KR102662880B1 - Electromagnetic waves monitoring system and monitoring position selecting method - Google Patents

Abstract

The present invention provides imaged electromagnetic wave exposure information and relates to a method for selecting the optimal site for electromagnetic wave monitoring in an electromagnetic interference area. The present invention relates to a measuring device that processes electromagnetic wave signals to generate measurement data and transmits the measured data to the measuring instrument. A measuring unit consisting of a control box that supplies power; a management server including a database that stores measurement data transmitted from the control box and a management program that processes the measurement data stored in the database to generate electromagnetic wave exposure information displayed along with the measurement time; and a display unit that receives electromagnetic wave exposure information from the management server and displays it.

Description

Electromagnetic waves monitoring system and monitoring position selecting method}

The present invention relates to an electromagnetic wave monitoring system and a method for selecting a monitoring location. More specifically, it relates to a method that provides imaged electromagnetic wave exposure information and can select the optimal location for electromagnetic wave monitoring in an electromagnetic wave mutual interference area.

Electromagnetic waves refer to a physical phenomenon in which a pair of electric and magnetic fields whose strength periodically changes are propagated through space. Among several types of electromagnetic waves, extremely low frequency (ELF), very low frequency (VLF), radio waves (RF), and microwaves (microwaves) ) are reported to cause headaches and various diseases.

Accordingly, standards for protecting the human body from electromagnetic waves are established for each frequency band, and various electromagnetic wave shielding measures are implemented for household appliances such as mobile phones and microwave ovens.

However, it is difficult to determine the frequency or intensity of exposure to electromagnetic waves generated from high-voltage transmission lines, transmission towers, switchboards of buildings or factories, base stations of mobile carriers, or data centers, etc., and civil complaints about electromagnetic wave damage may occur.

Accordingly, a device for monitoring broadband electromagnetic waves was introduced in Domestic Patent No. 10-1378837 (registration date: March 21, 2014).

The electromagnetic wave monitoring device includes an electromagnetic wave detection unit, a central processing unit that processes the electromagnetic wave signal detected by the detection unit, a power unit that supplies power for the operation of the detection unit and the central processing unit, and a server that stores and manages data processed by the central processing unit. It is characterized by being carried out.

However, the prior art is a technology that focuses on the accuracy of measurements of the electromagnetic wave detection unit, reduction of power consumption of the power source, and storage and management of data extracted from the measurements, and it is difficult for the general public to determine the level of electromagnetic wave harmfulness from the data.

Meanwhile, in order to increase data reliability, it is desirable to install the detection unit in a location adjacent to the electromagnetic wave generator, but it is difficult to select the optimal location in areas where multiple electromagnetic wave generators are gathered, such as where multiple transmission lines intersect.

KR 10-1378837 B1 2014.03.21.

The problem to be solved by the present invention is to provide an electromagnetic wave monitoring system that can easily determine electromagnetic wave exposure information, and to provide a method for selecting an electromagnetic wave monitoring location in an area where a plurality of electromagnetic wave sources are gathered.

The electromagnetic wave monitoring system of the present invention for solving the above problems includes a measuring unit consisting of a measuring device that processes electromagnetic wave signals to generate measurement data and a control box that transmits the measurement data and supplies power to the measuring device; a management server including a database that stores measurement data transmitted from the control box and a management program that processes the measurement data stored in the database to generate electromagnetic wave exposure information displayed along with the measurement time; and a display unit that receives electromagnetic wave exposure information from the management server and displays it.

In addition, the electromagnetic wave monitoring system of the present invention includes an antenna for receiving electromagnetic wave signals for each of the three axes, a band filter for filtering the electromagnetic wave signals, an AD converter for converting the filtered electromagnetic wave signals into digital signals, and the digital signals for each of the three axes. It is characterized in that it includes a control unit that adds up.

In addition, the electromagnetic wave monitoring system of the present invention is characterized in that the electromagnetic wave exposure amount information displayed on the display unit is displayed by imaging the maximum, minimum, and average values of the electromagnetic wave intensity for a certain period of time.

In addition, the electromagnetic wave monitoring location selection method of the present invention uses the electromagnetic wave monitoring system to select an electromagnetic wave monitoring location. The electromagnetic wave monitoring location is selected by installing a measuring unit at an intersection within the electromagnetic wave mutual interference area and performing measurement work, where After generating a daily effective peak curve that displays electromagnetic wave intensity by time zone using the obtained measurement data, preliminary installation to find the overlap time zone included in all effective peak curves above a predetermined lower limit intensity while overlapping multiple effective peak curves. step; During the overlapping time period obtained in the preliminary installation step, a mobile measurement operation is performed to measure the electromagnetic wave intensity using a portable electromagnetic wave meter along one side and the other side of the intersection, and the first point where the electromagnetic wave intensity is measured at the maximum on one side and the other side The first measurement step of selecting two points on the furnace where the electromagnetic wave intensity is measured at maximum; A second measurement step of performing a moving measurement operation along an extension line connecting points 1 and 2 selected in the first measurement step and selecting 3 points on the extension line where the electromagnetic wave intensity is measured at the maximum; And a main installation step in which electromagnetic wave monitoring work is started after installing the measurement unit at the three points selected in the secondary measurement step.

In addition, in the electromagnetic wave monitoring location selection method of the present invention, if the electromagnetic wave intensity at point 1 is greater than the intensity at point 2 in the secondary measurement step, starting from point 2 and performing a moving measurement in the direction of point 1, If the intensity of the electromagnetic wave is greater than the intensity of the electromagnetic wave at point 1, the measurement process starts from point 1 and moves toward point 2.

According to the electromagnetic wave monitoring system of the present invention, the current electromagnetic wave exposure status can be easily determined through a measuring instrument that generates measurement data and a management program that processes the measurement data to generate electromagnetic wave exposure information, making it easy to popularize the electromagnetic wave monitoring system. .

In addition, the electromagnetic wave monitoring location selection method of the present invention can select the optimal monitoring location within the interference area through a preliminary installation step of finding the overlap time zone by installing a measuring unit at an intersection within the electromagnetic wave mutual interference area, and thus the information provided by the electromagnetic wave monitoring system. Reliability can be increased.

1 is a configuration diagram showing an electromagnetic wave monitoring system according to the present invention.
Figure 2 is a diagram showing an embodiment of the display unit of the electromagnetic wave monitoring system according to the present invention.
Figure 3 is a block flow diagram showing a method for selecting an electromagnetic wave monitoring location according to the present invention.
Figure 4 is a plan view illustrating an electromagnetic wave mutual interference area.
Figure 5 is a diagram illustrating a peak curve obtained in the preliminary installation stage of the electromagnetic wave monitoring location selection method according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the attached drawings.

Figure 1 is a configuration diagram showing an electromagnetic wave monitoring system according to the present invention, Figure 2 is a diagram showing an embodiment of the display unit of the electromagnetic wave monitoring system according to the present invention, and Figure 3 is a method for selecting an electromagnetic wave monitoring location according to the present invention. This is a block flow diagram showing.

Referring to FIGS. 1, 2, and 3, the present invention includes a measurement unit 10 that performs an electromagnetic wave measurement operation to obtain measurement data, a management server 20 that processes the measurement data to generate electromagnetic wave exposure information, and It consists of a display unit 30 on which the electromagnetic wave exposure amount information is displayed, and the electromagnetic wave exposure amount information is displayed in an image format.

Hereinafter, the specific details of the present invention will be described focusing on the above components. First, the measurement unit 10 includes a measuring device 11 that processes electromagnetic wave signals to generate measurement data, and transmits and transmits the measurement data to the measuring device 11. It consists of a control box (12) that supplies power.

In addition, the measuring unit 10 can be installed indoors or outdoors depending on the monitoring target (transmission line, switchgear, etc.). When installed outdoors, the measuring device 11 and the control box 12 each have a waterproof and dustproof case. It is disclosed as being built in and interconnected through cables.

In addition, depending on the monitoring target area, a plurality of measuring units 10 and display units 30 may be distributed across the target area for one management server 20. In this case, each measuring unit 10 is used for mutual identification. and the display unit 30 are assigned a unique number.

Meanwhile, the measuring device 11 includes an antenna, a band filter, an AD converter, a memory, and a control unit.

A 3-axis isotropic antenna is mainly used as the antenna, and the electromagnetic wave signals detected for each 3 axis are band-filtered at set measurement time intervals (1.5, 3, 10, 15, 30, 60, 180, 300, 600 sec). filtered through. Then, the filtered signal is converted into a digital signal through an AD converter, and then the digital signals for each of the three axes are summed in the control unit, and the measurement data collected from the summed measurements by time period is temporarily stored in memory.

Meanwhile, the bandwidth of the band filter can be arbitrarily set within 40 to 800 Hz, and the setting standard is determined depending on the monitoring target (transmission line, switchgear, etc.).

The control box 12 consists of a communication modem and a power unit that transmits the measurement data stored in the memory to the management server 20. Additionally, the power unit is either rechargeable or externally powered, and in the case of the rechargeable type, a battery is additionally provided.

The management server 20 includes a database and a management program.

The database stores measurement data transmitted from the communication modem, and when a unique number is designated, it is stored for each unique number.

The management program processes the measurement data stored in the database to generate electromagnetic wave exposure information displayed along with the measurement time, and the generated electromagnetic wave exposure information is transmitted to the display unit 30.

The display unit 30 is a component that displays electromagnetic wave exposure information transmitted from the management server 20, and can be provided in the form of a PC monitor or TV monitor, and is provided in the form of a stand monitor 31 as shown in FIG. 2. It could be.

The electromagnetic wave exposure information displayed on the stand monitor 31, etc. images the maximum, minimum, and average values of the electromagnetic wave intensity over a certain period of time in an image that is easy for the general public to understand. For example, as shown in FIG. 3, the current electromagnetic wave level is set to the human body protection standard ( 83.3 μT), whether it is safe, normal, or dangerous can be expressed with a smiling face, normal face, or frowning face.

As mentioned earlier, in areas where multiple electromagnetic wave sources are gathered, such as where transmission lines intersect, it is difficult to select the optimal location due to mutual interference of electromagnetic waves.

For example, as shown in FIG. 4, the point directly below the intersection (m) of the transmission line (M) may not be the maximum electromagnetic wave exposure area, and the electromagnetic wave intensity also changes from time to time.

Therefore, when measuring the electromagnetic wave intensity around the interference area with a portable electromagnetic wave meter to select the optimal location for installing the measuring unit 10, an inappropriate location may be selected if the measurement time period is an electromagnetic wave inactive time period.

Accordingly, in the present invention, the electromagnetic wave monitoring system can be used to select the optimal monitoring site in the electromagnetic wave mutual interference area, and the specific selection method includes the preliminary installation step (S10) and the first measurement step (S20) as shown in FIG. 3. , consists of a secondary measurement step (S30) and a main installation step (S40).

First, in the preliminary installation stage (S10), the measurement unit (10) is installed near the intersection (C) in the mutual interference area and measurement work is performed for several days, and the daily peak electromagnetic wave intensity is displayed by time zone using the measurement data obtained here. Find the curve.

This daily peak curve consists of an effective peak curve that occurs at a certain time every day along with an unspecified peak curve that occurs intermittently, and multiple daily peak curves obtained over several days are overlapped on a daily basis.

For example, when measurement work was performed over 3 days, as shown in Figure 5, the peak curve is an unspecified peak curve (p, p'), an effective peak curve H ₁ (t) on the 1st day, and an effective peak on the 2nd day. The curve H ₂ (t) and the 3rd day effective peak curve H ₃ (t) are shown in an overlapping state, and through this, the overlap time zone (ΔT) included in all effective peak curves above a predetermined lower limit intensity (H _min ) is shown. You can get it.
Here, the lower limit intensity (Hmin) is determined within a predetermined range of the aforementioned human body protection standard (83.3 μT).

In the first measurement stage (S20), the electromagnetic wave intensity is measured using a portable electromagnetic wave measuring instrument along one side road (X) and the other side road (Y) of the intersection (C) in the overlap time zone (ΔT) obtained in the preliminary installation stage (S10). Perform mobile measurement tasks.

In addition, during the mobile measurement process, one point (X _max ) where the electromagnetic wave intensity is measured to a maximum on one side of the path (X) and two points (Y _max ) where the electromagnetic wave intensity is measured to a maximum on the other side of the path (Y) are selected. do.

Here, an orthogonal intersection is recommended as the intersection (C), but is not limited thereto.

In the second measurement step (S30), a moving measurement operation is performed along the extension line (Z) connecting point 1 (X _max ) and point 2 (Y _max ) selected in the first measurement step (S20), and the extension line (Z) Select three points (Z _max ) where the electromagnetic wave intensity is measured to be maximum.

Here _{, if} the electromagnetic wave intensity _at point 1 ₍ If the strength of Y _max ) is large, start from point 1 (X _max ) and proceed with work in the direction of point 2 (Y _max ).

In the main installation step (S40), the measurement unit (10) is installed at the 3 points (Z _max ) selected in the second measurement step (S30), and the stand monitor (31) is installed at a point with a large floating population, such as an intersection (C). After installation, normal electromagnetic wave monitoring work begins.

Although the preferred embodiments of the present invention have been described above, the scope of the rights of the present invention is not limited thereto, and it should be understood that the scope of the rights of the present invention extends to the scope substantially equivalent to the embodiments of the present invention. Various modifications can be made by those skilled in the art without departing from the spirit of the invention.

10: Measuring part
11: Instrument
12: Control box
20: Management server
30: display unit
31: stand monitor

Claims (5)

delete delete delete A measurement unit 10 consisting of a measuring device 11 that processes electromagnetic signals to generate measurement data and a control box 12 that transmits the measurement data and supplies power to the measuring device 11;
A management server 20 including a database storing the measurement data transmitted from the control box 12 and a management program for processing the measurement data stored in the database to generate electromagnetic wave exposure information displayed along with the measurement time; and
a display unit 30 that receives electromagnetic wave exposure information from the management server 20 and displays it;
The electromagnetic wave monitoring location is selected using an electromagnetic wave monitoring system consisting of,
The electromagnetic wave monitoring location selection is
The measuring unit 10 is set up at an intersection (C) in the electromagnetic wave mutual interference area and measurement work is performed, and a daily effective peak curve showing the electromagnetic wave intensity by time zone is generated using the measurement data obtained here, and then multiple effective peaks are measured. Preliminary installation step (S10) of calculating the overlap time zone (ΔT) included in all effective peak curves above a predetermined lower limit intensity (H _min ) while overlapping the curves;
By performing a mobile measurement operation to measure the electromagnetic wave intensity using a portable electromagnetic wave meter along one side road (X) and the other side road (Y) of the intersection (C) in the overlap time zone (ΔT) obtained in the preliminary installation step (S10), The first measurement step ( _S20 ) of selecting one point (X _max ) where the electromagnetic wave intensity is measured to a maximum on one side of the path ( );
By performing a moving measurement operation along the extension line (Z) connecting point 1 (X _max ) and point 2 (Y _max ) selected in the first measurement step (S20), the maximum electromagnetic wave intensity is measured on the extension line (Z). Second measurement step (S30) of selecting 3 points (Z _max ); and
A main installation step (S40) of installing the measurement unit 10 at the three points (Z _max ) selected in the second measurement step (S30) and then starting electromagnetic wave monitoring work;
An electromagnetic wave monitoring location selection method comprising:
According to clause 4,
In the second measurement step (S30), if the electromagnetic wave intensity at point 1 (X _max ) is greater than the intensity at point 2 (Y _max ), measurement starts from point 2 (Y _max ) and moves in the direction of point 1 (X _max ). While working, if the intensity of the electromagnetic waves at point 2 (Y _max ) is greater than the electromagnetic wave intensity at point 1 (X _max ), start from point 1 (X _max ) and proceed with the moving measurement work in the direction of point 2 (Y _max ). Electromagnetic wave monitoring location selection method, characterized in that.