JPWO2019139011A1 - Portable gas suction device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable gas suction device capable of detecting a user's basic vital signs and transmitting them to the outside without preparing a separate wearable terminal or the like. A portable gas suction device comprises a battery, an operating means in which a user touches or presses a finger with a finger to transmit a control signal requesting generation of hydrogen gas and / or oxygen gas, and the battery. A control board that controls the power supply, a pair of positive and negative electrodes that energize or shield the power from the battery by the control board, and an electrolytic cell that can store water into which the pair of positive and negative electrodes are inserted. A portable gas suction device including a permeation device capable of permeating only a predetermined gas inside the electrolytic cell and a nozzle capable of sucking the gas released from the permeation device. The operating means detects the user's quantified vital sign when the user's finger touches or presses with the finger. [Selection diagram] FIG. 5 (a)

Description

The present invention is a portable gas suction device that sucks hydrogen gas or the like for the purpose of promoting the health of the user. When the operation buttons or the like are operated, the vital sign of the user is detected at the same time to suck gas according to the actual physical condition. It relates to a portable gas suction device that makes it possible to promote health corresponding to each user.

In recent years, the effectiveness of hydrogen has attracted attention in various animal disease experiments such as neurodegenerative diseases and acute lung disorders, and in human clinical experiments in metabolic syndrome and diabetes, and various studies in medical applications have been actively conducted. .. In addition, even so-called non-illnesses who do not develop a specific disease are particularly prone to generate active oxygen in their bodies, when exercising, eating and drinking, smoking, staying in an ultraviolet / contaminated environment, lack of sleep, etc. It is recommended to take hydrogen into the body to prevent aging and promote beauty and health in various conditions such as when receiving high stress such as long working hours.

In addition to hydrogen, oxygen is used to generate energy for cells and is an indispensable element for the human body to metabolize. Focusing on the activation of oxygen cells in the body, in recent years, consciously taking in oxygen into the body for recovery from fatigue, promotion of natural healing of medical conditions such as bone fractures, improvement of blood circulation disorders, beauty, stress relief, etc. Has been found to be effective.

In view of these circumstances, hydrogen generators that can ingest hydrogen and oxygen have been provided in recent years, and the applicant is also rechargeable, compact and inexpensive so that the user can carry it freely. Further, it provides a portable gas suction device capable of selectively generating hydrogen and oxygen.

Japanese Unexamined Patent Publication No. 2004-41949 Japanese Patent Application No. 2014-09640

However, the intake of hydrogen, etc. by the conventional hydrogen generator, etc. is to the user who manages his / her own physical condition and ingests hydrogen, etc. at the desired time by his / her own judgment, so that he / she can ingest an appropriate amount of hydrogen, etc. when necessary. It was not a thing, but an incomplete one as a health promotion tool. On the other hand, in recent years, it has become possible to measure basic vital signs such as heart rate and respiratory rate on a daily basis, and it has become easier to diagnose the physical condition of a user in real time.

There is a general-purpose wearable terminal that has been remarkably developed in recent years as a means for measuring such vital signs, but some users do not own a separate wearable terminal or do not own or wear a wearable terminal on a daily basis. There are also circumstances in which they are often not worn.

The present invention was created in view of the above circumstances, and detects and externally transmits the user's basic vital signs without preparing a separate wearable terminal or the like other than the portable gas suction device. It is an object of the present invention to provide a portable gas suction device capable of sucking an appropriate gas corresponding to this.

In order to solve the above problems, in the present invention,
From the battery, an operating means (see, for example, the operation button 335 in the present embodiment) for transmitting a control signal requesting the generation of hydrogen gas and / or oxygen gas by the user touching or pressing the finger with the finger, and the battery. A control board that controls the power supply (see, for example, control boards 33 and 42 in the present embodiment) and a pair of positive and negative electrodes (for example, the present embodiment) in which the power from the battery is energized or shielded by the control board. (Refer to the mesh electrode 17 in the above), an electrolytic tank capable of storing water into which the pair of positive and negative electrodes are inserted (see, for example, the electrolytic tank 10 in the present embodiment), and a predetermined gas inside the electrolytic tank are allowed to flow in. A portable gas suction device including a nozzle capable of sucking the gas (see, for example, the mixer 2 and the nozzle 5 in the present embodiment).
The operating means provides one that detects the user's quantified vital signs when the user's finger touches or presses with the finger.

According to the present invention, since the vital sign of the user can be detected by a switch (operating means) that requires the release of hydrogen gas or the like, a portable gas suction device can be used as a gas such as hydrogen while observing the user's health condition. And the amount of suction can be selected, and it can function as a health promotion device according to the actual physical condition of the individual user. In particular, in view of the social situation in which the utilization of data detected by the wearable terminal is required, this portable gas suction device can be positioned as a kind of wearable terminal, which is beneficial.

Further, it is preferable that the operating means transmits a control signal for generating a predetermined amount of hydrogen gas and / or oxygen gas based on the detected vital signs to the control substrate.

According to this operating means, the amount of hydrogen gas or the like generated can be controlled according to the user's vital signs detected when using the portable gas suction device, and the user can ingest it. It is possible to promote proper health according to the physical condition of the patient.

In addition, as another configuration, this portable gas suction device is
A vital sign transmitting means for externally transmitting the vital signs detected by the operating means, and
The control board may include a power signal receiving means that receives a control signal for controlling the power supply from the battery to the pair of positive and negative electrodes from the outside and transmits the control signal to the control board.

This portable gas suction device sends the detected user's vital sign to an external server or cloud server, analyzes the amount of hydrogen gas required for applications installed on other wearable terminals, etc., and uses this as a result. By returning the control signal of the power supply to the pair of positive and negative electrodes of the portable gas suction device according to the situation, it is possible to promote the health appropriate for the actual physical condition. This portable gas suction device is also advantageous for users who do not understand the amount of gas required according to vital signs.

In the portable gas suction device of the present invention, the user can suck hydrogen gas or the like at a desired place and time, and the portable gas suction device itself is basically sucked at the same time without preparing a separate wearable terminal or the like. Vital sign can be detected, and hydrogen gas or the like can be sucked according to the actual physical condition of the user.

In addition, according to this portable gas suction device, it is possible to perform appropriate gas selection and gas amount control based on the vital signs of the individual user who actually uses the gas, so the user does not have specialized knowledge. Can also take in the gas necessary to promote one's own health.

It is an assembly exploded view which illustrates each member of the portable gas suction device of this invention. 2A and 2B show views of the portable gas suction device of the present invention in FIG. 1 as viewed from each direction. FIG. 2A is a left side view, FIG. 2B is a front view, and FIG. 2C is a right side view. d) is a bottom view, and (e) is a top view. A cross-sectional view of the portable gas suction device of the present invention shown in FIGS. 1 to 2 along the line AA of FIG. 2C is shown. (A) shows a photographic diagram of an embodiment of the portable gas suction device of the present invention, and (b) shows a photographic diagram of another embodiment of the portable gas suction device of the present invention. The block diagram of the Example of the portable gas suction device of this invention is shown. A block diagram of another embodiment of the portable gas suction device of the present invention is shown. The flow of the implementation of the portable gas suction device of the present invention is shown. The flow of the implementation of the portable gas suction device of the present invention is shown. The flow of the practice of another example of the portable gas suction device of this invention is shown. The flow of the practice of another example of the portable gas suction device of this invention is shown. The flow of the practice of another example of the portable gas suction device of this invention is shown. A part of the flow in the embodiment of the portable gas suction device of the present invention shown in FIG. 7 is shown. A part of the flow in the embodiment of the portable gas suction device of the present invention shown in FIG. 7 is shown. A schematic diagram for explaining the calculation method of the required gas is shown.

Hereinafter, the configuration of the portable gas suction device of the present invention will be illustrated with reference to FIGS. 1 to 3. This portable gas suction device is not limited to the portable gas suction device shown in FIGS. 1 to 3, and includes various modified devices.

First, the basic structure of the portable gas suction device other than the vital sign detection function will be described as a premise for explaining the portable gas suction device of the present invention with reference to FIGS. 1 to 3. FIG. 1 is an assembled exploded view illustrating each member of the portable gas suction device 100. 2A and 2B show views of the portable gas suction device 100 of FIG. 1 as viewed from each direction, where FIG. 2A is a left side view, FIG. 2B is a front view, and FIG. 2C is a right side view. d) is a bottom view, and (e) is a top view. In the present specification, the terms vertical direction and vertical direction mean the vertical direction and vertical direction of the paper surface of (b), and the terms width direction, horizontal direction and side side mean the horizontal direction of the paper surface and the paper surface of (b). It means the horizontal direction and the left and right sides of the paper.

Further, FIG. 3 shows a cross-sectional view of the portable gas suction device 100 of FIGS. 1 to 2 along the line AA of FIG. 2C. Hereinafter, the portable gas suction device 100 will be described with reference mainly to the assembled exploded view of FIG. 1, and other drawings will be referred to for convenience of explanation. The main body cover 1 opens upward, and inserts and mounts the battery receiving portion 43 into which the battery (rechargeable lithium battery) 36 is inserted and built in in the vertical direction from the opening, and the lower part of the electrolytic cell 10 in parallel with this in the vertical direction. An electrolytic cell receiving unit 44 that can be formed is provided. The main body cover 1 has a shape in which the battery receiving portion 43 side is long and the upper portion on the electrolytic cell receiving portion 44 side is cut off so as to be inclined sideways. The bottom of the main body cover 1 can be opened and closed at the bottom of the battery receiving portion 43 by the main body bottom cover 6, and the battery 36 is inserted from the bottom at the time of assembly and closed with a screw 38 having a cross hole. Further, in the main body cover 1, two control boards 33 and 42 are arranged so as to vertically sandwich the battery 36 on both sides of the battery receiving portion 43. The control board 33 on the side surface side of the main body cover 1 is the main control board, and the power from the battery 36 to the control board 42 on the electrolytic cell 10 side that supplies power to the mesh electrode 17 (electrode plate) and the suction unit 32. Control the supply. Although the suction unit 32 is not an essential component, for example, a device that emits fragrance when power is supplied can be considered.

In the case of the portable gas suction device 100 shown in FIGS. 1 to 3, there is no function of detecting the vital sign of the user, a function of transmitting the vital sign externally, a function of receiving a control command from the mobile terminal or the like, and a function of sucking hydrogen gas or the like. It is the basic structure of.

On the side surface of the main body cover 1, the openings 9a, 9b, and 9c of the decorative plate 9 are provided with an operation button 35 for the control board 33, an LED 30, and a connector for charging the battery 36. When the operation button 35 is pressed, the control board 33 powers the power. The supply signal is transmitted to the control board 42, and the power of the battery 36 is supplied to the pair of mesh electrodes (electrode plates) 17 for a predetermined time via the board connector housing 31 and the terminal board 28. When power is supplied to the mesh electrode 17, the control board 33 transmits a power supply signal to the LED board 30, the LED emits light from the LED board 30, and the user can recognize the generation of hydrogen or oxygen gas.

In the examples of FIGS. 1 to 3, the condition operation button 35 for supplying electric power to the mesh electrode 17 is manually pressed, but the control board 42 that receives the command signal from the mobile terminal or the like described later moves to the mesh electrode 17. It is also possible to control the power supply of. For example, a receiving terminal (not shown) receives a predetermined power supply signal, transmits it to the control board 42, supplies power from the battery 36 to the mesh electrode 17 based on the power supply signal, and stops the mesh electrode 17.

When a current is supplied, the mesh electrodes 17 are arranged in pairs in a pair in the longitudinal direction upward in the longitudinal direction, each forming a positive cathode, and corresponds to the electric power from the positive cathode of the battery 36. Further, the upper end of the mesh electrode 17 has a shape cut diagonally so as to correspond to the boundary line between the reduced diameter portion 45 of the electrolytic cell 10 and the water storage main body portion 46. A rod-shaped titanium electrode 16 is connected to the lower end of the mesh electrode 17 so that it can stand upright on the terminal substrate 28 and be electrically connected. A packing 13 (made of resin such as silicon) mounted on the terminal substrate 28 to shield the mesh substrate 17 and the terminal substrate 28 from water with the mesh electrode 17 upright, and an O-ring attached around the titanium electrode 16 ( Made of resin such as silicon: Hereinafter, the O-ring is the same).

The electrolytic cell 10 is a water storage container, and the reduced diameter portion 45 and the water storage main body portion 46 are integrally formed in order from the bottom, and are fluidly connected to each other internally. The water storage main body 46 is opened upward so that water can be injected, and is semi-closed by attaching the electrolytic cell lid 12. The electrolytic cell lid 12 penetrates vertically and is provided with a through opening 12a for receiving the umbrella valve 23, the screw cap 14, and the like. As shown in FIG. 3, in the water storage main body 46, the outer side 46a forms a substantially flat side wall in the lateral direction from the upper end to the lower end and is directly connected to the upper end of the reduced diameter portion 45, and the inner portion on the main body cover 1 side. The 46b is formed parallel to the outer portion 46a from the upper end to the lower center position, and has a bottom portion 46c that is bent and inclined from the lower center position. The bottom portion 46c extends to an intermediate position in the lateral direction and is connected to the upper end of the reduced diameter portion 45.

Further, the reduced diameter portion 45 is thinner than the water storage body portion 46 as described above, and as shown in FIG. 3, the upper end of the outer side portion 46a on the side wall side remains as it is at the lower end of the outer portion 46a of the water storage body portion 46. It is continuously connected and extends to the lower end, and the upper end of the inner portion 45b on the main body cover 1 side is bent downward at the position of the tip (edge) of the bottom portion 46c of the main body cover 46 and connected to the inner portion 45b. It extends to the lower end in parallel with.

Further, at the connecting position between the lower end of the outer portion 46a of the water storage main body 46 and the upper end of the outer portion 46a of the reduced diameter portion 45, the impermeable plate 45d is inclined substantially the same as the bottom portion 46c of the water storage main body 46 and extends to the opening 45c. It is provided. The impermeable plate 45d extends over the entire area in the vertical direction of the paper surface of FIG. Therefore, even when the aqueous solution accumulated in the electrolytic cell 10 is electrolyzed and the amount of water stored is reduced, water is always stored in substantially the entire inside of the reduced diameter portion 45. Specifically, when the amount of water stored decreases and a part of the air layer is formed in the electrolytic cell 10, the diameter-reduced portion 45 is thinner than the main body 46 of the water storage, so unless the amount of water stored is significantly reduced in the normal standing state. The reduced diameter portion 45 is filled with water and no air layer is generated.

Even if the amount of water stored is reduced to some extent, it is conceivable that an air layer will be generated in the reduced diameter portion 45 when the portable gas suction device 100 is tilted or placed horizontally. In the case of the present electrolytic cell 10, such an air layer may be generated. Even in this case, the reduced diameter portion 45 is filled with water. Specifically, for example, when the paper is inclined to the left in FIG. 3, the bottom portion 46c serves as an obstacle plate and an air layer is formed on the inner portion 46b side of the water storage main body portion 46. On the contrary, when the paper is inclined to the right in FIG. 3, the impermeable plate 45d serves as an obstacle plate and an air layer is formed only on the outer side 46a of the water storage main body 46. Therefore, the mesh electrode 17 arranged in the reduced diameter portion 45 is always in contact with water as a whole, and the amount of hydrogen or oxygen generated can always be secured even when the user is sucking sideways. ..

The upper end edge of the mesh electrode 17 is formed by being obliquely cut along the shape of the reduced diameter portion 45 and the opening 45c so that the electrode is immersed in water in the reduced diameter portion 45 without a gap. Returning to FIG. 1 again, the lower end of the electrolytic cell 10 is closed by the electrolytic cell bottom 11, but the electrolytic cell bottom 11 is provided with a pair of through holes into which the mesh electrode 17 is inserted, and the reduced diameter portion 45 of the electrolytic cell 10 is provided. Is inserted into the electrolytic cell receiving portion 44 of the cover body 1, and the mesh electrode 17 passes through the through hole of the electrolytic cell bottom 11 and is positioned in the reduced diameter portion 45.

The umbrella valve 23 and the like mounted on the through opening 12a of the electrolytic cell lid 12 at the upper end of the electrolytic cell 10 will be described. A screw cap 14 having an upper opening and penetrating up and down is attached to the through opening 12a, and at that time, a vent filter 18 is interposed between the hole at the bottom of the screw cap 14 and the bottom of the through opening 12a. Then, the O-ring 20 is inserted around the lower part of the screw cap 14. The vent filter 18 has a function of waterproofing and dustproofing while adjusting the internal pressure in the opening of the screw cap 14 with a minute hole. Further, the O-ring 21 shields water between the outer peripheral wall of the opening of the screw cap 14 and the inner peripheral wall of the through opening 12a.

Further, an amplifier valve 23 (made of a flexible material such as silicon) that operates in the vertical direction is installed in the opening of the screw cap 14, and when the user sucks the nozzle 5 and a negative pressure acts upward, the amplifier is used. The valve 23 rises and is fluidly connected to the inside of the electrolytic cell 10 through the through hole at the bottom of the screw cap 14 and the through opening 12a of the electrolytic cell lid 12. Therefore, when the nozzle 5 is sucked in, the hydrogen or oxygen gas that has risen and stored in the electrolytic cell 10 is released to the outside. On the contrary, when the user interrupts the suction and the negative pressure does not act, the amplella valve 23 descends, the through hole at the bottom of the screw cap 14 is closed, and the release of hydrogen or oxygen gas in the electrolytic cell 10 is closed. To do.

The mixer 2 is attached to the electrolytic cell lid 12 to which the screw cap 14 and the umbrella valve 20 are attached from above. The mixer 2 has a tubular member 2a extending downward as shown in FIG. 3, and by inserting the lower end of the tubular member 2a into the opening of the screw cap 14, the tubular member 2a is hydrogenated from the umbrella valve 23. Alternatively, a flow path for guiding oxygen gas upward is formed. An O-ring 20 is provided around the outer peripheral wall of the tubular member 2a to seal the gap between the screw cap 14 and the inner wall of the opening.

Lock buttons 3 and 4 are attached to fix the mixer 2 and the electrolytic cell lid 12. The lock buttons 3 and 4 are sandwiched and snapped in the front-rear direction (vertical direction on the paper surface of FIG. 3) at the vertical gap positions between the mixer 2 and the electrolytic cell lid 12, respectively. Further, as shown in FIG. 3, the mixer 2 is provided with a flow path 2b at the upper portion thereof in the direction of the nozzle 5. The flow path 2b is connected to a flow path formed by the tubular member 2a and guides hydrogen or oxygen gas as shown by an arrow in FIG.

Next, the fragrance release device (fragrance heater unit) 32 that generates fragrance air will be described. The fragrance heater unit 32 is supplied with electric power from the battery 36 from the contact terminal 37 of the battery 36, and the fragrant air generated inside is discharged upward. The contact terminal 37 is fastened to the joint 37 with a screw 38 having a cross hole, and when the mixer 2 is attached, the contact terminal 37 is sandwiched between the joint 8 and the mixer 2 and fixed to the main body cover 1. Further, the mixer 2 is provided with a tubular member 2c extending downward in parallel with the tubular member 2a, and the upper end of the fragrance heater portion 32 is connected to the tubular member 2c to allow fragrant air to flow downward. It passes through 2c (see the arrow in FIG. 3), merges with hydrogen or oxygen gas, flows into the nozzle 5, and reaches the user's mouth. An O-ring 22 is arranged and sealed at the connecting portion between the bottom of the nozzle 5 and the mixer 2. In the example of FIGS. 1 to 3, the fragrance heater unit 32 supplies electric power to the control board 33 by pressing the button 35 in the same manner as the mesh electrode 17 (for example, long pressing the button 35), but similarly to the mesh electrode 17. In some cases, power is supplied by the control board 33 that has received a signal from a mobile terminal or the like.

The basic structure of the portable gas suction device has been described above, but it is needless to say that various modifications are permitted by those skilled in the art, not limited to those described above.

Next, an embodiment of the portable gas suction device of the present invention provided with the above-mentioned basic structure, a function of detecting a user's vital sign, a function of transmitting an external vital sign, a function of receiving a control command from a mobile terminal or the like, and the like. , FIGS. 4 to 9 will be described. The same description as the above-mentioned basic structure will be omitted as appropriate.

First, one embodiment of the portable gas suction device of the present invention will be described with reference to FIGS. 4 (a), 5 (a), and 6.
FIG. 4A shows a photograph of the portable gas suction device 300 of the present invention provided with a function of detecting a user's vital signs and a function of transmitting an external vital sign. The portable gas suction device 300 includes an operation button 335 for measuring vital signs and releasing gas.
FIG. 5A shows a block diagram of the portable gas suction device 300. The portable gas suction device 300 releases gas by an operation button 335, a battery 36, a mesh electrode 17, an environmental temperature measuring means 301 for measuring vital signs, a body temperature measuring means 302, a pulse / blood pressure measuring means 303, and an LED. The LED board 30 for displaying the above, the control board 33 and / or 42 (hereinafter, referred to as the control board 33) for controlling the generation of each signal and the like are provided. The control board 33 includes signal generation means 304, determination means 305, recording means 306, and transmission means 307. Further, the server 400 that receives the signal transmitted from the portable gas suction device 300 by the transmitting means 307 includes a recording means 406, a receiving means 408, a data collecting means 409, and a vital sign signal determining means 405a.
FIG. 6 is a diagram showing an implementation flow of the portable gas suction device 300. Hereinafter, an embodiment of the portable gas suction device 300 will be described with reference to FIGS. 5 (a) and 6 (a) and 6 (b).

In the portable gas suction device 300, when the user presses the operation button 335, the portable gas suction device 300 is switched to the usable state, and the gas is released and the vital sign of the user is measured at the same time.
In the portable gas suction device 300, first, the operation button ON / OFF determination means 305a determines ON / OFF of the operation button 335 (S100), and when the operation button 335 is in the ON state, the user uses the portable gas suction device 300. Is determined to be used, and the process proceeds to the steps of gas release (S230 to S260) and vital sign measurement (S110 to S220 and S270 to S300).

In the vital sign measurement (S130 to S220 and S270 to S300) steps, first, the pulse a is measured from the user's finger by the pulse wave sensor 303a provided on the operation button 335 (S110). Further, the environmental temperature measuring means 301 measures the environmental temperature T1, and the infrared detecting means 302a provided on the operation button 335 measures the relative temperature T2 obtained from the infrared rays detected from the user's finger (S120, S130), and the body temperature calculating means. Body temperature b is calculated from the temperature difference between T1 and T2 according to 302b (S140). Further, the pressing pressure detecting means 303b provided on the operation button 335 detects the pressing force P on the operating button 335 of the user's finger (S150), and the blood pressure calculating means 303c calculates the blood pressure c from the pulse a and the pressing pressure P. (S160). Next, the biological reaction signal is set and generated by the biological reaction signal generating means 304a based on the measured / calculated pulse a, body temperature b, and blood pressure c (S170). Next, for noise cancellation, the magnitude of the generated biological reaction signals a, b, c and the predetermined thresholds c1, c2, c3, respectively, is determined by the biological reaction determining means 305b (S180), and each is larger than the threshold. In this case, the pulse a = A, the body temperature b = B, and the blood pressure c = C are set as the actual pulse, body temperature, and blood pressure (= vital signs) instead of noise (S190). Next, in order to make the vital sign information available, the vital sign signal generation means 304d generates the vital sign signal (S200), the recording means 306 records the vital sign signal (S210), and the transmission means 307 records the vital sign signal. Sent to the outside (S220). After S220, the process proceeds to S270 of the flow of server 400 in FIG. 6 (b).

The server 400 receives the signal by the receiving means 408 (S270), and determines whether the received signal includes the vital sign signal externally transmitted from the portable gas suction device 300 by the vital sign signal determining means 405a ( S280). When the vital sign signal is included, the vital sign signal is recorded by the recording means 406 (S290) and accumulated in the past vital sign signal by the data collecting means 409 (S300). Therefore, the server 400 acquires vital sign information of all users using the portable gas suction device 300, creates a database, and can be used as a platform for using the vital sign information of users.

Next, the gas release (S230 to S260) steps performed at the same time as the vital sign measurement (S130 to S220 and S270 to S300) steps when the operation buttons are ON will be described. First, a power supply signal to the mesh electrode 17 is generated for the release of gas (S230), and power is supplied from the battery 36 to the mesh electrode 17 to generate gas (S240). Further, a power supply signal to the LED substrate is generated by the mesh electrode power supply signal generation means 304b (S250), power is supplied to the LED substrate, and the LED 30b emits light by the LED light emitting means 30a (S260). The LED emission allows the user to confirm that the gas is being emitted. Therefore, the user can surely suck the colorless and transparent gas by performing the suction operation while checking the LED light emission.

In the portable gas suction device 300, gas suction can be performed at the same time as the acquisition of vital signs, so that the influence of the user's gas suction on the vital signs can be accumulated and recorded as information. Therefore, it is possible to propose a more effective gas suction method to the user by feeding back the accumulated information.

The embodiment of the portable gas suction device of the present invention has been described above. Subsequently, another embodiment of the portable gas suction device of the present invention will be described with reference to FIGS. 4 (b), 5 (b), and 7.
FIG. 4B shows the present invention in which the portable gas suction device of FIG. 4A is further provided with a control command receiving function from a server, a mobile terminal, or the like, and a glass substrate 330 is provided instead of the LED substrate 30. An example of the portable gas suction device 300 is shown. The user can confirm information such as the measured / calculated vital signs and the type / amount / time (described later) of the gas released from the server or the like by the display 330b provided on the glass substrate 330.
FIG. 5B shows a block diagram of the portable gas suction device 300. As a configuration different from the embodiment of FIG. 5A, the portable gas suction device 300 includes a glass substrate 330, a receiving means 308, and a required gas signal determining means 305c. Further, the server 400 has a different configuration from the embodiment of FIG. 5A, that is, a transmission means 407, a gas signal generation means 404a, an integrated data signal generation means 404b, an integrated data signal determination means 405b, a data calling means 410, and a required gas. The calculation means 500 is provided.
FIG. 7 is a diagram showing a flow of implementation of another example of the portable gas suction device 300. Hereinafter, other examples of the portable gas suction device 300 will be described with reference to FIGS. 5 (b) and 7 (a) to 7 (c).

In the flow chart of FIG. 7, as compared with the flow chart of FIG. 6, some steps S100 to S210 of vital sign measurement are common, but gas generation and LED light emission steps (S230 to S260) and steps on the server 400. It is not provided with S270 to S300, and instead the flows shown in FIGS. 7 (b) and 7 (c) are added. The flow after S210 (recording of vital sign signals) will be described below.
In FIG. 7A, in the portable gas suction device 300, after recording the vital sign signal, the power supply signal to the glass substrate 330 is generated by the display electrode power supply signal generation means 304c (S211), and the recorded vital is recorded. Based on the sine signal, power is supplied to the glass substrate 320 and the display 330 is displayed by the display light emitting means 330a (S212). This allows the user to confirm the vital signs. After that, the signal is transmitted externally (S220). After S220, proceed to S310 in FIG. 7 (b).

Next, in FIG. 7B, in the server 400, the server 400 acquires the vital sign information transmitted from the portable gas suction device 300, calculates the type, amount, and time of the gas required for the user, and calculates it. The flow of transmitting the result to the portable gas suction device 300 again will be described.
First, the signal is received by the receiving means 409 (S310), and it is determined whether or not there is a vital sign signal transmitted from the portable gas suction device 300 (S320). If there is a vital sign signal, the type, amount, and time of the gas based on the vital sign signal are calculated using the calculation means 500 and the registered data calling means 410a (details will be described later using S330, FIGS. 8 and 9). Explain to). After the calculation, the gas signal generation means 404a generates a necessary gas signal (S340) indicating information on the gas necessary for the user. Next, the vital sign signal and the required gas signal are recorded in the server 400 (S350) and transmitted to the outside (the present portable gas suction device 300) by the transmission means 407 (S360). After S190, proceed to S400 in Fig. 7 (c).

Next, FIG. 7C describes a flow in which the portable gas suction device 300 receives the required gas signal transmitted from the server 400 and releases a gas of a type, amount, and time suitable for the user.
First, the signal is received by the receiving means 308 (S400). Then, it is determined by the required gas signal determining means 305c whether the received signal includes the required gas signal (S410a), and if the required gas signal is included, the ON / OFF of the operation button is further determined (S420). , In the ON state, it is determined that the user is in the state of using the portable gas suction device 300. Next, the received required gas signal is amplified by an amplifier (not shown) and AD-converted by an AD conversion means (not shown) (S430). Next, a power supply signal to the mesh electrode 17 is generated (S440), power is supplied from the battery 36 to the mesh electrode 17, and gas is generated (S450). Further, a power supply signal to the glass substrate 330 is generated (S460), power is supplied to the glass substrate 330, and information on the required gas is displayed on the display 330 (S470). The display allows the user to see the type, amount and time of the released gas, along with vital signs.
If there is no signal in the judgment of S410a or S420, the gas is not released.

The flow of another embodiment of the present portable gas suction device 300 has been described above. Subsequently, with respect to the calculation (S330) of the type, amount, and time of the gas based on the vital sign signal using the calculation means 500 in the flow and the registration data calling means 410a described above, FIGS. 8 (a) and 8 (b) and This will be described in detail with reference to FIG.
The user has registered in advance information that does not change, such as the user's own gender and date of birth, on the portable gas suction device 300 or the homepage via the Internet, and also uses the portable gas suction device 300. After the start, register changing information such as weight, height, and amount of food as appropriate. From this information and the information based on the latest vital sign signal, the server 400 calculates the gas information suitable for the user.

Specifically, in the server 400, first, the registration information (D) of the user's weight, height, and meal amount and the registration information (E) of gender and date of birth, which cannot be measured by the portable gas suction device 300, are registered. It is called and set by the information calling means 410a (S500, S510), and then it is determined whether or not an integrated data signal (described later in FIG. 8B) that accumulates the user's past information and creates a database is received. It is determined (S520), and if it is received, it is set as signal information F (S530). Next, the required gas calculation table is generated by the required gas table creating means 500a based on the set information D, E (, F) (S540). The required gas calculation table is a program set to calculate the required gas, amount, and time suitable for the vital signs at each time for each user input / registration information. The user's vital signs pulse A, body temperature B, and blood pressure C are set as vital X (S550), and the required gas, amount, and time are obtained by searching (calculating) in the required gas calculation table using the table determination means 500b. Judge (S560).

In the determination in the required gas calculation table, typically, as shown in FIG. 9, gas information corresponding to the "room" based on the setting information such as each vital sign is set as the required gas. In the example of FIG. 9, for the sake of simplicity of display, a case where the vital signs and registration information are only three, pulse A, body temperature B, and body weight D, will be described (actually, other setting information such as blood pressure and gender are also considered. To do). For example, when the pulse A, the body temperature B, and the body weight D are a1, b1, and d1, respectively, the "room" of r1 in the space is determined and selected. The gas information corresponding to the "room" judged / selected from the setting information is set as the gas required by the user.

Next, the determination / setting (S520, S530) of the above-mentioned integrated data signal will be described with reference to FIG. 8B. FIG. 8B shows a flow in which an integrated data signal is generated in the server 400 in order to calculate gas information more suitable for the user by referring to the accumulated information from the user's past.
First, the server 400 receives the latest signal (S600), then calls the past accumulated data by the integrated data calling means 410b (S610), and uses the latest signal (data) and the past integrated data as the vital sign. A signal related to the system of the portable gas suction device 300, which is a signal, a required gas signal, a user input information signal, and a pre-registered user registration information signal, is set (S620). Next, the past accumulated data is updated (S630) based on the latest received information, and the new integrated data is signalized by the integrated data signal generation means 404b (S640). The aggregated data is updated from time to time as it is used by users around the world. Further, the generation of the required gas calculation table using the integrated data signal (S540 in FIG. 8A) is optimized and speeded up by performing deep learning by AI.

Although the two examples of the portable gas suction device 300 have been described above, the present invention is not limited to the above examples, and it goes without saying that the portable gas suction device 300 is appropriately modified. For example, when the vital signs pulse A, body temperature B, and blood pressure C are larger than the predetermined thresholds c4, c5, and c6, it is determined that the vital signs are abnormal, and LED light emission or display is performed. A configuration is conceivable in which the portable gas suction device 300 is provided with a generation means, and if this configuration is adopted, the user can suck gas based on whether or not his / her own vitals are abnormal and the abnormality is resolved. it can.

1 Body cover 2 Mixer 5 Nozzle 10 Electrolytic cell 13 Packing 14 Screw cap 16 Titanium electrode 17 Mesh electrode (positive and negative electrode)
18 Vent filter 20 O-ring 23 Umbrella valve 28 Terminal board 33 Control board 42 Control board 100, 300 Portable gas suction device 304, 404 Signal generation means 305, 405 Judgment means 307 Transmission means 308 Reception means 335 Operation button (operation means)
500 calculation means

In order to solve the above problems, in the present invention,
A battery, an operating means for transmitting a control signal requesting the generation of hydrogen gas and / or oxygen gas by a user touching or pressing a finger, a control board for controlling power supply from the battery, and the control board. A pair of positive and negative electrodes for energizing or blocking power from the battery, a water-storable electrolytic cell into which the pair of positive and negative electrodes are inserted, and a predetermined gas inside the electrolytic cell are allowed to flow in. A portable gas suction device including a nozzle capable of sucking the gas, wherein the operating means is arranged at the position of a finger when the user grips the gas during suction, and the user can use hydrogen gas and hydrogen gas. / Or when a finger is touched or pressed to request the generation of oxygen gas, the user's quantified vital sign is detected at the same time.

According to the present invention, Ru can be detected vital signs at the same time is operated with a finger the user when the suction switch (operation means) for requesting release such as hydrogen gas. Thus, the user can be viewed simultaneously user's health when the suction by portable gas suction device without a separate operation vital signs, can be selected gas and suction amount of such proper hydrogen To. Therefore, it can function as a health promotion device according to the actual physical condition of the individual user. In particular, in view of the social situation in which the utilization of data detected by the wearable terminal is required, this portable gas suction device can be positioned as a kind of wearable terminal, which is beneficial.

Claims (3)

A battery, an operating means for transmitting a control signal requesting the generation of hydrogen gas and / or oxygen gas by a user touching or pressing a finger, a control board for controlling power supply from the battery, and the control board. A pair of positive and negative electrodes for energizing or blocking electricity from the battery, a water-storable electrolytic cell into which the pair of positive and negative electrodes are inserted, and a predetermined gas inside the electrolytic cell are allowed to flow in. A portable gas suction device equipped with a nozzle capable of sucking the gas.
The operating means is a portable gas suction device that detects a user's quantified vital signs when the user's finger touches or presses with the finger. The portable gas suction device according to claim 1, wherein the operating means transmits a control signal for generating a predetermined amount of hydrogen gas and / or oxygen gas based on the detected vital signs to the control board. .. A vital sign transmitting means for externally transmitting the vital signs detected by the operating means, and
The portable gas according to claim 1 or 2, wherein the control board includes a power signal receiving means for receiving a control signal for controlling power supply from the battery to the pair of positive and negative electrodes from the outside and transmitting the power signal to the control board. Suction device.