KR200347110Y1 - brain wave inducing learning machine using oxygen - Google Patents

Abstract

The present invention relates to an EEG-induced learner that can change the brain activity of the learner by supplying air containing oxygen of a specific concentration waveform, the oxygen generating unit for generating high oxygen air having an oxygen concentration above the oxygen in the atmosphere; A mixing unit for mixing the high oxygen air with air in the air to produce mixed air; Distribution unit for providing the mixed air to the user; And a control unit for controlling the operation of the oxygen generating unit, the mixing ratio of high oxygen air and oxygen concentration in the air in the mixing unit, and the distribution state of the distribution unit.

Another design is a brain wave guide learner using oxygen, characterized in that it further comprises a storage unit for storing high oxygen air.

Description

Brain wave inducing learning machine using oxygen

The present invention relates to an EEG-guided learner using oxygen, and more particularly to an EEG-guided learner that can change the brain activity of learners by supplying air containing oxygen of a specific concentration waveform.

In the process of processing information received from external sensory organs such as eyes, ears, nose, mouth and skin, human brain cells emit electric current. The electrical waveforms derived and amplified and recorded are called brain waves.

According to the brain activity, which is a complex information processing process, the electrical type of the brain is changed. The type is divided into alpha wave, beta wave, delta wave, and theta wave according to the frequency.

In general, the alpha wave has a frequency of 8 to 13 Hz and occurs in a stable state of a normal person such as attention, learning and meditation, and the beta wave has a frequency of 14 to 30 Hz to concentrate the mind or increase brain activity, or to relax. Occurs when a job is in progress. Theta waves occur at a frequency of 4-7 Hz and occur when there is a shallow sleep or stress. Delta waves are frequencies of less than 4 Hz and occur during deep sleep and are independent of the outer cortex.

The human brain tends to match or resonate with frequencies generated by external stimuli, called frequency following response (FFR). A signal made to induce a specific EEG using this principle is called an EEG induction signal. Most EEG-induced signals use light and sound as stimuli, and optical glasses equipped with LEDs for light stimulation use earphones or headphones to stimulate sound.

Conventional EEG-induced signal generators are stimulating signals, it is difficult to learn at the same time in the case of optical glasses, the sound stimulation by the earphone is a feeling of rejection or the sound stimulus rather disturbs the phenomenon occurs.

The same problem is found when using an EEG learner for sleep.

An object of the present invention devised to solve the above problems is to provide an EEG-guided learner using oxygen to induce brain activity to a desired state through olfactory stimulation and proper oxygen supply.

Still another object of the present invention is to provide an EEG-guided learner using oxygen that includes a brain function and a comparative check function while inducing brain activity to a desired state through olfactory stimulation and proper oxygen supply.

1 is a block diagram of Embodiment 1 of the present invention.

2 is a block diagram of Embodiment 2 of the present invention.

<Description of the symbols for the main parts of the drawings>

100: oxygen generator 110: filter

120: compressor 130: oxygen generator

170: oxygen generation control unit 200: storage unit

210: storage tank 220: compressor

230: regulator 240: valve

270: pressure control unit 300: mixing unit

310: filter 320: mixer

330: humidifier 340: valve

350: compressor 360: air freshener

370: mixing control unit 400: distribution unit

401,402,403,404,405; Regulating valves 411,412,413,414,415; Respiratory system

420: main control valve 470: distribution control unit

500: control unit 510: power

520: display unit 530: memory

540: sinusoidal wave generator 600: brain frequency measuring instrument

610: interface

The present invention for achieving the above object, the oxygen generating unit for generating high oxygen air having an oxygen concentration of more than oxygen in the atmosphere; A mixing unit for mixing the high oxygen air with air in the air to produce mixed air; Distribution unit for providing the mixed air to the user; And a control unit for controlling the operation of the oxygen generating unit, the mixing ratio of high oxygen air and oxygen concentration in the air in the mixing unit, and the distribution state of the distribution unit.

Another design is a brain wave guide learner using oxygen, characterized in that it further comprises a storage unit for storing high oxygen air.

Another design is a brain wave guide learner using oxygen, characterized in that it further comprises a brain frequency measuring device connected to the control unit and measuring the brain wave transmitted through the interface to the control unit.

The oxygen generator includes a filter for sucking external air, a compressor for compressing suction air, and an oxygen generator for generating oxygen from the sucked air.

The storage unit includes a compressor for compressing the high oxygen air supplied from the oxygen generating unit to a high pressure, a storage tank for storing the high pressure high oxygen air, and a regulator for adjusting the pressure of the output port of the storage tank to a predetermined pressure; It is characterized by.

The mixing unit includes a filter for sucking outside air, a compressor for sucking outside air, and a mixer for mixing the high oxygen air and the outside air at a predetermined ratio.

In addition, the mixing unit further comprises a humidifier or / and characterized in that it further comprises a fragrance supply.

The distribution unit may include at least one or more control valves and a respirator connected to the control valves to allow the user to suck the mixed air.

The control unit generates a sine wave from a digital signal stored in a memory through a sine wave generator, and adjusts the mixing ratio or discharge flow rate of the high oxygen air and the external air of the mixing unit according to the sine wave.

In the above, the mixing ratio is fluctuated between a minimum of 22 to 25% and a maximum of 30 to 60%, or the discharge flow rate is varied between a minimum of 0.5 to 1.0l / min and a maximum of 1.5 to 5.0l / min.

The frequency of the sine wave is characterized in that 2 to 20 times per minute.

In the above, the control unit displays the brain frequency received from the brain frequency measuring unit on the display unit, and varies the mixing ratio so that the selection mode approaches the target brain waveform.

Hereinafter, the present invention will be described in detail through examples and drawings.

The most important feature of the present invention is to supply the user with the mixed air having a constant concentration wave while having an oxygen concentration of 20.095% or more, which is the oxygen concentration in the atmosphere.

1 is an overall configuration diagram of a preferred embodiment of an EEG using oxygen according to the present invention, largely divided into an oxygen generating unit, a storage unit, a mixing unit, a distribution unit, a control unit.

The oxygen generator serves to generate high oxygen air having an oxygen concentration higher than the oxygen in the air, a filter 110 for sucking outside air, a compressor 120 for compressing suction air, and the suction Oxygen generator 130 for generating oxygen from the air.

The filter 110 may be installed by combining an air filter (not shown), an electrostatic precipitator (not shown), activated carbon (not shown), anion generator (not shown), and the like as necessary.

The air filter basically removes relatively large dust in the inflowing outside air through a network filter such as a paper filter, and is mainly installed at the outermost side of the intake port.

Electrostatic precipitators are generally two-stage charged, in which fine dust passing through the air filter is ionized by high voltage when passing through an electro-static field, and when dust is passed between electrodes having a negative voltage. It was made possible.

Activated charcoal removes by adsorbing fine gas particles in the air filtered through the air filter, that is, various harmful gases including odor components and carcinogens and chemical components therein.

Anion generators generate negative ions by passing the drawn air through a current.

The compressor 120 serves to supply the force for allowing air to pass through the intake of air and the oxygen generator 130.

The oxygen generator 130 may use a PSA method or a membrane method.

In the membrane method, the oxygen concentration of the generated air is about 35%, which is somewhat inappropriate for use in a method of changing the concentration as in the present invention.

Therefore, it is preferable to use the PSA method that can produce air having an oxygen concentration of 90% or more as the oxygen generator 130 in the present invention.

Control of the oxygen vacancies is by the oxygen generation control unit 170.

The storage unit serves as a temporary storage means for stabilizing the oxygen supply, it may be omitted.

The storage unit compresses the high oxygen air supplied from the oxygen generating unit to a high pressure, a storage tank 210 for storing the high pressure high oxygen air, and a pressure at an output port of the storage tank 210. It includes a regulator 230 to adjust the pressure.

Compressor 220 is to fill the storage tank 210 with high oxygen air at a high pressure.

Storage tank 210 is made of a material that can withstand high pressure.

The storage tank 210 and the compressor 220 are designed to occupy a large volume, and are manufactured in consideration of the size and specifications of the product.

The regulator 240 serves to maintain a constant flow rate of high oxygen air exiting from the storage tank 210. It is because controlling the flow rate of the high oxygen air is advantageous in changing the mixing ratio of the high oxygen air and the external air of the mixed air in the mixing section described later to a desired ratio.

The control of the storage unit is by the intrusion control unit 170.

The mixing section mixes the high oxygen air with the air in the atmosphere to produce the mixed air.

The mixing unit includes a filter 310 for sucking outside air, a compressor 350 for sucking outside air, and a mixer 320 for mixing the high oxygen air and the outside air at a predetermined ratio.

In addition, the mixing unit may further include a humidifier 330 on the output side of the mixer 320. Since the air is dried by the filter 110 of the oxygen generator 100, the humidifier 330 may impart moisture to the humidifier 330 to prevent a disease due to drying such as a cold.

In addition, the perfume supplier 360 may be further connected to the output side. The supply system of the fragrance may be sprayed in an appropriate amount over a predetermined time, or sprayed in small amounts continuously.

The fragrance feeder 360 gives a comfortable feeling or a refreshing feeling to the user and helps to enhance the effect of the EEG learner of the present invention.

The air freshener 360 and the humidifier 330 are more useful when the present invention is used indoors.

The filter 310 may be formed like the filter 110 of the oxygen generator. By changing the piping, it is also possible to configure the filter 110 of the oxygen generating unit and the filter 310 of the mixing unit as one, and to heat the pipes in each unit.

The valve 340 may be installed at the front end or the rear end of the compressor 350 to control the suction amount of the external air.

Mixer 320 has a throttle valve (not shown) therein, it is possible to mix the outside air and high oxygen air. Of course, it is also possible to use a flow regulator (not shown) that can control the inflow of external air and the inflow of high oxygen air, respectively.

Control of the oxygen vacancies is by the oxygen generation control unit 170.

The distribution unit serves to provide the mixed air to the user.

Therefore, it has at least one control valve (401, 402. 403, 404, 405), and the respirator (411, 412. 413, 414, 415) connected to the control valve to allow the user to suck the mixed air.

The front end of the control valve (401,402.403,404,405) is provided with a main control valve 420 connected in parallel with each control valve.

Control of the oxygen vacancies is by the distribution controller 470.

The oxygen generation control unit 170, the pressure control unit 270, the mixing control unit 370, and the distribution control unit 470 are electrically connected to the control unit 500 again.

In addition to the control unit 500, a power source 510, a display unit 520, a memory 530, and a sine wave generator 540 are respectively connected.

The power supply 510 supplies power to the entire system.

The controller generates a sine wave through the sine wave generator 540 from the digital signal stored in the memory 530.

Then, the mixing control unit 370 is controlled to synchronize the mixing ratio or discharge flow rate of the high oxygen air and the external air of the mixing unit in accordance with the sine wave.

Therefore, the mixing control unit 370 may operate the throttle valve or the flow regulator and the valve 340 in the mixer to form a wave of the desired oxygen concentration, or form a wave of the discharge flow rate.

The contents of the memory 530 may be provided from a specific web server through a communication network including a hard disk, a floppy disk, a CD-ROM, or the Internet, and the user may download it from a computer (including a client). It can be used in the form of storing in the memory 530.

The display unit 520 displays the current operating state and the EEG selection mode.

The mixing ratio may vary between a minimum of 22-25% and a maximum of 30-60%, or the discharge flow rate may vary between a minimum of 0.5-1.0 L / min and a maximum of 1.5-5 L / min.

By changing the mixing ratio or the discharge flow rate as described above, several EEG modes can be set in advance and stored in the memory.

Here, the frequency of the sine wave is approximately matched to the human respiratory rate. In other words, change in mixing ratio or discharge flow rate is 2 ~ 20 times per minute.

For example, seven EEG modes may be configured as follows.

The first mode M1 induces an EEG that can improve concentration in a stable state in the concentration mode.

The second mode (M2) induces brain waves that can enhance memory by activating the brain function by maintaining concentration in the learning mode.

The third mode M3 induces brain waves that can maintain concentration in the language learning mode.

The fourth mode (M4) is a relaxation mode to induce brain waves to stabilize the mind and to relieve fatigue.

The fifth mode (M5) is a meditation mode to stabilize the mind and induces the brain waves of feeling clear.

The sixth mode (M6) is a vitality mode to induce brain waves to relieve helplessness or stress.

The seventh mode M7 induces brain waves to take a deep sleep in the sleep mode.

Therefore, the brain stimulation by the mixing ratio or the discharge flow rate can be adjusted in a total of seven stages through the user's control unit operation. The mixing ratio or discharge flow rate is determined in advance by the characteristics of the EEG inducing signal and variously provided, and is selected and used according to the user's preference.

However, the brain wave modes M1 to M7 are merely examples for the implementation of the present invention, and of course, modification or modification by those skilled in the art is possible.

In addition, the present invention can also be used in connection with the existing brain stimulation learning by sound stimulation or light stimulation.

2 is an embodiment in which the interface 610 and the frequency meter 600 are further included in the embodiment of FIG. 1.

The frequency meter 600 is used to measure the state of the user's brain in real time.

Then, the value measured by the frequency measuring device 600 is transmitted to the control unit 500 through the interface 610.

The controller 500 outputs the measured brain frequency to the display unit 520 and compares the brain wave modes M1 to M7 described above.

Therefore, the user can use the embodiment of the present invention while comparing the current state of the brain with the state of the target brain.

In addition, the control unit 500 analyzes the difference between the brain wave modes M1 to M7 and the measured brain frequencies, and changes the variation of the mixing ratio or the discharge flow rate, so that the state of the user's brain can quickly reach the target brain state. To help.

Through the present invention, by inducing the brain activity to the desired state through the olfactory stimulation and the appropriate oxygen supply, the user can maintain a comfortable state without using a special rejection or the brain wave guide learner.

In addition, the current state of the brain can be measured in real time and delivered to the user, and the state of the brain can be induced as desired, so that the state of the brain can be changed quickly.

Claims (15)

An oxygen generator for generating high oxygen air having an oxygen concentration higher than oxygen in the atmosphere; A mixing unit for mixing the high oxygen air with air in the air to produce mixed air; Distribution unit for providing the mixed air to the user; And And a control unit for controlling the operation of the oxygen generator, the mixing ratio of high oxygen air and oxygen concentration in the air in the mixing unit, and the distribution state of the distribution unit. The brain wave guide learner using oxygen according to claim 1, further comprising a storage unit for storing high oxygen air. The brain wave guide learner using oxygen according to claim 1 or 2, further comprising a brain frequency measuring device connected to the control unit and measuring brain waves and transmitting the brain waves through an interface. The EEG-guided learner using oxygen according to claim 1, wherein the oxygen generator includes a filter for sucking external air, a compressor for compressing suction air, and an oxygen generator for generating oxygen from the sucked air. The storage unit of claim 2, wherein the storage unit adjusts the pressure of the compressor for compressing the high oxygen air supplied from the oxygen generating unit to a high pressure, the storage tank for storing the high pressure high oxygen air, and the pressure of the output port of the storage tank to a predetermined pressure. Brain wave guide learner using oxygen, characterized in that it comprises a regulator. The EEG-guided learner using oxygen according to claim 1, wherein the mixing unit includes a filter for sucking external air, a compressor for sucking outside air, and a mixer for mixing the high oxygen air and the outside air at a predetermined ratio. The brain wave guide learner using oxygen according to claim 6, wherein the mixing unit further comprises a humidifier. 8. The EEG-guided learner using oxygen according to claim 6 or 7, wherein the mixing part further comprises a fragrance feeder. The EEG-guided learner using oxygen according to claim 1, wherein the distribution unit includes at least one or more control valves and a respirator connected to the control valves to allow the user to inhale the mixed air. The method of claim 1, wherein the control unit generates a sine wave from the digital signal stored in the memory through a sine wave generator, and adjusts the mixing ratio of the high oxygen air and the external air of the mixing unit in accordance with the sine wave. EEG learner. 11. The EEG-guided learner using oxygen according to claim 10, wherein the mixing ratio varies between a minimum of 22-25% and a maximum of 30-60%. The brain waveguide learner using oxygen according to claim 1, wherein the control unit generates a sine wave from a digital signal stored in a memory through a sine wave generator, and tunes the discharge flow rate of the mixing unit according to the sine wave. 13. The EEG-guided learner using oxygen according to claim 12, wherein the discharge flow rate varies between a minimum of 0.5 to 1.0 L / min and a maximum of 1.5 to 5.0 L / min. The brain wave guide learner using oxygen according to claim 10 or 12, wherein the frequency of the sine wave is 2 to 20 times per minute. The EEG-guided learner using oxygen according to claim 3, wherein the control unit displays the brain frequency received from the brain frequency measuring instrument and changes the mixing ratio so that the selection mode approaches the target brain waveform.