KR200311361Y1 - Electron Wave Radiation Apparatus for Living Body Irradiation - Google Patents

Abstract

The present invention selectively radiates electromagnetic signals corresponding to various electromagnetic signals generated from transmission lines, mobile phones, and the like, and the state of stress, DNA structure, and protein deformation on the living body of subjects such as rats and rabbits. The present invention relates to an electromagnetic radiation device for observing a living body. The main configuration of the present invention is an electromagnetic wave generator for generating an electromagnetic signal corresponding to various frequencies; An antenna for receiving and radiating an electromagnetic wave signal from the electromagnetic wave generator; And an accommodating space part disposed under the antenna and accommodating a subject such as a mouse or a rabbit coated with an electromagnetic wave signal radiated from the antenna.

Description

Electromagnetic Wave Radiation Apparatus for Living Body Irradiation

The present invention selectively radiates electromagnetic signals corresponding to various electromagnetic signals generated from transmission lines, mobile phones, and the like, and monitors the state of stress, etc., on the living bodies of subjects such as rats and rabbits. It relates to the electromagnetic wave emitting device used.

At present, we are living in an environment exposed to the electromagnetic field generated by various electric and electronic devices including the natural electromagnetic field. In recent years, as the size of these devices becomes larger and larger, interest in harmonization between the electromagnetic field and human society is increasing. Among these, the effect of the electromagnetic field on the living body needs to be elucidated in terms of safety. Electromagnetic fields in areas with high frequencies, such as microwaves, have long been of interest, and their mechanisms have been elucidated, and the electrical properties and absorption power distributions of living bodies with respect to high frequencies have been well investigated.

On the other hand, in the 1970s, studies on the biological effects of ELF (Extremely Low Frequency, 0 ~ 1kHz) electromagnetic field were started in earnest with the safety standards of ultra-high voltage transmission lines. It is a reality that opinion is not obtained.

Even in such a situation, developed countries such as Europe and the United States have officially expressed concern about the harmfulness of electromagnetic waves since the early 1990s, but remain in the line of recommending that they not be exposed to electromagnetic waves so that they cannot come up with regulations.

In addition, most of the research on the effect of the electromagnetic wave on the living body is the antenna of the electromagnetic wave generator. As a result, the effect of the type of antenna, the distance from the antenna, the strength of the electromagnetic wave, and the waveform were varied, so that a uniform result was not obtained.

On the other hand, with the spread of mobile phones, electromagnetic waves emitted from mobile phones are regulated by SAR (Specific Absorption Rate), which represents the amount absorbed by the human brain, and most countries including Korea, including the US, adopt 1.6mW / g or less. .

However, in order to understand the effects of the electromagnetic waves generated from the transmitter and the mobile phone on the human body, studies on stress, DNA structure, and protein modification were continuously performed using mice and rabbits as test subjects.

An object of the present invention is to selectively radiate electromagnetic signals corresponding to various electromagnetic signals generated from transmission lines, mobile phones, and the like, and to observe the state of stress, etc., on the living bodies of subjects such as rats and rabbits. The present invention provides an electromagnetic radiation device for irradiation.

1 is a conceptual diagram of the electromagnetic radiation device for irradiation according to the present invention.

2 is a block diagram of an electromagnetic wave generator according to the present invention.

Figure 3 is a front view of the electromagnetic radiation device for irradiation according to the present invention.

4 is an operating state of the storage space according to the present invention.

5 is a flowchart illustrating a process of irradiating an electromagnetic wave signal to a test subject according to an exemplary embodiment of the present invention.

<Description of the reference numerals for the main parts of the drawings>

1: electromagnetic wave radiation device 3: case

5: electromagnetic wave generator 7: antenna

9: accommodating space part 11: electromagnetic wave generating part

13 power amplifier 15 antenna connection

17: control panel 19: power supply

21: output control unit 23: coaxial cable

Electromagnetic radiation emitting device for biological irradiation to achieve the above object is an electromagnetic wave generator for generating an electromagnetic wave signal corresponding to various frequencies; An antenna for receiving and radiating an electromagnetic wave signal from the electromagnetic wave generator; And an accommodating space part disposed under the antenna and accommodating a subject such as a mouse or a rabbit coated with an electromagnetic wave signal radiated from the antenna.

Preferably, the electromagnetic wave generator includes an oscillator for generating various electromagnetic signals, a power amplifier for amplifying the electromagnetic signal generated by the electromagnetic wave generator, and a SAR of the electromagnetic signal according to SAR selection. An output controller for controlling an amplification output, an antenna connector for transmitting an electromagnetic signal amplified by the power amplifier to the antenna, a SAR control switch for selecting a type of the electromagnetic signal, and a temperature in the storage space It characterized in that it comprises a control panel formed with a display for displaying a power switch and a power switch for controlling the power of the electromagnetic wave generator.

Hereinafter, with reference to the accompanying drawings looks at in detail the electromagnetic radiation device for irradiation of the present invention.

1 is a conceptual diagram of the electromagnetic radiation emitting device for irradiation according to the present invention, Figure 2 is a block diagram of the electromagnetic wave generator according to the present invention, Figure 3 is a front view of the electromagnetic radiation device for irradiation according to the present invention, Figure 4 Is a storage space part according to the present invention, Figure 5 is a flow chart for the process of irradiating the electromagnetic wave signal to the test subject according to an embodiment of the present invention.

1 and 3, the electromagnetic radiation emitting device 1 for irradiation is formed of a case 3 having a predetermined shape having a tetrahedron or the like, and an electromagnetic wave generator for generating electromagnetic waves inside the case 3. (5) and an antenna (7) for receiving and radiating electromagnetic signals generated by the electromagnetic wave generator (5), and an accommodating body in which an electromagnetic wave signal radiated from the antenna (7) is irradiated and coated on the electromagnetic signal. The space 9 is provided. The electromagnetic wave generator 5 and the antenna 7 are connected by a coaxial cable 23, and the electromagnetic signal generated by the electromagnetic wave generator 5 is transmitted to the antenna 7 through the coaxial cable 23.

2, the electromagnetic wave generator 5 includes the electromagnetic wave generator 11, the power amplifier 13, the antenna connector 15, the control panel 17, and the power supply 19. And it is made of an output control unit 21, it can be selectively positioned inside or outside of the case (3) for easy operation of the operator.

The electromagnetic wave generator 11 of the electromagnetic wave generator generates various electromagnetic signals including an electromagnetic frequency generated by a mobile telephone, an electromagnetic frequency generated by a transmission line, and the like. The output and amplification of the electromagnetic signal generated by the electromagnetic wave generator 11 is controlled by the SAR control switch 25 of the control panel 17 to be described later.

The power amplifier 13 amplifies various electromagnetic signals generated by the electromagnetic wave generator 11.

The output control unit 21 adjusts the amplification output according to the Specific Absorption Rate (SAR).

The antenna connection unit 15 transmits the amplified electromagnetic signal through the power amplifier 13 using the coaxial cable 23 connected to the antenna 7 so that the electromagnetic signal can be radiated from the antenna 7.

The control panel 17 controls the power supply of the SAR control switch 25 for controlling the output of the electromagnetic wave generated by the electromagnetic wave generator 11 and the display 27 and the electromagnetic wave generator 5 for displaying the temperature in the storage space. It consists of a power switch 29.

The power supply unit 19 supplies power required for the use of the electromagnetic wave generator 5, and a power switch 29 for controlling the power supply is formed in the control panel 17.

On the other hand, as shown in Figure 3, the antenna 7 is preferably a horn antenna, which is a waveguide in which the electromagnetic wave is transmitted from one side and the other side is open, the coaxial connected to the antenna connection portion 15 of the electromagnetic wave generator (5) The electromagnetic wave signal transmitted through the cable 23 is radiated to the space from the open end of the waveguide. By using a waveguide as such an antenna, the electromagnetic wave signal in the tube mode can be kept constant. On the other hand, the antenna 7 is installed in various sizes and shapes according to the size of the storage space (9).

In addition, as shown in Figure 4, the storage space 9 is a receiving box 31 that can accommodate them so that the electromagnetic wave signal emitted through the antenna 7 can be irradiated to the subject, such as a rat, rabbit, etc. Is formed. The accommodating space 9 is positioned below the antenna 7 from which electromagnetic waves are radiated. When the antenna 7 is a waveguide, the storage space 9 is formed to have a size to accommodate the open end of the waveguide.

The storage space 9 is detachably installed in the case 3 so as to easily accommodate the object to be observed, and the storage space 9 is provided with a temperature sensor and various data measuring devices for observing the test subject. . For example, when the temperature sensor is installed in the storage space 9, the measured temperature is transmitted to the display 27 installed in the control panel 17 of the electromagnetic wave generator, thereby storing the storage space outside the storage space 9. It is provided to know the temperature inside the unit

On the other hand, the side and bottom of the storage space 9 is preferably applied with an electromagnetic wave absorber to prevent the electromagnetic wave emitted from the antenna 7 is reflected.

A process of irradiating an electromagnetic wave signal in a state where the test subject is accommodated in the accommodation space will be described with reference to FIG. 5.

Position the antenna 7 radiating electromagnetic waves on the upper part of the inside of the case, and place the storage space 9 in which the test subjects, such as rats and rabbits, are placed in the accommodating box 31 on the lower part of the antenna 7 (inside the case). Position it. In addition, after placing the electromagnetic wave generator 5 for generating an electromagnetic wave signal in the lower portion (lower case bottom) of the storage space 9, the electromagnetic wave generator 5 and the antenna 7 are connected by a coaxial cable 23 ( Step S502).

Thereafter, a test object such as a mouse or a rabbit is accommodated in the storage space 9 (step S504), and an electromagnetic wave signal generated from the mobile phone using the SAR control switch 25 formed on the control panel 17 of the electromagnetic wave generator. A frequency of about 1.6 mW / g corresponding to the frequency is set (step S506).

When the frequency of the electromagnetic wave signal is set by the SAR control switch 25, the electromagnetic wave generator 11 generates an electromagnetic signal corresponding to the set frequency, and the power amplifier 13 amplifies the generated electromagnetic signal (step S508).

The amplified electromagnetic wave signal is transmitted to the antenna 7 via the antenna connection unit 15 and the coaxial cable 23 (step S510).

The antenna 7 radiates the transmitted electromagnetic wave to the upper portion of the storage space 9 to expose a test subject such as a mouse or a rabbit accommodated in the storage box 31 of the storage space (step S512).

Through this process, data on a test subject such as a mouse or a rabbit accommodated through various data measuring devices installed in the storage space 9 can be measured (step S514).

Although the preferred embodiments of the present invention have been described in detail above, those of ordinary skill in the art to which the present invention pertains without departing from the spirit of the present invention as defined in the appended claims. All changes or modifications to the design will fall within the scope of the present invention.

As described above, the electromagnetic radiation device for biological irradiation of the present invention has the advantage of selectively detecting the harmful effects of specific electromagnetic waves by selectively radiating various electromagnetic wave signals to subjects such as rats and rabbits and observing the stress of the coated subjects. There is this.

In addition, there is an advantage that can examine the DNA structure and protein modification state using the test subject coated on the electromagnetic wave signal.

In addition, by using a waveguide as an antenna for emitting electromagnetic waves and applying an electromagnetic wave absorbing material to a space in which the test object is received, there is an advantage in that the effect of the electromagnetic signal emitted from the antenna on the test subject can be accurately determined.

Claims (5)

An electromagnetic generator for generating electromagnetic signals corresponding to various frequencies; An antenna for receiving and radiating an electromagnetic wave signal from the electromagnetic wave generator; And And an accommodating space part disposed under the antenna and accommodating a subject such as a mouse or a rabbit coated with an electromagnetic wave signal radiated from the antenna. The electromagnetic wave generator of claim 1, further comprising: an oscillator for generating various electromagnetic signals; A power amplifier for amplifying the electromagnetic wave signal generated by the electromagnetic wave generator; An output controller controlling amplified output of the electromagnetic wave signal; An antenna connector for transmitting the electromagnetic signal amplified by the power amplifier to the antenna; And And a control panel including a SAR control switch for selecting a type of the electromagnetic wave signal, a display for indicating a temperature in the storage space, and a power switch for controlling a power source of the electromagnetic wave generator. The apparatus of claim 1, wherein the antenna is a waveguide connected to the antenna connection portion of the electromagnetic wave generator by a coaxial cable, and transmits electromagnetic waves at one side and is open at the other side. The apparatus of claim 1, wherein the storage space is detachably mounted, a data measuring device for observing a test subject is installed, and an inner surface is coated with an electromagnetic wave absorber. The apparatus of claim 1, wherein the storage space includes a storage box in which a test subject is placed.