: 2021-10-26
Anticipated expiration: 2039-11-09
Also published as: CN110850181A

Abstract

The invention discloses a mobile monitoring device for a base station electromagnetic radiation environment, which relates to the field of electromagnetic radiation detection and adopts the technical scheme that: including the measuring apparatu body, the measuring apparatu body includes the organism and is coupled in the probe of the signal input part of organism, still includes the removal probe frame, and the removal probe frame includes a plurality of stabilizer blades, sets up mount pad and swing joint on a plurality of stabilizer blades in the lifter group of mount pad, set up the vertical feed tank that link up on the mount pad, the lifter group is including the unit post of adaptation feed tank, the jack is seted up to vertical and up end when the unit post uses, the inserted bar of its fixed adaptation jack of terminal surface, still be provided with on the mount pad and be used for upwards propelling movement from the feed tank under shed with a plurality of unit posts in proper order, the probe is fixed in the unit post. The invention makes the measurement more convenient and the movement and the transportation relatively more convenient.

Description

Mobile monitoring device for electromagnetic radiation environment of base station

Technical Field

The invention relates to the field of electromagnetic radiation detection, in particular to a base station electromagnetic radiation environment monitoring method.

Background

A base station, i.e., a public mobile communication base station, which is a form of a radio station, refers to a radio transceiver station that performs information transfer between a mobile communication switching center and a mobile phone terminal in a certain radio coverage area. The base station is composed of indoor equipment and outdoor transmitting antenna, and the main equipment of the indoor part of the base station is composed of base station controller, signal transmitter, power amplifier, combiner, coupler, duplexer and part of feeder line.

Electromagnetic radiation refers to "a phenomenon in which energy is emitted into space from a source of emission in the form of electromagnetic waves". People live in electromagnetic radiation all the time, but only if the electromagnetic radiation exceeds certain power to cause 'electromagnetic pollution', the electromagnetic pollution can cause harm to human bodies.

Three sources of electromagnetic radiation of the base station are electromagnetic leakage of a transmitter, signal transmission of a transmitting antenna and high-frequency cables and joints thereof. High frequency cables and joints thereof are generally well shielded, electromagnetic radiation to the outside environment is extremely small, and therefore the influence of the base station on the surrounding electromagnetic radiation is mainly caused by electromagnetic waves emitted by the transmitting antenna. In order to effectively guarantee the health of the masses, relevant departments and personnel are required to monitor and investigate the electromagnetic radiation environment of the communication base station.

Patent No. CN109683192A discloses a method for detecting and calculating radiation of a base station, which includes the following steps: (1) acquiring the receiving power of a pilot channel of a base station by using an intelligent mobile phone; (2) performing power conversion according to the modes of different wireless networks to which the base station belongs; (3) converting to total receiving power of the base station according to the fact that the total transmitting power of the pilot channel power meets a certain ratio; (4) calculating the radiation intensity corresponding to the total received power of the base station; (5) and converting the standard into a safe time boundary according to the national standard of radiation.

The technical scheme provides a base station radiation method, and the invention provides a new technical scheme for monitoring the electromagnetic radiation of the base station.

Disclosure of Invention

The invention aims to provide a mobile monitoring device for a base station electromagnetic radiation environment, which can be used for detecting base station radiation by workers.

The technical purpose of the invention is realized by the following technical scheme:

the invention provides a mobile monitoring device for a base station electromagnetic radiation environment, which comprises the following components: including the measuring apparatu body, the measuring apparatu body includes the organism and is coupled in the probe of the signal input part of organism, still includes the removal probe frame, and the removal probe frame includes a plurality of stabilizer blades, sets up mount pad and swing joint on a plurality of stabilizer blades in the lifter group of mount pad, set up the vertical feed tank that link up on the mount pad, the lifter group is including the unit post of adaptation feed tank, the jack is seted up to vertical and up end when the unit post uses, the inserted bar of its fixed adaptation jack of terminal surface, still be provided with on the mount pad and be used for upwards propelling movement from the feed tank under shed with a plurality of unit posts in proper order, the probe is fixed in the unit post.

By adopting the technical scheme, when the probe needs to be installed and erected to the specified height position, a worker can firstly feed the unit columns for installing the probe into the feeding groove from the lower part of the feeding groove, then sequentially feed the unit columns into other unit columns, push each unit column to rise by using the pushing mechanism, and fix the unit columns in a mode that the insertion rods are inserted into the insertion holes at the moment to form a columnar structure so as to convey the probe to the proper height; compared with the common telescopic rod structure, the lifting rod group can be disassembled into the unit columns at the moment and then stacked and stored in the container to move, so that the lifting rod group is relatively convenient to move and carry.

The invention is further configured to: push mechanism includes the screw rod that sets up in the feed tank with the center pin, the inner wall in feed tank is fixed with the linking arm, the linking arm extends and the tip is fixed in the go-between towards the center in feed tank, screw rod circumference has been seted up around the outer wall and has been inlayed and establish the groove, the go-between cover is established the screw rod and is hidden in inlaying and establishing the inslot, the unit post is hollow internal thread structure and adaptation screw rod, the limit mouth that supplies the linking arm to pass through is seted up along length direction to the outer wall of unit post, the vertical projection in feed tank is the polygon, push mechanism is still including being used for driving screw pivoted drive assembly.

By adopting the technical scheme, when the unit column needs to be pushed to gradually start to move upwards from the lower opening of the feeding groove, the screw rod is driven to rotate by the driving assembly, and then the unit column is put into the feeding groove from the lower opening of the feeding groove; at the moment, because the vertical projection of the feeding groove is polygonal, namely the unit column is polygonal, the feeding groove can not rotate any more and only can ascend; at the moment, the connecting arm is arranged in the edge opening of the unit column, and the unit column does not rotate, so that the connecting arm can be effectively prevented from causing obstruction.

The invention is further configured to: the utility model discloses a driving assembly, including screw rod, drive pulley, drive belt and handle, the upper end of screw rod is fixed with the pivot with the center pin, drive pulley rotates and connects in the outer wall of mount pad and with the coplanar of driven pulley, the drive belt cover is located and is offered the logical groove that supplies the drive belt to pass through on drive pulley and driven pulley and the mount pad, the handle is fixed in the drive pulley.

Through adopting above-mentioned technical scheme, the rotatable handle drive driving pulley of staff, driving pulley drives from the driving pulley through the drive belt after rotating, and from the driving pulley drives the screw rod through the pivot after rotating and rotates to be used for the propelling movement unit post to rise.

The invention is further configured to: and the upper seat surface of the mounting seat is provided with a limiting plate around the upper opening of the feeding groove.

Through adopting above-mentioned technical scheme, when next unit post is not yet pegged graft fixedly with the unit post that is located the mount pad top, can utilize the restriction board to enclose and establish the ring that forms and restrict the unit post, prevent that it from removing at will and influencing each unit post and peg graft each other.

The invention is further configured to: the lower seat surface of mount pad is provided with the guide board around the under shed that advances to the groove, the lower extreme slope of guide board is towards keeping away from the central axis one side of mount pad.

Through adopting above-mentioned technical scheme, the guide board encloses the ring of establishing formation and is loudspeaker form and great mouth down to when sending into the feed tank with the unit post, can do the restriction guide to it, make things convenient for the staff to send into the feed tank with it.

The invention is further configured to: it is a plurality of divide one in the unit post as the top cylinder, the probe is fixed in the top cylinder, and the lower terminal surface of top cylinder is fixed with the connection rope, except that the top cylinder is outer other the stringing hole has been seted up along length direction on the unit post, the draw-in groove of mutual intercommunication is seted up around the stringing hole to the lower terminal surface of unit post, the draw-in groove is open structure down, the joint has centre gripping group in the draw-in groove, centre gripping group is including two clamp splice of mutually supporting, two wherein one side of clamp splice opposite side sets up the card post, and the card hole of agreeing with the card post is seted up to the opposite side, connect the rope by the centre gripping between two clamp splice.

Through adopting above-mentioned technical scheme, peg graft each other at a plurality of unit posts and form column structure propelling movement probe to the in-process of appointed height, the staff can pass the rope threading hole of connecting from each unit post, and the rope is connected to usable two clamp splice centre grippings this moment, arranges two clamp splice in the draw-in groove to it is fixed to connect the rope to do the enhancement to a plurality of unit posts, strengthens the structural strength of the column structure that a plurality of unit posts formed.

In conclusion, the invention has the following beneficial effects:

1. selecting a relatively proper monitoring point by collecting basic information of a monitoring point area and collecting basic information of a base station; selecting a time period which can better reflect actual electromagnetic radiation as monitoring time by using peak value analysis for local communication network equipment; detecting the electromagnetic radiation intensity of the monitoring point position by using a relatively convenient non-frequency-selection type radiation measuring instrument to obtain detection data for subsequently judging whether the electromagnetic radiation intensity of the current environment is reasonable or not;

2. a movable mounting rack is arranged for mounting the probe to a proper height position; the lifting rod group of the mobile mounting frame is used for fixing the probe, and the mobile mounting frame can be split into a plurality of unit columns, so that the mobile mounting frame can be stacked and stored in the container to move when necessary, and the mobile mounting frame is relatively convenient to move and carry.

Drawings

FIG. 1 is a schematic flow chart diagram according to a first embodiment of the present invention;

FIG. 2 is a schematic overall structure diagram of a second embodiment of the present invention;

fig. 3 is a partial structural schematic view of a lifting rod set according to a second embodiment of the present invention, which is mainly used for showing the structures of a jack and a rope threading hole;

fig. 4 is a schematic view of a second structure of the lifting rod set according to the second embodiment of the present invention, mainly illustrating the structure of the side opening and the insertion rod;

FIG. 5 is a schematic partial exploded view of a second embodiment of the mounting base of the present invention, mainly illustrating the structure of the feeding slot and the limiting plate;

fig. 6 is a schematic partial longitudinal sectional view of the mounting seat according to the second embodiment of the present invention, which is mainly used for showing a connection structure between the pushing mechanism and the mounting seat;

fig. 7 is a schematic partial exploded view of a pushing mechanism according to a second embodiment of the present invention;

fig. 8 is an exploded view of a clamping group according to a second embodiment of the present invention;

fig. 9 is a schematic view of monitoring distribution according to a first embodiment of the present invention.

In the figure: 1. a gauge body; 11. a body; 12. a probe; 2. a support leg; 3. a mounting seat; 31. a feed slot; 4. a lifter group; 41. a unit column; 411. a jack; 412. inserting a rod; 413. a side opening; 42. connecting ropes; 43. a stringing hole; 44. a card slot; 5. a pushing mechanism; 51. a screw; 511. embedding a groove; 512. a rotating shaft; 52. a connecting arm; 521. a connecting ring; 53. a drive assembly; 531. a driven pulley; 532. a driving pulley; 533. a transmission belt; 534. a handle; 61. a limiting plate; 62. a guide plate; 7. a clamping group; 71. a clamping block; 72. clamping the column; 73. and (6) clamping the hole.

Detailed Description

The invention is described in detail below with reference to the figures and examples.

The first embodiment is as follows:

the method for monitoring the electromagnetic radiation environment of the base station, referring to fig. 1, includes:

step one, preparation, which comprises confirming the area environment of the monitoring point, selecting a measuring instrument, and selecting the normal working time of the base station as the monitoring time.

The method comprises the steps of confirming the regional environment of a monitoring point, wherein the step of confirming the regional environment of the monitoring point comprises the steps of obtaining local weather through weather forecast, and selecting weather without rain or snow as a monitoring date so as to reduce interference of weather factors on radiation detection;

the measuring instrument comprises a non-frequency-selection type radiation measuring instrument; it should adapt to the frequency, range and response time requirements of the base station to be monitored.

And step two, preceding stage information acquisition, which comprises collecting and recording base station information, wherein the base station information comprises base station basic information, transmitter information and antenna information.

The base station basic information comprises the name, the number, the construction site, the construction unit and the type of the mobile communication base station;

the transmitter information comprises the type of the transmitter, the nominal power, the set power and the antenna gain;

the antenna information comprises the number of antennas, the type of the antennas, the gain of the antennas, the erecting mode of the antennas and the ground clearance of the antennas.

Step three, monitoring point selection, which comprises the steps of setting monitoring points in the range of the radius of 50m by taking the transmitting antenna as the center, and determining the monitoring points according to the information collected in the step two;

the monitoring points are preferably arranged at the nearest distance to the antenna that can be reached by the public. When the transmitting antenna of the mobile communication base station is a directional antenna, the detection points are arranged in the main lobe direction of the antenna.

Step four, establishing a monitoring point, moving the measuring instrument selected in the step one to the monitoring point, and installing a probe to a specified position according to a measuring purpose;

the distance between probe distance operating personnel is no less than 0.5m among the testing process, and the height is adjusting according to the measurement purpose apart from the height on ground, for example: 1.7 m; monitoring indoors, wherein the center position of a room is generally selected, and the distance between a point location and household appliances and other equipment is not less than 1 m; for window (balcony) position monitoring, the probe (antenna) tip should be inside the window frame (balcony) interface.

Acquiring monitoring data, wherein the acquisition of the monitoring data comprises the step of acquiring data through a measuring instrument for multiple times in a specified time period;

continuously measuring for 5 times at each measuring point, wherein the monitoring time is not less than 15s each time, and reading the maximum value in a stable state; and if the data difference obtained for multiple times is large, prolonging the monitoring time or monitoring again.

And step six, data processing, which comprises the steps of calculating the mean value of the monitoring data obtained in the step five and obtaining a monitoring result by combining the standard deviation value.

In the process of monitoring the radiation of the base station, the monitoring time also needs to be selected relatively properly, because the user quantity and the like have certain interference on the electromagnetic radiation intensity of the base station, a plurality of different time periods on the same day are selected as the monitoring time periods, and the monitoring time periods are selected according to the use peak values of local communication network equipment and comprise time periods from early peak periods to late peak periods, power utilization peak periods and power utilization valley periods.

After the relevant data is measured, the monitoring result is calculated and compared with the relevant standard, and whether the radiation intensity is reasonable or not is judged. After the monitoring result and the judging result are obtained, the working personnel records and stores the data to the computer; when the radiation monitoring is carried out on the same point position next time, the data of the previous time or a plurality of times can be called out for carrying out contrastive analysis, and the change condition of the radiation intensity is judged, so that the using effect is better. Meanwhile, in order to facilitate the comparison and analysis and information summarization of a plurality of groups of subsequent data, the data processing also comprises the steps of making a form and a monitoring point distribution schematic diagram according to the actual weather information, the monitoring time, the base station information, the monitoring point position information and the monitoring data of the monitoring point.

The following are form examples in sequence; fig. 9 is an example of a schematic and monitoring layout.

Note that fig. 9 indicates a measured base station antenna, a circle indicates another base station antenna, and a delta indicates a monitoring point location.

In conclusion, the invention can be used for monitoring the electromagnetic radiation of the base station, so that the staff can determine whether the masses are in a proper electromagnetic radiation environment or not, and the physical health of the masses is guaranteed.

Example two:

referring to fig. 1, the mobile monitoring device applied to a base station electromagnetic radiation environment includes a measuring instrument body 1, where the measuring instrument body 1 includes a machine body 11 for analyzing and processing detected data and a probe 12 coupled to a signal input end of the machine body 11 through a wire.

In order to facilitate the arrangement of the probe 12 at a proper position and a proper height by workers, the invention further comprises a movable probe frame, the movable probe frame comprises a mounting seat 3 and a plurality of support legs 2 longitudinally hinged to the mounting seat 3, the mounting seat 3 is in a block shape, and the plurality of support legs 2 are uniformly distributed at the bottom of the mounting seat 3 and are telescopic rods so as to meet the use requirements of various terrains. The installation base 3 is also provided with a lifting rod group 4, the lifting rod group 4 is vertically lifted, and the probe 12 is installed and fixed at the upper end of the lifting rod group so as to be arranged at a proper height.

Referring to fig. 3 and 4, a vertically through feed groove 31 (indicated in fig. 5) is opened in the mounting base 3, and an adapter cover plate is covered by a bolt and opened at one side of the feed groove 31. The lifting rod group 4 comprises a plurality of unit columns 41 matched with the feeding grooves 31, when the unit columns 41 are used, the unit columns 41 are vertical, the upper end faces of the unit columns are provided with jacks 411, and the jacks 411 are of an upper opening structure; the lower end surface of the unit column 41 is fixed with an insertion rod 412 which is matched with the insertion hole 411. A pushing mechanism 5 (shown in fig. 7) for sequentially pushing the plurality of unit columns 41 upward from the lower opening of the feed chute 31 is further mounted on the mounting base 3.

When the device is used, the pushing mechanism 5 pushes the unit columns 41 to be spliced into a cylindrical body, and the probe 12 is fixed on the unit column 41 at the uppermost end.

Referring to fig. 6 and 7, the pushing mechanism 5 includes a screw 51 concentrically disposed in the feed groove 31; a rod-shaped connecting arm 52 is fixed on the inner wall of the feeding groove 31, the connecting arm 52 extends radially, and a connecting ring 521 is fixed at one end of the connecting arm facing the center of the feeding groove 31; the outer wall of the screw 51 is provided with an adaptive embedding groove 511 in a surrounding way; the connection ring 521 is sleeved on the screw 51 and embedded in the embedding groove 511.

The pushing mechanism 5 further comprises a driving component 53 for driving the screw 51 to rotate; a rotating shaft 512 is coaxially formed at the upper end of the screw 51, and the driving assembly 53 includes a driven pulley 531, a driving pulley 532, a transmission belt 533 and a handle 534, wherein the driven pulley 531 is coaxially fixed to the rotating shaft 512 and has a diameter smaller than that of the screw 51.

A base plate is fixed on the outer wall of the mounting base 3, a vertically extending driving rotating shaft is fixedly and rotatably connected to the upper base plate, a driving belt wheel 532 is concentrically fixed on the driving rotating shaft, and a handle 534 is fixed at the upper end of the driving rotating shaft. The driving belt wheel 532 and the driven belt wheel 531 are sleeved with the driving belt wheel 533 (the mounting base 3 is provided with a hollow groove for the driving belt wheel 533 to pass through), and the handle 534 is rotated at the moment, so that the screw 51 can be driven to rotate through the belt wheel structure.

Referring to fig. 4 and 6, the unit column 41 has a hollow internal thread structure and is fitted with a screw 51; the outer wall of the unit column 41 is provided with a vertical edge port 413, and the edge port 413 is vertically communicated with the inner cavity of the unit column 41 and is transversely communicated with the inner cavity of the unit column 41; when the unit column 41 is placed in the feeding groove 31, it is screwed to the screw 51, and the connecting arm 52 and the driving belt 533 are extended from the side opening 413 into the unit column 41; the vertical projection of the feed slot 31 is polygonal, for example: and a hexagon shape.

The use process comprises the following steps: the worker rotates the handle 534 to drive the screw 51 to rotate, and at this time, the unit column 41 is fed from the lower opening of the feed chute 31; under the shape restriction of the screw 51 and the feed groove 31, the unit column 41 cannot rotate relative to the screw, and it can only move upward; the plurality of unit columns 41 are sequentially moved upward and fixed to each other by inserting to form a column structure, so that the probe 12 is fed to a designated height. Compared with a common telescopic rod structure, the telescopic rod can be split into a plurality of unit columns 41 which are arranged in the box body to be stacked and stored, so that the telescopic rod is relatively convenient to move and carry.

Referring to fig. 5, in order to prevent the unit posts 41, which are pushed out of the feed slot 31 but have not yet been inserted into the lower unit posts 41, from moving laterally and affecting the effect of use, a stopper plate 61 is fixed to the upper seat surface of the mount 3 around the upper opening of the feed slot 31.

Referring to fig. 2, to facilitate the feeding of the unit column 41 into the feeding groove 31 (indicated in fig. 5), a guide plate 62 is provided on the lower seat surface of the mounting base 3 around the lower opening of the feeding groove 31, and the lower end of the guide plate 62 is inclined toward the side away from the central axis of the mounting base 3, and is formed to surround a trumpet-shaped structure with the trumpet facing downward.

Referring to fig. 3 and 4, in order to enhance the structural strength of the long column, one unit column 41 is selected as the uppermost column, the probe 12 is mounted and fixed thereon, the lower end surface of the unit column 41 is fixed with a connecting rope 42, and the remaining unit columns 41 are all provided with rope penetrating holes 43 along the length direction; a clamping groove 44 is formed on the lower end surface of the unit column 41 around the rope passing hole 43, and the clamping groove 44 is transversely communicated with the rope passing hole 43 and is a lower opening.

Referring to fig. 4 and 8, the present invention further includes a plurality of clamping groups 7, each clamping group 7 includes two clamping blocks 71 that are matched with each other, one of the opposite side surfaces of the two clamping blocks 71 is formed with a clamping column 72, and the other side surface is provided with a clamping hole 73 that fits the clamping column 72.

During the use, a plurality of unit post 41 are pegged graft each other fixedly, connect rope 42 this moment and pass and it is fixed by two clamp splice 71 centre gripping (two clamp splice 71 side indent in opposite directions and form and splice the hole that slightly is less than the rope 42 diameter of connecting) from the rope handling hole 43 of each unit post 41, clamp splice 71 is arranged in draw-in groove 44, strengthens the fixed slot through connecting rope 42 between a plurality of unit posts 41 this moment to structural strength is higher relatively.

The above description is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention, and are considered to be within the scope of the invention.

Claims

1. The utility model provides a mobile monitoring device of basic station electromagnetic radiation environment, includes measuring apparatu body (1), measuring apparatu body (1) includes organism (11) and coupling probe (12) at the signal input part of organism (11), its characterized in that: the device is characterized by further comprising a movable probe frame, the movable probe frame comprises a plurality of support legs (2), a mounting seat (3) arranged on the support legs (2) and a lifting rod group (4) movably connected to the mounting seat (3), a vertical through feeding groove (31) is formed in the mounting seat (3), the lifting rod group (4) comprises a unit column (41) matched with the feeding groove (31), a jack (411) is vertically formed in the upper end face of the unit column (41) when the unit column is used, the jack (412) matched with the jack (411) is fixed to the end face of the unit column, a pushing mechanism (5) used for sequentially pushing the unit columns (41) upwards from the lower opening of the feeding groove (31) is further arranged on the mounting seat (3), the probe (12) is fixed on the unit column (41), and the device is characterized in that,

the pushing mechanism (5) comprises a screw rod (51) which is arranged in a feeding groove (31) in a concentric mode, a connecting arm (52) is fixed to the inner wall of the feeding groove (31), the connecting arm (52) extends towards the center of the feeding groove (31) and is fixed to a connecting ring (521) at the end portion, an embedded groove (511) is formed in the circumferential direction of the screw rod (51) in a surrounding mode, the connecting ring (521) is sleeved with the screw rod (51) and is hidden in the embedded groove (511), a unit column (41) is of a hollow internal thread structure and is matched with the screw rod (51), a side opening (413) for the connecting arm (52) to pass through is formed in the outer wall of the unit column (41) in the length direction, the vertical projection of the feeding groove (31) is polygonal, and the pushing mechanism (5) further comprises a driving assembly (53) for driving the screw rod (51) to rotate;

the utility model discloses a driving assembly, including mount pad (3), drive pulley (531), drive belt (533), handle (534), drive assembly (53), drive pulley (532), drive belt (533) and drive belt (534) are fixed with the center pin in the upper end of screw rod (51), drive pulley (531) are fixed in pivot (512) with the center pin, drive pulley (532) rotate connect in the outer wall of mount pad (3) and with driven pulley (531) coplanar, drive belt (533) cover is located and is offered logical groove (32) that supply drive belt (533) to pass through on drive pulley (532) and driven pulley (531) and mount pad (3), handle (534) are fixed in drive pulley (532).

2. The mobile monitoring device of claim 1, wherein: and a limiting plate (61) is arranged on the upper seat surface of the mounting seat (3) around the upper opening of the feeding groove (31).

3. The mobile monitoring device of claim 1, wherein: the lower seat surface of the mounting seat (3) is provided with a guide plate (62) around the lower opening of the feeding groove (31), and the lower end of the guide plate (62) inclines towards one side of the central axis far away from the mounting seat (3).

4. The mobile monitoring device of claim 1, wherein: it is a plurality of divide one in unit post (41) as the top cylinder, probe (12) are fixed in the top cylinder, and the lower terminal surface of the top cylinder is fixed with connection rope (42), and other except that the top cylinder is outer seted up stringing hole (43) along length direction on unit post (41), mutually linked draw-in groove (44) have been seted up around stringing hole (43) to the lower terminal surface of unit post (41), draw-in groove (44) are open structure down, the joint has centre gripping group (7) in draw-in groove (44), centre gripping group (7) are including two clamp splice (71) of mutually supporting, two wherein one side of clamp splice (71) opposite side sets up card post (72), and the card hole (73) of agreeing with card post (72) are seted up to the opposite side, connect rope (42) by the centre gripping between two clamp splice (71).