KR101334722B1 - Electrical equipment electromagnetic measuring device and measuring method - Google Patents

Abstract

The present invention relates to an electrical equipment electromagnetic measuring device and a measuring method capable of including the accuracy of the measurement for the change of measurement condition and the interference of external elements by mixing different measurement methods by accurately obtaining the value of the magnetic field and the magnetic field of the electrical equipment. The electrical equipment electromagnetic measuring device comprises a high frequency oscillator for oscillating the high frequency and an analog signal supplied from a power source unit to a first amplifier and a frequency calculator; and a first sensor unit including a first, a second, a third electronic inducing sensor for measuring the electromagnetic from three directions by being installed at a X shaft, a Y shaft, and a Z shaft. The respective electromagnetic values measured by first, second, and third electronic inducing sensor of the first sensor unit are transmitted to the calculator by converting the electromagnetic values into the electric signals. The method guarantees the safety of the electromagnetic by displaying the electromagnetic values with analog or digital electromagnetic values on a display window. [Reference numerals] (10) Power unit;(10a) Sub-power unit;(11) Frequency counter;(12) First amplifier;(13) High-frequency oscillator;(21) First electronic inducement sensor;(22) Second electronic inducement sensor;(23) Third electronic inducement sensor;(30) Displayer;(31) Magnetic field modulator;(32) Calculator;(AA) Electronic device power source unit

Description

Electromagnetic measuring device and measuring method using the same {Electrical equipment electromagnetic measuring device and measuring method}

The present invention relates to an electromagnetic wave measuring device of an electric device, and in particular, by accurately grasp the electric and magnetic fields of electric devices used in daily life to induce the user's prior not to be exposed to the risk of electromagnetic waves, different measurement methods The present invention relates to an electromagnetic wave measuring apparatus of an electrical apparatus and a measuring method using the same, which have a measurement accuracy with respect to the interference of an external element and the change of the measurement condition by using a mixed measurement.

In general, the original name of electromagnetic waves is called electromagnetic waves, which are called electromagnetic waves, and are a kind of electromagnetic energy generated from the flow of electricity and magnetism. It is referred to as electromagnetic waves because the electric and magnetic fields repeatedly spread like waves.

In addition, electromagnetic waves are transverse waves, like waves in the ocean or strings of string instruments. All electromagnetic waves have amplitude, wavelength, velocity, and frequency. Originally called electromagnetic waves, these are called electromagnetic waves. It is a wave composed of branch components, and propagates a space at an optical speed.

Frequently, electromagnetic waves are so close to us that there is no place not only in the electronic products we use, but also throughout the life such as transportation means such as subways and mobile phones, and also occurs in power lines widely distributed in our living environment. Doing. In addition, almost all environments such as homes, schools, and workplaces are exposed to electromagnetic waves.

In particular, there are two main effects of the human body due to electromagnetic waves, which can be classified into exothermic effects generated when energy is absorbed into tissues and non-exothermic effects generated by effects such as impact or ionization on cell membranes.

Among them, electronic devices and general electrical facilities that are exposed a lot in our living environment are extremely low frequency of less than 100Hz, and if they are accumulated in the human body for a long time, they may cause fatal diseases such as brain cancer, leukemia, breast cancer, lymphadenopathy cancers after several decades. Headache, dizziness, muscle pain and increased stress have been reported.

Looking at the kind of the electromagnetic wave, it is shown in Table 1 below.

One Microwaves Mobile phone, satellite TV and communication, microwave 2 Microwave (UHF) TV Broadcasting, Digital TV Broadcasting 3 Microwave (VH) FM radio broadcast, Radio controlled models 4 Short wave Police radio, aircraft radio 5 Medium wave AM radio broadcasting 6 Long wave AM Radio Broadcasting for Coast and Ships

Such electromagnetic waves may be expressed as electric and magnetic fields, but when expressed as electric fields, V (volts) and magnetic fields are G (gaussian). For example, 3 mV / m (meters) represents 0.003 volts per meter, and 3 mG / m means 0.001 G (gauss) per meter. Normally, all countries in the world test and regulate with electric fields and measure the law to ensure the reproducibility of the measurement.

As described above, devices that measure various electromagnetic waves due to the harmfulness of electromagnetic waves have been proposed due to their necessity in real life.

However, the device for measuring the electromagnetic wave is configured in such a way that one measuring method is used, the reliability of the measured value for the electromagnetic wave measurement is underestimated, and the measuring range according to the limit range of the measuring range which is characteristic for the measuring methods of different measuring methods. At the same time, the measurement was not possible at the same time the measured value is different, there was a problem that the error rate is not generated, the realistic measurement effectiveness.

Thus, by calculating the average of the sum of the values measured in various measurement directions as an average, it is possible to accurately determine the average value of the electromagnetic wave values measured differently in each zone of the electronic device, and the accuracy and stability of the measurement using two or more types of complex measurement methods There is an urgent need for an electromagnetic wave measuring device that can improve the reliability of measurement by securing the accuracy.

1. Publication No. 2001-0068151 (Handheld electromagnetic wave measuring device providing safety distance information) 2. Publication No. 10-2008-0028007 (electromagnetic wave measuring device for mobile phone) 3. Publication No. 2002-0074593 (Digital Electromagnetic Wave Meter for Environmental Evaluation)

Accordingly, the present invention has been made in view of the problems of the prior art as described above, and measures the average value of the directionality of electromagnetic waves generated in an electric device through a mixed measurement in one or three directions, one direction and three directions. An object of the present invention is to provide an electromagnetic wave measuring apparatus and a measuring method using the same.

In addition, another object of the present invention is to measure the measured value in accordance with the measurement range and the measurement characteristics by converting the magnetic induction method and the Hall effect method mixed to the average value.

In addition, another object of the present invention is to display the electric field and magnetic field constituting the electromagnetic wave in a digital value, so that it is easy to check and display a lamp, warning sound, and action tips for the danger of the electromagnetic wave.

In addition, another object of the present invention is to be applicable to all the electric devices that operate with electricity to be applicable to the existing electric devices in everyday life or industrial sites to increase the utilization.

In order to achieve the above object, the present invention provides a device for measuring electromagnetic waves generated by an electric device operating using electricity in home, medical, and industrial fields, the electricity being supplied through a power supply unit for receiving power of the electric device. It consists of a high frequency oscillator which transmits the analog signal to the frequency counter and the first amplifier and oscillates high frequency, receives the signal of the high frequency oscillator, and is installed in the X-axis, Y-axis, and Z-axis directions on the center line of the electric equipment. And a first sensor part comprising first to third electromagnetic induction sensors measuring electromagnetic waves in three directions, and measuring X, Y, and Z axes on the first and third electromagnetic induction sensors of the first sensor part. The measured modulation value changed by the magnetic field modulator and the electric signal amplified by the first amplifier are transferred to the calculator to calculate the electric field (V) value and the magnetic field (G) value. Using electromagnetic measurements of the electrical device, characterized in that configured to display the analog value to a digital value in the electromagnetic Sight device and this provides a measurement method.

As described above, the present invention has the effect of improving the accuracy of the measured value by measuring the average value for the directionality of the electromagnetic waves generated in the electrical device through the measurement in one or three directions, mixed in one and three directions.

In addition, the magnetic induction method and the hall effect method are used in combination to improve the reliability of the measured value by converting the measured value according to the measurement range and the measurement characteristic into an average value.

In addition, it is easy to check by displaying the electric and magnetic fields that make up electromagnetic waves in digital values, and it is possible to display the lamp, warning sound, and behavioral hazards of the electromagnetic waves so that non-professionals can safely and conveniently use them in their daily lives. There is.

In addition, since it can be applied to all electric devices that operate with electricity, it can be applied to existing electric devices in everyday life or industrial sites, and thus can be applied without any structural change by increasing the utilization, thereby reducing the installation cost.

1 is a configuration diagram of an electromagnetic wave measuring apparatus 100A of an electric apparatus according to the present invention;
2 is a front view of an electromagnetic wave measuring apparatus 100A of an electric apparatus according to the present invention;
3 is a configuration diagram of an electromagnetic wave measuring apparatus 100B of an electric apparatus according to the present invention;
4 is a front view of an electromagnetic wave measuring apparatus 100B of an electric apparatus according to the present invention;
5 is a configuration diagram of an electromagnetic wave measuring apparatus 100C of an electric apparatus according to the present invention;
6 is a front view of the electromagnetic wave measuring apparatus 100C of the electric apparatus according to the present invention,
7 is a configuration diagram of an electromagnetic wave measuring apparatus 100D of an electric apparatus according to the present invention;
8 is a front view of an electromagnetic wave measuring apparatus 100D of an electric apparatus according to the present invention;
9 is a schematic configuration diagram of an electromagnetic induction sensor according to the present invention;
10 is a front view of the measuring apparatus according to the present invention applied to a microwave oven,
11 is a partial perspective view of the measuring apparatus 100A according to the present invention applied to a microwave oven,
12 is a partial perspective view of the measuring apparatus 100C according to the present invention applied to a microwave oven,
13 is a partial sectional view in which the measuring apparatus 100A according to the present invention is applied to a microwave oven,
14 is a partial cross-sectional view of a measuring apparatus 100C according to the present invention applied to a microwave oven,
15 is a measurement flowchart of the measuring apparatus 100A according to the present invention;
16 is a measurement flowchart of the measuring apparatus 100C according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

1, 3, 5, and 7, the electromagnetic wave measuring apparatus of the electric device of the present invention as an oscillation signal through the high frequency oscillator 13 applied through the power supply unit 10 of the electric device The first to third electromagnetic induction sensors 21, 22, and 23 using the electromagnetic induction method measure electromagnetic waves in three directions of the electric device, and display values of the electric field V and the magnetic field G on the display window 30. Measuring device 100A; A measuring device (100B) for measuring unidirectional electromagnetic waves using only the first electromagnetic induction sensor (21) in the same configuration as the measuring device (100A); The first electromagnetic induction sensor 21 using the electromagnetic induction method as an oscillation signal through the high frequency oscillator 13 supplied with the power of the electrical device through the power supply unit 10 to measure electromagnetic waves in one direction of the electrical device, and the power supply unit 10 The first to third Hall effect sensors (51, 52, 53) using the Hall effect method and measuring the electromagnetic waves in three directions of the electrical device to receive the power of the electric power (V) and magnetic field (G) A measuring device 100C displayed on the display window 30; In the same configuration as the measuring apparatus 100C, the measuring apparatus 100D measures the first electromagnetic induction sensor 21 unidirectional electromagnetic waves using only the first hall effect sensor 51.

As shown in FIGS. 1 and 2, the measuring device 100A transmits an analog signal of electricity supplied through a power supply unit 10 to which electric power is applied, and includes a frequency counter 11 and a first amplifier 12. The high frequency oscillator 13 which transmits and oscillates a high frequency is comprised.

In addition, the first to third electromagnetic induction sensor 21 receiving the signal of the high-frequency oscillator 13 and installed in the X-axis, Y-axis, Z-axis direction on the center line of the electric equipment, respectively, to measure the electromagnetic wave in three directions by the electromagnetic induction method A first sensor unit 20 consisting of 22) and 23) is constituted.

In addition, the magnetic field modulator 31 displays the electromagnetic values on the X-axis, Y-axis, and Z-axis lines measured by the first to third electromagnetic induction sensors 21, 22, and 23 of the first sensor unit 20. The changed measurement modulation value and the electric signal amplified by the first amplifier 12 are transferred to the calculator 32 to be converted into an electric field (V) value and a magnetic field (G) value to convert the analog electromagnetic wave value into a digital value in the display window 30. Configure to display.

On the other hand, the measuring device (100B) is configured to measure the first sensor unit 20 with one first electromagnetic induction sensor (21), the measuring device (100A) to the number of electromagnetic induction sensors to three It is made up.

Commonly, the measuring device 100A, 100B includes a power supply unit 10, a frequency counter 11, a first amplifier 12, a high frequency oscillator 13, a first sensor unit 20, and a magnetic field modulator 31. The calculator 32 and the display window 30 may all be configured by a circuit connection method on a separate PCB board 60.

At this time, the power supply unit 10 is a configuration for receiving the power for driving the measuring device (100A) (100B) when the power is applied to the electrical equipment, the frequency counter 11 for determining the frequency of the electrical signal The first amplifier 12 is configured to amplify an electrical signal, the high frequency oscillator 13 is configured to oscillate an electrical signal at a high frequency, and the first sensor unit 20 has three electromagnetic induction sensors, respectively. Measurement of three-way electromagnetic waves by using and one-way electromagnetic waves using one electromagnetic induction sensor, the magnetic field modulator 31 is a configuration for modulating the electromagnetic wave signal measured by the first sensor unit 20, the calculator Reference numeral 32 is a configuration for converting the amplified signal of the first amplifier 12 and the analog signal of the modulated electromagnetic wave value of the magnetic field modulator 31 into a digital signal, the display window 30 is a digital signal received from the calculator 32 It is the configuration to display by value.

The first electromagnetic induction sensor 21 of the first to third electromagnetic induction sensors 21, 22, 23 constituting the first sensor unit 20 of the measuring device 100A is a PCB substrate 60. The second and third electromagnetic induction sensors 22 and 23 are connected to the power line 61 from the PCB 60 and connected to the Y-axis line in the electronic device. It is configured to be installed in the Z-axis linear direction.

3 and 4, the first electromagnetic induction sensor 21 constituting the measuring device (100B) is to measure the electromagnetic wave only in one direction is installed by connecting to the PCB substrate (60) Would be preferred.

1 and 2, the first sensor unit 20 of the measuring device (100A) is configured to cover a portion and the shielding means 40 to expose the remaining portion.

That is, the first to third electromagnetic induction sensors 21, 22 and 23 of the first sensor unit 20 constituting the measuring device 100A may be connected to another electrical device near the electrical device to measure electromagnetic waves. When installed, the first to third electromagnetic induction sensors 21, 22, and 23 may be affected by electromagnetic waves generated by other electrical devices, so that the shielding means 40 may be minimized. By using the first to third electromagnetic induction sensors 21, 22, 23 is configured to shield the surface facing the outside of the electrical device to measure the electromagnetic wave and the surface facing the inside.

At this time, the shielding means 40 forms a semi-cylindrical shielding film 41 in a form that can cover the first to third electromagnetic induction sensors 21, 22, 23, one side of the shielding film 41 As one or more fixed end 42 to be fixed to the electrical device and the PCB board 60 is made of a non-conductive material such as Teflon.

In addition, the display window 30 is configured to simultaneously or selectively display the electromagnetic wave value by the electric field (V) value and the magnetic field (G) value measured by the electric device.

In addition, the display window 30 may be configured to display a warning lamp, a warning sound or a safety distance display when an electromagnetic wave value exceeding a reference value is measured.

The display window 30 is configured to be installed on one side of the PCB substrate 60 so as to be exposed to the outside of the electric device, the display window 30 may be configured as an LED panel or an LCD panel.

In addition, the display window 30 has a power button 30a for controlling the power supply and shut-off of the power supply unit 10, a time button 30b for indicating the time for measuring the current electromagnetic wave, and confirming the current measured electromagnetic wave value. Hold button (30c) for fixing, the electric field button (30d) for displaying the electric field value, the magnetic field button (30e) for displaying the magnetic field value, respectively in the first to third electromagnetic induction sensors (21) (22) (23) The X value button (X), the Y value button (Y), and the Z value button (Z) for displaying each measured value alone are configured to be functionally connected.

That is, the power button 30a, time button 30b, hold button 30c, electric field button 30d, magnetic field button 30e, X value button (X), Y value button (Y), Z value button (Z) is installed at each lower portion of the PCB substrate 60, the display window 30 is installed is configured to transmit a control signal to the display window (30).

In detail, the display window 30 indicates a power remaining amount zone A indicating a charge amount of the auxiliary power supply 10a that appears when the power button 30a is pressed, continuously displaying the current time, or indicating a time that appears when the time button 30b is pressed. When the time display zone (B) and the hold button (30c) are pressed, an electric field display zone (C) showing a measured electric field value at any time and a magnetic field display zone (D) showing a magnetic field measurement value are respectively formed. When the X value button (X), Y value button (Y), and Z value button (Z) are pressed, the respective electromagnetic wave measured values measured by the first to third electromagnetic induction sensors 21 (22) and 23 are applied to the electric field. It is configured to be displayed as a separate measured value display zone (E), which is divided into a magnetic field and a magnetic field, a warning lamp zone (F) for emitting a warning light, and a safety distance display zone (G) for a safe distance, which is a harmless range of electromagnetic waves. do.

In addition, the buzzer 30-1 is configured at one side of the PCB substrate 60 to generate a warning sound.

In addition, the power supply unit 10 constitutes an auxiliary power supply unit 10a for temporarily storing power, and the auxiliary power supply unit 10a does not operate an electric device but measures an electromagnetic wave while only an electric cord is connected to the power button ( Press 30a) to supply power for measurement by receiving power from the auxiliary power supply 10a.

As shown in FIG. 9, the first to third electromagnetic induction sensors 21 and 22 and 23 are paired on both sides of the high frequency coil 20a receiving the oscillation signal of the high frequency oscillator 13. The magnetic field generated between the magnetometer 20b and the electromagnet 20c is based on Faraday's law of electromagnetic induction and uses the electromotive force induced by the high frequency coil 20a according to the rate of change of the magnetic flux Φ. It is configured to connect with the magnetic flux meter 20b to measure and deliver the measured value to the magnetic field modulator 31.

As shown in FIG. 5 and FIG. 6, the measuring device (100C) is a frequency counter 11 and the first amplifier 12 of the analog signal of electricity supplied through the power supply unit 10 receives the power of the electrical equipment The high frequency oscillator 13 which transmits and oscillates a high frequency is comprised.

In addition, the first sensor unit 20 is configured to be unidirectionally measured by the first electromagnetic induction sensor 21 which receives the signal of the high frequency oscillator 13 and is installed at one side of the electric device to measure the electromagnetic wave by the electromagnetic induction method.

In addition, the electric signal is received from the power supply unit 10 and is installed in the X-axis, Y-axis, and Z-axis directions based on the first sensor unit 20, respectively, and measures electromagnetic waves in three directions by a Hall effect method. A second sensor unit 50 composed of the first to third Hall effect sensors 51, 52 and 53 is configured.

In addition, the measurement modulated value obtained by changing the electromagnetic wave value measured by the first electromagnetic induction sensor 21 of the first sensor unit 20 by the magnetic field modulator 31, the amplified signal of the first amplifier 12 and the first ~. Due to the three-hole effect sensors 51, 52 and 53, the electromagnetic wave values measured on the X-axis, Y-axis, and Z-axis are amplified by the second amplifier 54 and transmitted to the calculator 32 to transmit the electric field (V). By calculating the value and the magnetic field G value, the display window 30 is configured to display the analog electromagnetic wave value as a digital value.

As shown in FIG. 7 and FIG. 8, the measuring device 100D is configured such that the second sensor unit 50 includes one first hall effect sensor 51 to measure unidirectionally. Is composed of three Hall effect sensors while the measuring device (100D) is composed of one Hall effect sensor.

Commonly, the measuring devices 100C and 100D include a power supply unit 10, a frequency counter 11, a first amplifier 12, a high frequency oscillator 13, a first sensor unit 20, and a magnetic field modulator 31. The second sensor unit 50, the second amplifier 54, the calculator 32, and the display window 30 may all be configured in a circuit connection method on a separate PCB board 60.

At this time, the power supply unit 10 is a configuration for receiving the power for driving the measuring device (100A) (100B) when the power is applied to the electrical equipment, the frequency counter 11 for determining the frequency of the electrical signal The first amplifier 12 is configured to amplify an electrical signal, the high frequency oscillator 13 is configured to oscillate an electrical signal at a high frequency, and the first sensor unit 20 uses one electromagnetic induction sensor. The magnetic field modulator 31 is configured to modulate the electromagnetic wave signal measured by the first sensor unit 20, and the second sensor unit 50 uses three Hall effect sensors. The unidirectional electromagnetic wave is measured by using the three-way electromagnetic wave measurement and one Hall effect sensor, and the second amplifier 54 is configured to amplify the electromagnetic wave signal measured by the second sensor unit 50. ) Is the amplified signal of the first amplifier (12) and the magnetic field modulator (31) Modulated electromagnetic wave value, and a second configuration to convert the analog signal from the amplified signal is passed to the amplifier 54 into a digital signal, the display 30 is configured to display a signal transmitted from the computing unit 32 into a digital value.

The first to third Hall effect sensors 51, 52 and 53 constituting the second sensor unit 50 of the measuring device 100C are connected to the power line 61 on the PCB 60. It is configured to be installed in any X-axis, Y-axis, Z-axis direction inside the electronic device.

At this time, the first electromagnetic induction sensor 21 constituting the measuring device (100D) is to measure the electromagnetic wave only in one direction to be fixed to the PCB substrate 60 or installed at any point of the electrical equipment Would be preferred.

The first to third Hall effect sensors 51, 52, and 53 of the first electromagnetic induction sensor 21 and the second sensor unit 50 of the first sensor unit 20 of the measuring device 100C. And the first electromagnetic induction sensor 21 of the first sensor unit 20 of the measuring device 100D and the first hall effect sensor 51 of the second sensor unit 50 shield a part and expose the remaining part. It is configured to cover with the shielding means (40).

That is, the first to third Hall effect sensor 51 of the first electromagnetic induction sensor 21 and the second sensor unit 50 of the first sensor unit 20 constituting the measuring device (100C) (100D) ( 52) 53 or the first Hall effect sensor 51 may be affected by electromagnetic waves generated by other electric devices when another electric device is installed near the electric device to measure electromagnetic waves. The first electromagnetic induction sensor 21 and the first and third Hall effect sensors 51, 52, and 53 are shielded by using the shielding means 40 so as to minimize the influence of electromagnetic waves of other electric devices. 1 to 3 Hall effect sensors 51, 52, 53 is configured to shield the surface facing the outside of the electrical equipment to measure the electromagnetic waves and to expose the surface facing toward the inside.

The first electromagnetic induction sensor 21 generates a pair of magnetic flux meters 20b and electromagnets 20c positioned between both sides of the high frequency coil 20a receiving the oscillation signal of the high frequency oscillator 13. The magnetic field is measured based on Faraday's law of electromagnetic induction, and the magnetic field is measured using the electromotive force induced in the high frequency coil 20a according to the rate of change of the magnetic flux Φ to transfer the measured value to the magnetic field modulator 31. It is connected with the magnetometer 20b.

At this time, the shielding means 40 forms a semi-cylindrical shielding film 41 in a form that can cover the first electromagnetic induction sensor 21 and the first to third Hall effect sensors 51, 52, 53. In addition, one side of the shielding film 41 is one or more fixed end 42 to be fixed to the electrical device and the PCB substrate 60 is made of a non-conductive material such as Teflon.

In addition, the display window 30 is configured to simultaneously or selectively display the electromagnetic wave value by the electric field (V) value and the magnetic field (G) value measured by the electric device.

In addition, the display window 30 may be configured to display a warning lamp, a warning sound or a safety distance display when an electromagnetic wave value exceeding a reference value is measured.

The display window 30 is configured to be installed on one side of the PCB substrate 60 so as to be exposed to the outside of the electric device, the display window 30 may be configured as an LED panel or an LCD panel.

In addition, the display window 30 has a power button 30a for controlling the power supply and shut-off of the power supply unit 10, a time button 30b for indicating the time for measuring the current electromagnetic wave, and confirming the current measured electromagnetic wave value. Hold button (30c) for fixing, the electric field button (30d) for displaying the electric field value, the magnetic field button (30e) for displaying the magnetic field value, respectively in the first to third electromagnetic induction sensors (21) (22) (23) The X value button (X), the Y value button (Y), and the Z value button (Z) for displaying each measured value alone are configured to be functionally connected.

That is, the power button 30a, time button 30b, hold button 30c, electric field button 30d, magnetic field button 30e, X value button (X), Y value button (Y), Z value button (Z) is installed at each lower portion of the PCB substrate 60, the display window 30 is installed is configured to transmit a control signal to the display window (30).

In detail, the display window 30 indicates a power remaining amount zone A indicating a charge amount of the auxiliary power supply 10a that appears when the power button 30a is pressed, continuously displaying the current time, or indicating a time that appears when the time button 30b is pressed. When the time display zone (B) and the hold button (30c) are pressed, an electric field display zone (C) showing a measured electric field value at any time and a magnetic field display zone (D) showing a magnetic field measurement value are respectively formed. When the X value button (X), Y value button (Y), and Z value button (Z) are pressed, the respective electromagnetic wave measured values measured by the first to third electromagnetic induction sensors 21 (22) and 23 are applied to the electric field. It is configured to be displayed as a separate measured value display zone (E), which is divided into a magnetic field and a magnetic field, a warning lamp zone (F) for emitting a warning light, and a safety distance display zone (G) for a safe distance, which is a harmless range of electromagnetic waves. do.

And, in order to generate a warning sound, the buzzer 30-1 is configured on one side of the PCB substrate 60.

In addition, the power supply unit 10 constitutes an auxiliary power supply unit 10a for temporarily storing power, and the auxiliary power supply unit 10a does not operate an electric device but measures an electromagnetic wave while only an electric cord is connected to the power button ( Press 30a) to supply power for measurement by receiving power from the auxiliary power supply 10a.

As shown in FIG. 9, the first to third electromagnetic induction sensors 21 and 22 and 23 are paired on both sides of the high frequency coil 20a receiving the oscillation signal of the high frequency oscillator 13. The magnetic field generated between the magnetometer 20b and the electromagnet 20c is based on Faraday's law of electromagnetic induction and uses the electromotive force induced by the high frequency coil 20a according to the rate of change of the magnetic flux Φ. It is configured to connect with the magnetic flux meter 20b to measure and deliver the measured value to the magnetic field modulator 31.

The operation and effect of the present invention constructed as described above will be described below.

First, the electric device will be described as an example of applying and installing measuring devices 100A, 100B, 100C, and 100D to the microwave oven 200 that is most closely used in daily life among various devices.

In addition, the measurement apparatuses 100A, 100B, 100C, and 100D may be installed inside the microwave oven 200 to the side where the operation panel 201 of the microwave oven 200 is installed, but the display window 30 and Various buttons are installed to be exposed to the outside.

As shown in FIGS. 10, 11, 13, and 15, the first electromagnetic induction sensor 21 of the first sensor unit 20 constituting the measuring device 100A is connected to the PCB substrate 60. The microwave oven 200 is installed to be positioned on the X-axis line in the microwave oven 200 in the state, and the second and third electromagnetic induction sensors 22 and 23 are positioned on the Y-axis line and the Z-axis line, respectively. Installed on the inner surface of the outer panel 202 of each of the X-axis, Y-axis, and Z-axis are installed to measure the electromagnetic waves in three directions.

On the other hand, the measuring device 100B is installed so that the first electromagnetic induction sensor 21 of the first sensor unit 20 is located on the X-axis line inside the microwave oven 200 while being connected to the PCB substrate 60. To measure electromagnetic waves in one direction.

In this case, the first to third electromagnetic induction sensors 21, 22, 23 are shielded by using the shielding means 40 so as not to be affected by other electromagnetic waves acting on the outside of the microwave oven 200, and accurate measured values. There is a characteristic to ensure the stability of the calculation and measurement of.

First, the electromagnetic wave measuring method of the measuring apparatus 100A will be described. The electric power is applied to the microwave oven 200 which is an electric device to measure the electromagnetic wave value.

Subsequently, when the power applied to the microwave oven 200 is supplied to the power supply unit 10, the high frequency oscillator 13 oscillates and at the same time the frequency counter 11 counts the frequency of the electric signal, and in the first amplifier 12, Amplify the frequency of the electrical signal.

At the same time, the signal oscillated by the high frequency oscillator 13 is transmitted to the first to third electromagnetic induction sensors 21, 22 and 23, and the first to third electromagnetic induction sensors 21 to receive the oscillation signal ( 22 and 23 measure the electromagnetic waves generated when the magnetron oscillating the microwave to heat the food when the microwave oven 200 is operated.

At this time, the measuring principle of the first to third electromagnetic induction sensors 21, 22, 23 is that the oscillation signal of the high frequency oscillator 13 is respectively the first to third electromagnetic induction sensors 21, 22, 23. When the magnetic field generated between the pair of magnetic flux meters 20b and the electromagnet 20c positioned at both sides of the high frequency coil 20a is transmitted to the high frequency coil 20a positioned inside the magnetic field, the Faraday electromagnetic induction. Based on the law, the magnetic field is measured using electromotive force induced in the high frequency coil 20a according to the rate of change of the magnetic flux Φ.

Such a method using the first to third electromagnetic induction sensors 21, 22 and 23 does not require calibration because it uses physical inherent phenomena, and is commonly used as a magnetic field standard in combination with an electromagnet system. It is characterized by 1 × 10 ^-2 to 15 T and resolution of about 10 ^-8 T.

In this way, the first to third electromagnetic induction sensors (21, 22, 23) measures the electromagnetic wave values on the X-axis, Y-axis, Z-axis line inside the microwave oven 200.

Next, the magnetic field modulator 31 connected to the magnetic flux meter 20b is used to transfer the electromagnetic values on the X-axis, Y-axis, and Z-axis lines measured by the first to third electromagnetic induction sensors 21, 22, 23. Transfer the measured modulation value and the electric signal amplified by the first amplifier 12 by changing the electromagnetic wave value of the magnetic field measured from the first to third electromagnetic induction sensors 21, 22, 23 in the magnetic field modulator 31 Transfer to operator 32.

Next, the measurement modulated value and the amplified electric signal input to the calculator 32 are calculated as the electric field V value and the magnetic field G value, and the analog electromagnetic wave values are displayed on the display window 30 as digital values.

On the other hand, since the measuring device 100B uses only the first electromagnetic induction sensor 21, only the electromagnetic wave measurement value for the X axis may be measured and displayed on the display window 30.

10, 12, 14, and 16, look at the installation in the microwave oven 200 to measure the electromagnetic wave by using the measuring device (100C) as follows.

First, the first electromagnetic induction sensor 21 of the measuring device 100C is installed on the PCB substrate 60, and the first to third Hall effect sensors 51 of the second sensor unit 50 ( 52 and 53 are respectively disposed on the inner surface of the outer panel 202 of the microwave oven 200 so as to be positioned on the X axis line, the Y axis line, and the Z axis line, respectively, out of the line where the first electromagnetic induction sensor 21 is located. It is installed to measure electromagnetic waves in three directions of X, Y, and Z axes.

When the electromagnetic wave measuring method is described using the measuring apparatus 100C installed as described above, power is applied to the microwave oven 200 which is an electric device to measure the electromagnetic wave value.

Subsequently, when the power applied to the microwave oven 200 is supplied to the power supply unit 10, the high frequency oscillator 13 oscillates and at the same time the frequency counter 11 counts the frequency of the electric signal, and in the first amplifier 12, Amplify the frequency of the electrical signal.

At the same time, the signal oscillated by the high frequency oscillator 13 is transmitted to the first electromagnetic induction sensor 21, and the first electromagnetic induction sensor 21 receiving the oscillation signal is provided with food during operation of the microwave oven 200. The magnetron, which oscillates microwaves to heat it, measures the electromagnetic waves generated.

In this case, the measuring principle of the first electromagnetic induction sensor 21 is that when the oscillation signal of the high frequency oscillator 13 is transmitted to the high frequency coil 20a located in each of the first electromagnetic induction sensor 21, a high frequency coil ( Based on Faraday's law of electromagnetic induction, a magnetic field generated between a pair of magnetometers 20b and an electromagnet 20c positioned on both sides of 20a) has a high frequency coil ( The magnetic field is measured in one direction using electromotive force induced in 20a).

At the same time, the first to third Hall effect sensors 51 and 52 and 53 of the second sensor unit 50 are supplied with the power of the power supply unit 10 together with the operation of the microwave oven 200.

In this way, the electromagnetic measuring principle of the first to third Hall effect sensors 51, 52, 53, which are supplied with power, is a Hall effect method for measuring the potential difference (Hall voltage) across the conductor. By measuring the electromagnetic wave values on the X-axis, Y-axis, and Z-axis lines.

In detail, the Hall effect means that current flows through both ends of a metal or a semiconductor and a magnetic field is applied perpendicularly thereto, so that electrons or holes receive Lorentz force, and both ends in a direction perpendicular to the current and the magnetic field are charged. It will take on the inside of the battlefield is formed. When the force received by this electric field and Lorentz force are in equilibrium, the voltage generated at both ends is proportional to the magnetic field.

The magnetic field, which can be generally measured using the Hall effect, is about 1 × 10 ⁻⁵ to 30 T and the resolution is about 1 × 10 ⁻⁷ T.

The first to third Hall effect sensors 51 and 52 and 53 are easy to mass-produce, and the size of the Hall probe is small, so that the measurement is advantageous in a narrow place.

Next, the electronic device 32 transmits the measured modulation value of the electromagnetic wave value measured by the first electromagnetic induction sensor 21 and the electric signal amplified by the first amplifier 12 to the calculator 32. .

At the same time, the first and third Hall effect sensors 51, 52 and 53 amplify each electromagnetic wave value measured in the X-axis, Y-axis, and Z-axis by the second amplifier 54 to calculate the arithmetic operator 32. To pass.

Thereafter, the measured modulation value, the amplified electric signal, and the amplified electromagnetic wave value input to the calculator 32 are calculated as the electric field V value and the magnetic field G value, thereby converting the analog electromagnetic wave value into a digital value in the display window 30. To display.

In the meantime, the measuring device 100D maintains a state in which the first electromagnetic induction sensor 21 of the first sensor unit 20 is fixed to the PCB substrate 60 and the first hole of the second sensor unit 50. The effect sensor 51 may be installed at an arbitrary position inside the microwave oven 200 to measure electromagnetic waves in both directions together with the first electromagnetic induction sensor 21.

In this case, the first electromagnetic induction sensor 21 and the first to third Hall effect sensors 51, 52, 53 are shielded means 40 so as not to be affected by other electromagnetic waves acting from the outside of the microwave oven 200. Shielding using) ensures accurate measurement and the stability of the measurement.

Commonly, the measuring devices 100A, 100B, 100C, and 100D display the measured electromagnetic wave values on the display window 30, and operate the power button 30a to select the start and end of the measurement. There is a feature to choose from.

In addition, the measuring device (100A) (100B) (100C) (100D) is characterized in that the measured electromagnetic wave is divided into an electric field or a magnetic field in the display window 30 can be easily identified by non-professional, if necessary However, only the magnetic field value can be selectively displayed, which increases the convenience of use.

In addition, the measurement device 100A, 100B, 100C, 100D is a hold button 30c when the measured value is minutely changed according to the amount of current movement when the measured electromagnetic wave value is displayed on the display window 30. You can check the current displayed value by operating.

In addition, the measuring device (100A) (100B) (100C) (100D) is a display window by the operation of the program in advance if the measured electromagnetic wave value is out of the harmless range to the human body when the measured electromagnetic wave value is displayed on the display window (30) It also has a safety function that acts as a route lamp or generates a warning sound and displays a safety distance to alert the user or prevent exposure to electromagnetic waves.

In addition, the measurement device (100A) (100B) 100C (100D) is installed on the electric device is additionally attached to the detection sensor for detecting the human operation by the display window (if electromagnetic waves in the dangerous range occurs during operation of the electric device) 30) will be configured to activate the route lamp or generate a warning sound to indicate the safety distance.

In addition, the measuring apparatus (100A) (100C) is the electromagnetic wave by using the first to third electromagnetic induction sensor (21) (22) (23) and the first to third Hall effect sensor (51) (52) (53), respectively. Is measured in the X, Y, and Z directions, respectively, and the electric and magnetic fields that form electromagnetic waves are vectors having magnitude and direction as a kind of force formed in the air by electric charge and current, respectively. And when measuring the intensity of the magnetic field is to calculate the vector sum by measuring the respective intensities in the X-axis, Y-axis, Z-axis direction.

Here, Fx, Fy, and Fz representing the sum of electromagnetic wave vectors measured by the first to third electromagnetic induction sensors 21, 22 and 23 and the first to third Hall effect sensors 51, 52 and 53, respectively. Are the strengths of the electric or magnetic field on the X, Y, and Z axes, respectively, and the vector sum F can be expressed as shown on the graph, and the vector sum is calculated by the operator 32 and displayed on the display window 30. The preciseness and precision of the measurement can be improved by calculating accurate correction values by measuring different electromagnetic wave measurement values inside the target electronic device.

In addition, by measuring the electromagnetic waves in the X-axis, Y-axis, and Z-axis respectively, the first to third electromagnetic induction sensors 21, 22, 23 and the first to third Hall effect sensors 51, 52, 53 Since it calculates and displays the sum of electromagnetic waves within itself, it is convenient to measure only once at any point, and it is possible to know in which direction a lot of electromagnetic fields are generated depending on the magnitude of the sensor's measured values on the X, Y, and Z axes. There is a characteristic.

In addition, the magnetic field range of the electromagnetic wave that can be measured using the electromagnetic induction method of the electromagnetic induction method applied to the first to third electromagnetic induction sensors 21, 22, 23 is 10 ^-10 T or more, The magnetic field range of the electromagnetic wave that can be measured using the Hall effect measuring method applied to the 1 to 3 Hall effect sensors 51, 52 and 53 is about 1 x 10 ^-5 to 30 T, and the resolution is 1 x 10. ^{By about -7} T, it is possible to measure the electromagnetic waves generated by the electrical equipment to be measured at the same time using the different measurement ranges, it is characterized by the accurate measurement and the calculation of accurate measurement value and the measurement reliability is improved.

In addition, the measuring device (100A) (100B) is the first electromagnetic induction sensor (21) or the X value button (X), Y value button (Y), Z value button (Z) is pressed when pressing The measured electromagnetic wave value in the X-axis direction is displayed on the display window 30 by the first hall effect sensor 51, and when the Y value button Y is pressed, the second electromagnetic induction sensor 22 or the second hall effect sensor ( 52), the measured electromagnetic wave value in the Y-axis direction is displayed on the display window 30. When the Z value button Z is pressed, the Z-axis is driven by the third electromagnetic induction sensor 31 or the third hall effect sensor 53. The measured electromagnetic wave value for the direction is displayed on the display window 30 so that it is easy to check in which direction the electromagnetic wave is generated even in the measuring electronic device. There are features that can be.

In addition, the measuring device (100A) (100B) (100C) (100D) is used by changing the size and structure to all electrical devices that operate using electricity in home appliances, medical devices or industrial sites used in general households It can be.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Various changes and modifications may be made by those skilled in the art.

10: power supply unit 11: frequency counter
12: first amplifier 13: high frequency oscillator
20: first sensor unit 20a: high frequency coil
20b: magnetometer 20c: electromagnet
21: first electromagnetic induction sensor 22: second electromagnetic induction sensor
23: third electromagnetic induction sensor 30: display window
31: magnetic field modulator 32: calculator
30a: power button 30b: time button
30c: Hold button 30d: Electric field button
30e: magnetic field button 40: shielding means
41: shielding film 42: fixed end
50: second sensor unit 51: the first hall effect sensor
52: second hall effect sensor 53: third hall effect sensor
54: second amplifier 60: PCB board
61: power line 100A, 100B, 100C, 100D: measuring device
200: microwave oven 201: operation panel
202: External panel X: X value button
Y: Y value button Z: Z value button
A: Power remaining area B: Time display area
C: Electric field marking area D: Magnetic field marking area
E: Division measured value display area F: Warning lamp area
G: Safe Distance Marking Zone

Claims (20)

In the device for measuring the electromagnetic waves generated by the electrical equipment operating in the home, medical, industrial sector,
A high frequency oscillator 13 for transmitting an analog signal of electricity supplied through the power supply unit 10 receiving power of the electric device to the frequency counter 11 and the first amplifier 12 and oscillating high frequency;
The first to third electromagnetic induction sensor 21 to receive the signal of the high frequency oscillator 13 and are installed in the X-axis, Y-axis, Z-axis direction on the center line of the electrical equipment, respectively, and measure the electromagnetic wave in three directions by the electromagnetic induction method ( 22, 23 constitute a first sensor unit 20,
The magnetic field modulator 31 changes the values of electromagnetic waves on the X-, Y-, and Z-axis lines measured by the first to third electromagnetic induction sensors 21, 22, and 23 of the first sensor unit 20. The measured modulation value and the electric signal amplified by the first amplifier 12 are transferred to the calculator 32 to be calculated as the electric field V value and the magnetic field G value, and the analog electromagnetic wave values are displayed as digital values in the display window 30. Electromagnetic wave measuring apparatus of an electric device, characterized in that configured to.
The electromagnetic wave measuring apparatus of claim 1, wherein the first sensor unit comprises one first electromagnetic induction sensor 21.
The electromagnetic wave measuring apparatus of claim 1, wherein the first sensor unit 20 covers a part of the first sensor part and covers the remaining part with the shielding means 40 to expose the remaining part.
The display window (30) according to claim 1, wherein the display window (30) shows a power remaining amount zone (A) indicating a charge amount, a time display zone (B) continuously displaying the current time, and a hold button (30c). Measured by the first and third electromagnetic induction sensors 21 (22) and 23, and the magnetic field display zone (C) representing the measured electric field (V) value and the magnetic field display zone (D), which represent the measured value of the magnetic field (G). Separate measured value display area (E) for displaying each measured electromagnetic wave into electric field and magnetic field, warning lamp area for emitting warning light (F), and safety distance indication for safe distance which is harmless range of electromagnetic waves. Configure it to display as a zone (G),
One side of the display window 30 is installed, the electromagnetic wave measuring apparatus of the electric device, characterized in that configured to generate a warning sound when the electromagnetic wave value exceeding the reference value.
According to claim 1, wherein the power supply unit 10 constitutes an auxiliary power supply unit 10a for temporarily storing power,
The display window 30 has a power button (30a) for controlling the power supply and cutoff of the power supply unit 10, a time button (30b) for indicating the time to measure the current electromagnetic wave, fixed to confirm the current measured electromagnetic wave value Hold button 30c, the electric field button 30d for displaying the electric field value, the magnetic field button 30e for displaying the magnetic field value, respectively measured by the first to third electromagnetic induction sensors 21, 22, 23 The electromagnetic wave measuring apparatus of an electric apparatus, characterized in that the configuration is configured to functionally connect the X value button (X), Y value button (Y), Z value button (Z) for displaying the measured value alone.
In the device for measuring the electromagnetic waves generated by the electrical equipment operating in the home, medical, industrial sector,
A high frequency oscillator 13 for transmitting an analog signal of electricity supplied through the power supply unit 10 receiving power of the electric device to the frequency counter 11 and the first amplifier 12 and oscillating high frequency;
The first sensor unit 20 that can be unidirectionally measured by the first electromagnetic induction sensor 21 that receives the signal of the high-frequency oscillator 13 and is installed on one side of an electrical device to measure electromagnetic waves by an electromagnetic induction method,
The first signal receiving the electric signal of the power supply unit 10 and installed in the X-axis, Y-axis, Z-axis direction based on the first sensor unit 20, respectively, measuring the electromagnetic wave in three directions by the Hall effect (Hall effect) method And constitutes a second sensor unit 50 composed of ˜3 Hall effect sensors 51, 52, 53,
The measured modulation value of the electromagnetic wave modulator 31 of the first sensor unit 20 of the first sensor unit 20 is changed by the magnetic field modulator 31, the amplified signal of the first amplifier 12, and the first to third holes. Due to the effect sensors 51, 52 and 53, the electromagnetic wave values measured on the X-axis, Y-axis, and Z-axis are amplified by the second amplifier 54 and transmitted to the calculator 32 to transmit electric field (V) values and Electromagnetic wave measuring device of an electric device, characterized in that configured to display an analog electromagnetic wave value in the display window 30 as a digital value by calculating the magnetic field (G) value.
The electromagnetic wave measuring apparatus of claim 6, wherein the second sensor unit comprises one first hall effect sensor and configured to measure unidirectionally.
The method of claim 6, wherein the first electromagnetic induction sensor 21 of the first sensor unit 20 and the first to third Hall effect sensors 51, 52, 53 of the second sensor unit 50 are partially. Shielding the electromagnetic wave measuring apparatus of the electrical equipment, characterized in that configured to cover with the shielding means 40 so that the remaining portion is exposed.
7. The display window (30) according to claim 6, wherein the display window (30) appears as a stopped measurement value when the power remaining amount zone (A) indicating a charge amount, a time display zone (B) continuously displaying the current time, and a hold button (30c) are pressed. Measured by the first and third Hall effect sensors 51 (52) and 53, the field display zone (C) which frequently shows the measured electric field value (V) and the magnetic field display zone (D) which shows the measured value of the magnetic field (G). Separate measured value display area (E) for displaying each measured electromagnetic wave into electric field and magnetic field, warning lamp area for emitting warning light (F), and safety distance indication for safe distance which is harmless range of electromagnetic waves. Configure it to display as a zone (G),
One side of the display window 30 is installed, the electromagnetic wave measuring apparatus of the electric device, characterized in that configured to generate a warning sound when the electromagnetic wave value exceeding the reference value.
The method of claim 6, wherein the power supply unit 10 constitutes an auxiliary power supply unit 10a for temporarily storing power,
The display window 30 has a power button (30a) for controlling the power supply and cutoff of the power supply unit 10, a time button (30b) for indicating the time to measure the current electromagnetic wave, fixed to confirm the current measured electromagnetic wave value Hold button 30c, the electric field button 30d for displaying the electric field value, the magnetic field button 30e for displaying the magnetic field value, respectively measured by the first to third Hall effect sensors 51, 52, 53 The electromagnetic wave measuring apparatus of an electric apparatus, characterized in that the configuration is configured to functionally connect the X value button (X), Y value button (Y), Z value button (Z) for displaying the measured value alone.
In the electromagnetic wave measuring method using a device for measuring the electromagnetic waves generated by the electrical equipment operating in the home, medical, industrial fields,
When the electric power of the electric device is supplied to the power supply unit 10, the electric signal oscillated by the high frequency oscillator 13 is received and induced in the coil according to the rate of change of magnetic flux Φ based on Faraday's law of electromagnetic induction. Electromagnetic values of X, Y, and Z axes are measured by the first to third electromagnetic induction sensors 21, 22, and 23 using electromotive force,
Measurement modulated values and first amplifiers, in which magnetic field modulators 31 change the electromagnetic wave values measured on the X-, Y-, and Z-axis lines measured by the first to third electromagnetic induction sensors 21, 22, and 23, The electrical signal amplified in 12) is transferred to the calculator 32,
It is configured to display the analog electromagnetic wave value as a digital value in the display window 30 by calculating the measured modulation value and the amplified electric signal input to the calculator 32 to the electric field (V) value and the magnetic field (G) value Measurement method using the electromagnetic wave measuring device of the electrical equipment.
12. The method of claim 11, wherein the first to third electromagnetic induction sensors (21, 22, 23) of measuring the electromagnetic wave is provided with only the first electromagnetic induction sensor 21 is configured to measure the unidirectional Measurement method using the electromagnetic wave measuring device of the device.
12. The method of claim 11, wherein the first to third electromagnetic induction sensors (21, 22, 23) of the electric device, characterized in that configured to cover a portion and the shielding means 40 so that the remaining portion is exposed. Measurement method using electromagnetic wave measuring device.
12. The display window 30 according to claim 11, wherein the display window 30 shows a power remaining amount zone A indicating a charge amount, a time indication zone B continuously displaying the current time, and a hold value 30c when the hold button 30c is pressed. At the same time, the electric field display zone (C), which frequently shows the measured electric field value (V), and the magnetic field display zone (D), which represents the magnetic field (G) measurement value, in the first to third electromagnetic induction sensors 21 (22, 23). Separate measured value display area (E) that displays each measured electromagnetic wave value by electric field and magnetic field, warning lamp area (F) which emits warning light, and safety distance which displays safe distance which is harmless range of electromagnetic wave. To display as a display area (G),
One side of the display window 30 is installed, the measuring method using the electromagnetic wave measuring apparatus of the electric device, characterized in that configured to generate a warning sound when the electromagnetic wave value exceeding the reference value.
The method of claim 11, wherein the power supply unit 10 constitutes an auxiliary power supply unit 10a for temporarily storing power,
The display window 30 has a power button (30a) for controlling the power supply and cutoff of the power supply unit 10, a time button (30b) for indicating the time to measure the current electromagnetic wave, fixed to confirm the current measured electromagnetic wave value Hold button 30c, the electric field button 30d for displaying the electric field value, the magnetic field button 30e for displaying the magnetic field value, respectively measured by the first to third electromagnetic induction sensors 21, 22, 23 Measuring method using the electromagnetic measuring device of the electric device, characterized in that the configuration to be connected to the X value button (X), Y value button (Y), Z value button (Z) to display the measured value alone, respectively .
In the electromagnetic wave measuring method using a device for measuring the electromagnetic waves generated by the electrical equipment operating in the home, medical, industrial fields,
When the electric power of the electric device is supplied to the power supply unit 10, the electric signal oscillated by the high frequency oscillator 13 is received and induced in the coil according to the time change rate of the magnetic flux Φ based on Faraday's law of electromagnetic induction. The first electromagnetic induction sensor 21 using the electromotive force to measure the unidirectional electromagnetic wave value,
The Hall effect method for measuring the potential difference (Hall voltage) across the conductive wires with the first to third Hall effect sensors 51, 52, 53 by receiving the power from the power supply unit 10. Measure the electromagnetic wave values on the X, Y, and Z axes.
The measurement modulated value obtained by changing the electromagnetic wave value measured by the first electromagnetic induction sensor 21 and the magnetic modulator 31 and the electric signal amplified by the first amplifier 12 are transferred to the calculator 32.
The first to third Hall effect sensors 51, 52, 53 by amplifying each electromagnetic wave value measured on the X-axis, Y-axis, Z-axis in the second amplifier 54 and transmits to the calculator 32 ,
The measurement modulation value, the amplified electric signal, and the amplified electromagnetic wave value input to the calculator 32 are calculated by using the electric field (V) value and the magnetic field (G) value to display the analog electromagnetic wave value as a digital value in the display window 30. Measuring method using the electromagnetic wave measuring apparatus of the electric device, characterized in that the configuration.
17. The method of claim 16, wherein the first to third Hall effect sensors (51, 52, 53) of the electromagnetic wave value is provided with only the first Hall effect sensor 51 is configured to measure the unidirectional Measurement method using the electromagnetic wave measuring device of the device.
The method according to claim 16, wherein the first electromagnetic induction sensor 21 and the first to third Hall effect sensors 51, 52, 53 shield a part and cover the remaining part with the shielding means 40 to expose the remaining part. Measuring method using the electromagnetic wave measuring apparatus of the electric device, characterized in that the configuration.
17. The display window (30) according to claim 16, wherein the display window (30) shows the power remaining amount (A) indicating the charge amount, the time display area (B) continuously displaying the current time, and the hold button (30c). Measured by the first and third Hall effect sensors 51 (52) and 53, the field display zone (C) which frequently shows the measured electric field value (V) and the magnetic field display zone (D) which shows the measured value of the magnetic field (G). Separate measured value display area (E) for displaying each measured electromagnetic wave into electric field and magnetic field, warning lamp area for emitting warning light (F), and safety distance indication for safe distance which is harmless range of electromagnetic waves. Configure it to display as a zone (G),
One side of the display window 30 is installed, the measuring method using the electromagnetic wave measuring apparatus of the electric device, characterized in that configured to generate a warning sound when the electromagnetic wave value exceeding the reference value.
The method of claim 16, wherein the power supply unit 10 constitutes an auxiliary power supply unit 10a for temporarily storing power,
The display window 30 has a power button (30a) for controlling the power supply and cutoff of the power supply unit 10, a time button (30b) for indicating the time to measure the current electromagnetic wave, fixed to confirm the current measured electromagnetic wave value Hold button 30c, the electric field button 30d for displaying the electric field value, the magnetic field button 30e for displaying the magnetic field value, respectively measured by the first to third Hall effect sensors 51, 52, 53 Measuring method using the electromagnetic measuring device of the electric device, characterized in that the configuration to be connected to the X value button (X), Y value button (Y), Z value button (Z) to display the measured value alone, respectively .

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