CN111556768A

CN111556768A - Portable gas suction device

Info

Publication number: CN111556768A
Application number: CN201980007203.4A
Authority: CN
Inventors: 竹原隆
Original assignee: Water Bank Co ltd
Current assignee: Water Bank Co ltd
Priority date: 2018-01-09
Filing date: 2019-01-08
Publication date: 2020-08-18
Also published as: JPWO2019139011A1; WO2019139011A1; JP6786754B2; KR20200096799A; KR102466246B1

Abstract

The present invention provides a portable gas suction device which can detect basic vital signs of a user and transmit the same to the outside even if a separate wearable terminal or the like is not prepared. The portable gas suction device of the present invention includes: a battery; an operating device which is touched or pressed by a user's finger to transmit a control signal requesting generation of hydrogen and/or oxygen; a control substrate that controls power supply from the battery; a pair of positive and negative electrodes for supplying or interrupting power from the battery through the control board; an electrolytic bath capable of storing water, the pair of positive and negative electrodes being inserted into the interior thereof; a permeation device capable of permeating only a predetermined gas inside the lid electrolytic tank; and a suction nozzle capable of sucking the gas released from the permeation mechanism, wherein the operating mechanism detects the digitized vital signs of the user when the user touches or presses the operating mechanism with a finger.

Description

Portable gas suction device

Technical Field

The present invention relates to a portable gas suction device for sucking hydrogen gas or the like for the purpose of promoting the health of a user, which detects the vital signs of the user and sucks gas corresponding to the actual physical condition when an operation button or the like of the portable gas suction device is operated, thereby promoting the health of each user.

Background

In recent years, the availability of hydrogen has been receiving attention in various animal disease experiments such as neurodegenerative diseases and acute lung diseases, and in human clinical experiments in metabolic syndrome, diabetes, and the like, and various studies in medical applications have been actively conducted. In addition, even in a so-called non-sick person who does not suffer from a specific disease, it is recommended to take hydrogen into the body in order to prevent aging and promote beauty and health, particularly in various states such as exercise, diet, smoking, staying in an ultraviolet ray/polluted environment, and high stress such as insufficient sleep and long-term labor.

In addition to hydrogen, oxygen is also used to generate cellular energy and is an essential element for the human body to metabolize. Focusing on oxygen activation of human cells, studies have recently shown that conscious uptake of oxygen into the body has been effective in order to recover from fatigue, promote natural healing of disease states such as fracture, improve blood circulation disorders, beautify the skin, eliminate stress, and the like.

In view of the above circumstances, in recent years, a hydrogen gas generating device capable of taking in hydrogen gas and oxygen gas has been provided, and the applicant has also provided a rechargeable, small-sized, inexpensive portable gas suction device which can be carried and transported by a user and which can selectively generate hydrogen gas and oxygen gas.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2004-41949

Patent document 2: japanese patent application No. 2014-019640

Disclosure of Invention

Problems to be solved by the invention

However, since the intake of hydrogen gas or the like using the conventional hydrogen gas or the like generating device is performed by the user himself/herself for the purpose of managing the physical condition and the intake of hydrogen gas or the like is performed when necessary according to his/her own judgment, it is not always possible to take a proper amount of hydrogen gas or the like when necessary, and it is not always possible to take the hydrogen gas or the like as a tool for promoting health. On the other hand, in recent years, basic vital signs related to heart rate, respiration rate, and the like can be daily measured, and thus, the physical condition of the user can be easily diagnosed in real time.

As such a vital sign measurement device, there is a general-purpose wearable terminal which has been remarkably developed in recent years, but depending on users, there are many cases where: a case without an additional wearable terminal, a case without or without wearing a wearable terminal on a daily basis.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a portable gas suction device capable of detecting a basic vital sign of a user and transmitting the same to the outside without preparing a separate wearable terminal or the like, and also capable of sucking a suitable gas corresponding thereto.

Means for solving the problems

In order to solve the above problem, the present invention provides a portable gas suction device including: a battery; an operation device (for example, refer to the operation button 335 in the present embodiment) which is touched or pressed by a finger of a user to transmit a control signal requesting generation of hydrogen and/or oxygen; a control board (for example, see

control boards

33 and 42 in the present embodiment) that controls power supply from the battery; a pair of positive and negative electrodes (for example, see the mesh-shaped electrode 17 in the present embodiment) for supplying or interrupting power from the battery via the control board; an electrolytic cell (for example, refer to the electrolytic cell 10 in the present embodiment) capable of storing water, into which the pair of positive and negative electrodes are inserted; and a suction nozzle (for example, refer to the mixer 2 and the suction nozzle 5 in the present embodiment) capable of flowing a predetermined gas inside the electrolytic cell into and sucking the gas, wherein the operating device detects a digitized vital sign of a user when the user touches or presses the operating device with a finger.

According to the present invention, since the vital sign of the user can be detected by the switch (operation device) that requests release of hydrogen gas, the portable gas suction device can be made to function as a health promotion device that is in accordance with the actual physical condition of the user, and the health promotion device can select an appropriate amount of gas such as hydrogen gas or the like to be sucked while observing the health condition of the user. In particular, it is advantageous to locate the portable gas suction device of the present invention as a wearable terminal, even in view of social situations that require effective use of data detected by the wearable terminal.

Further, it is preferable that the operating device sends a control signal for requesting generation of a predetermined amount of hydrogen and/or oxygen set in advance to the control substrate based on the detected vital sign.

According to this operation device, the amount of hydrogen gas or the like generated can be controlled in accordance with the vital signs of the user detected when the portable gas suction device of the present invention is used, and the hydrogen gas or the like can be ingested by the user, and appropriate health promotion can be performed in accordance with the current physical condition of each user.

As another configuration, the portable gas suction device of the present invention may include: a vital sign transmission device that transmits the vital sign detected by the operation device to the outside; and a power signal receiving device that receives a control signal for controlling the supply of power from the battery to the pair of positive and negative electrodes through the control board from outside and transmits the control signal to the control board.

In this portable gas suction apparatus, the detected vital signs of the user are transmitted to an external server or a cloud server, the required amount of hydrogen gas is analyzed by an application installed in another wearable terminal or the like, and a control signal for supplying electric power to the pair of positive and negative electrodes of the portable gas suction apparatus is returned in accordance with the analysis, so that health promotion in accordance with the actual physical condition can be performed. In the case of the portable gas suction device, it is also advantageous for a user who is not aware of the amount of gas required according to vital signs or the like.

ADVANTAGEOUS EFFECTS OF INVENTION

The portable gas suction device of the present invention enables a user to suck hydrogen gas or the like at a desired place/time, and accordingly, even if other wearable terminals or the like are not prepared, the portable gas suction device itself can detect basic vital signs while performing a suction operation, and can suck hydrogen gas or the like corresponding to the actual physical condition of the user.

Further, according to the portable gas suction device of the present invention, since appropriate gas selection/gas amount control can be performed based on the individual vital signs of the user who is actually used, even a user who does not have special knowledge can perform gas intake necessary for health promotion of the user.

Drawings

Fig. 1 is an assembled exploded view illustrating components of the portable gas suction device of the present invention.

Fig. 2 shows a view from each direction of the portable gas suction device of the present invention of fig. 1, (a) of fig. 2 shows a left side view, (b) of fig. 2 shows a front view, (c) of fig. 2 shows a right side view, (d) of fig. 2 shows a bottom view, and (e) of fig. 2 shows a top view.

Fig. 3 shows a cross-sectional view of the portable gas suction device of the present invention of fig. 1 to 2 along line a-a of fig. 2 (c).

Fig. 4 (a) shows a photographic view of an embodiment of the portable gas suction apparatus of the present invention, and fig. 4 (b) shows a photographic view of another embodiment of the portable gas suction apparatus of the present invention.

Fig. 5(a) shows a block diagram of an embodiment of the portable gas suction device of the present invention.

Fig. 5(b) shows a block diagram of another embodiment of the portable gas suction device of the present invention.

Fig. 6(a) shows a flow of an implementation of the portable gas suction device of the present invention.

Fig. 6(b) shows a flow of implementation of the portable gas suction device of the present invention.

Fig. 7(a) shows a flow of another example of the portable gas suction apparatus according to the present invention.

Fig. 7(b) shows a flow of another example of the portable gas suction apparatus of the present invention.

Fig. 7(c) shows a flow of another example of the portable gas suction apparatus of the present invention.

Fig. 8(a) shows a part of the flow in the embodiment of the portable gas suction device of the present invention of fig. 7.

Fig. 8(b) shows a part of the flow in the embodiment of the portable gas suction device of the present invention of fig. 7.

Fig. 9 shows a schematic diagram for explaining a calculation method of a required gas.

Detailed Description

Hereinafter, the structure of the portable gas suction device of the present invention will be described by way of example with reference to fig. 1 to 3. The portable gas suction apparatus of the present invention is not limited to the portable gas suction apparatus shown in fig. 1 to 3, but includes various modifications of the portable gas suction apparatus.

First, with reference to fig. 1 to 3, the basic configuration of the portable gas suction apparatus other than the vital sign detection function will be described on the premise of describing the portable gas suction apparatus of the present invention. Fig. 1 is an assembled exploded view illustrating the components of a portable gas suction device 100. Further, fig. 2 shows a view seen from each direction of the portable gas suction device 100 of fig. 1, in which (a) of fig. 2 shows a left side view, (b) of fig. 2 shows a front view, (c) of fig. 2 shows a right side view, (d) of fig. 2 shows a bottom view, and (e) of fig. 2 shows a top view. In the present specification, the terms "vertical direction" and "longitudinal direction" mean the vertical direction and the longitudinal direction of the paper surface of (b) in fig. 2, and the terms "width direction", "lateral direction" and "side portion" mean the horizontal direction, the lateral direction, and the left and right side portions of the paper surface of (b) in fig. 2.

Further, fig. 3 shows a cross-sectional view of the portable gas suction device 100 of fig. 1 to 2 along line a-a of fig. 2 (c). The portable gas suction device 100 will be described below with reference mainly to the exploded view of fig. 1, and for convenience of description, other drawings will be referred to. The main body cover 1 is provided with: a battery housing portion 43 having an opening at the upper side, and into which the battery (rechargeable lithium battery) 36 is inserted/housed in the longitudinal direction from the opening; and an electrolytic cell housing part 44 which is arranged in the longitudinal direction of the battery housing part 43 and is insertable into the lower part of the electrolytic cell 10. The main body cover 1 has a shape in which the battery housing portion 43 side is long and the upper portion of the electrolytic cell housing portion 44 side is cut to be inclined to the side. The bottom of the body cover 1 can open/close the bottom of the battery receiving portion 43 through the body bottom cover 6, and the battery 36 is inserted from the bottom and closed using the screw 38 with a cross hole at the time of assembly. Further, the body cover 1 is provided with two

control boards

33, 42 to sandwich the battery 36 in the longitudinal direction on both sides of the side portion of the battery housing portion 43. The control board 33 on the side surface side of the body cover 1 is a main control board that controls the supply of electric power from the battery 36 to the control board 42 on the side of the electrolytic cell 10, in which the electrolytic cell 10 supplies electric power to the mesh electrode 17 (electrode plate) and the suction portion 32. The suction unit 32 is not essential, and for example, a device that releases fragrance when power is supplied may be considered.

In the case of the portable gas suction device 100 shown in fig. 1 to 3, the basic configuration is such that there is no suction function of hydrogen gas or the like, such as a vital sign detection function of a user, an external vital sign transmission function, and a control command reception function from a portable terminal or the like.

On the side surface of the body cover 1, an operation button 35 for the control board 33, an LED30, and a connector for charging the battery 36 are provided at the

openings

9a, 9b, 9c of the decorative plate 9, and when the operation button 35 is pressed, a power supply signal is sent to the control board 42 through the control board 33, 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, a power supply signal is transmitted to the LED substrate 30 through the control substrate 33, and the LED is illuminated by the LED substrate 30, so that a user can recognize generation of hydrogen or oxygen.

In the example of fig. 1 to 3, the condition operation button 35 for supplying power to the mesh electrode 17 is manually pressed, but the control board 42 receiving a command signal from a portable terminal or the like described later may control the supply of power to the mesh electrode 17. For example, a receiving terminal, not shown, receives a predetermined power supply signal, transmits the signal to the control board 42, and supplies power from the battery 36 to the mesh electrode 17 based on the power supply signal to stop the same.

When a current is supplied, the mesh electrodes 17 are arranged in a pair of two in the vertical direction, and form positive and negative electrodes, respectively, in response to the positive and negative electric powers from the battery 36. The upper end of the mesh electrode 17 is obliquely cut so as to correspond to the boundary line between the reduced diameter portion 45 of the electrolytic cell 10 and the water storage body portion 46. The lower end of the mesh electrode 17 is connected to a rod-shaped titanium electrode 16 so as to be able to stand on the terminal substrate 28 and be electrically connected to the terminal substrate 28. A seal 13 (made of resin such as silicon) attached to the terminal substrate 24 and an O-ring (made of resin such as silicon, hereinafter, the same O-ring) attached around the titanium electrode 16 are provided so as to shield water from the mesh substrate 17 and the terminal substrate 28 in a state where the mesh electrode 17 is erected.

The electrolytic cell 10 is a water storage container, and is formed by integrally forming a reduced diameter portion 45 and a water storage body portion 46 in this order from below, and is fluidly connected to each other inside. The water storage body 46 is opened upward to enable water injection, and is half-closed by attaching the electrolytic cell cover 12. The electrolytic cell cover 12 is provided with a through opening 12a which vertically penetrates therethrough and accommodates the umbrella valve 23, the nut 14, and the like. As shown in fig. 3, in the water storage body 46, the outer portion 46a is formed as 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 46b on the body cover 1 side is formed parallel to the outer portion 46a from the upper end to the central lower position and has a bottom portion 46c bent and inclined from the central lower position. The bottom portion 46c extends to a laterally intermediate position and is joined to the upper end of the reduced diameter portion 45.

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

A water guard 45d that extends to the opening 45c in an inclined manner substantially similar to the bottom 46c of the water storage body 46 is provided at a connection position between the lower end of the outer portion 46a of the water storage body 46 and the upper end of the outer portion 46a of the reduced diameter portion 45. The water guard plate 45d extends inside the entire area in the vertical direction of the paper of fig. 3. Therefore, even when the aqueous solution stored in the electrolytic cell 10 is electrolyzed and the water storage amount is reduced, water is always stored in substantially the entire area inside the reduced diameter portion 45. Specifically, when the water storage amount is reduced and a part of the air layer is formed in the electrolytic cell 10, first, since the reduced diameter portion 45 is thinner than the water storage main body portion 46, the reduced diameter portion 45 is filled with water without generating the air layer in a normal standing state as long as the water storage amount is not significantly reduced.

Even when the water storage amount is reduced to a certain level, it is conceivable that an air layer is generated in the reduced diameter portion 45 when the portable gas suction device 100 is tilted or horizontally placed, but in the present electrolytic cell 10, the reduced diameter portion 45 is filled with water even in such a case. Specifically, for example, when the water storage body 46 is inclined in the left direction of the drawing sheet of fig. 3, the bottom portion 46c serves as a baffle, and the air layer is formed on the inner portion 46b side of the water storage body 46. On the other hand, when the water stopper 45d is inclined in the right direction of the drawing sheet of fig. 3, the air layer is formed only on the outer portion 46a side of the water storage body 46. Therefore, the entire mesh electrode 17 disposed in the reduced diameter portion 45 is always in contact with water, and the amount of hydrogen or oxygen generated can be always ensured even when the user sucks in the lateral direction.

The upper end edge of the mesh electrode 17 is formed by obliquely cutting along the shape of the reduced diameter portion 45 and the opening 45c so that the electrode is immersed in the water in the reduced diameter portion 45 without a gap. Returning again to fig. 1, the lower end of the electrolytic cell 10 is closed by the electrolytic cell bottom 11, and the electrolytic cell bottom 11 is provided with a pair of through holes into which the mesh-like electrode 17 is inserted, and when the reduced diameter portion 45 of the electrolytic cell 10 is inserted into the electrolytic cell housing portion 44 of the lid main body 1, the mesh-like electrode 17 is positioned in the reduced diameter portion 45 through the through holes of the electrolytic cell bottom 11.

An umbrella valve 23 and the like attached to the through opening 12a of the electrolytic cell cover 12 at the upper end of the electrolytic cell 10 will be described. A nut 14 having an opening at the top and penetrating vertically is attached to the through opening 12a, a breather filter 18 is interposed between a hole at the bottom of the nut 14 and the bottom of the through opening 12a, and an O-ring 20 is inserted around the lower side of the nut 14. The breather filter 18 has a function of adjusting the internal pressure in the opening of the nut 14 using a minute hole and performing water/dust prevention. The O-ring 21 blocks water between the outer peripheral wall of the opening of the nut 14 and the inner peripheral wall of the through opening 12 a.

An umbrella valve 23 (made of a flexible material such as silicon) which moves in the vertical direction is attached to the opening of the nut 14, and when a user sucks the mouthpiece 5 and applies a negative pressure upward, the umbrella valve 23 moves upward and is connected to the fluid in the electrolytic cell 10 through the through hole in the bottom of the nut 14 and the through opening 12a of the cell cover 12. Therefore, when the suction nozzle 5 is sucked, the hydrogen gas or the oxygen gas accumulated in the electrolytic cell 10 while rising is discharged to the outside. On the contrary, when the user stops inhaling and the negative pressure is not applied, the umbrella-shaped valve 23 descends, the through hole at the bottom of the screw cap 14 is closed, and the release of hydrogen or oxygen in the electrolytic bath 10 is closed.

The mixer 2 is mounted from above on the cell cover 12 with the screw cap 14 and the umbrella valve 20. The mixer 2 has a cylindrical member 2a extending downward as shown in fig. 3, and the cylindrical member 2a forms a flow path for guiding the hydrogen gas or the oxygen gas upward from the umbrella valve 23 by inserting the lower end of the cylindrical member 2a into the opening of the nut 14. An O-ring 20 is provided around the outer peripheral wall of the cylindrical member 2a to seal a gap with the inner wall of the opening of the nut 14.

The mixer 2 and the cell cover 12 are fixed by installing locking buttons 3, 4. The lock buttons 3 and 4 are respectively sandwiched and fixed by being caught in the front-rear direction (the direction perpendicular to the paper surface of fig. 3) at the gap position in the vertical direction between the mixer 2 and the electrolytic tank cover 12. As shown in fig. 3, the mixer 2 is provided with a flow path 2b at its upper portion in the direction of the suction nozzle 5. The flow path 2b is connected to the flow path formed by the cylindrical member 2a, and guides hydrogen gas or oxygen gas as indicated by arrows in fig. 3.

Next, the fragrance releasing device (fragrance heater unit) 32 for generating fragrance air will be described. The fragrance heater 32 is supplied with electric power from a contact terminal 37 of the battery 36 to the battery 36, and releases fragrance-containing air generated inside upward. The contact terminal 37 is fastened to the joint 37 using a screw 38 with a cross-hole, and is held and fixed to the body cover 1 by the joint 8 and the mixer 2 when the mixer 2 is mounted. The mixer 2 is provided with a cylindrical member 2c extending downward in parallel with the cylindrical member 2a, and the upper end of the fragrance heater 32 is connected to the cylindrical member 2c, so that the fragrant air passes through the cylindrical member 2c (see the arrow in fig. 3), joins with the hydrogen gas or the oxygen gas, flows into the mouthpiece 5, and reaches the mouth of the user. Further, an O-ring 22 is disposed and sealed at a connection portion between the bottom of the suction nozzle 5 and the mixer 2. In the case of the example of fig. 1 to 3, the fragrance heater section 32 is configured to control the substrate 33 to supply power by pressing the button 35 (for example, by long-pressing the button 35) similarly to the mesh electrode 17, but there is also a case where: similarly to the mesh electrode 17, power is supplied from the control board 33 that receives a signal from a portable terminal or the like.

The basic structure of the portable gas suction device of the present invention has been described above, but the present invention is not limited to the above-described structure, and various modifications are certainly possible to those skilled in the art.

Next, an embodiment of the portable gas pumping device of the present invention having the basic configuration described above, such as a vital sign detection function of the user, an external vital sign transmission function, and a function of receiving a control command from a portable terminal, will be described with reference to fig. 4 to 9. The description of the same basic structure as described above is appropriately omitted for explanation.

First, an embodiment of the portable gas suction device according to the present invention will be described with reference to fig. 4 (a), 5(a), and 6.

Fig. 4 (a) is a photograph showing the portable gas pumping device 300 of the present invention having the vital sign detection function and the vital sign external transmission function of the user. The portable gas suction device 300 is provided with an operation button 335 for performing vital sign measurement and gas release.

Fig. 5(a) shows a block diagram of a portable gas suction device 300 of the present invention. The portable gas suction device 300 of the present invention includes: an operation button 335, a battery 36, a mesh electrode 17, an ambient temperature measuring device 301 for measuring vital signs, a body temperature measuring device 302, a pulse/blood pressure measuring device 303, an LED board 30 for displaying gas release by LEDs, and a control board 33 and/or 42 (hereinafter, referred to as a control board 33) for controlling generation of each signal and the like. The control board 33 includes: signal generation device 304, determination device 305, recording device 306, and transmission device 307. The server 400 that receives the signal transmitted from the portable gas suction device 300 of the present invention by the transmission device 307 includes: recording means 406, receiving means 408, data integration means 409, and vital sign signal determination means 405 a.

Fig. 6 is a diagram showing a flow of implementation of the portable gas suction device 300 of the present invention. Hereinafter, an embodiment of the portable gas suction apparatus 300 according to the present invention will be described with reference to fig. 5(a), mainly referring to fig. 6(a) and 6 (b).

The portable gas pumping device 300 of the present invention is switched to the usable state by pressing the operation button 335 by the user, and the release of gas and the measurement of the vital sign of the user are simultaneously performed.

In the portable gas pumping device 300 of the present invention, first, the ON/OFF of the operation button 335 is determined by the operation button ON/OFF determining means 305a (S100), and in the case of the ON state, it is determined that the user uses the portable gas pumping device 300 of the present invention, and the steps to the gas release (S230 to S260) and the vital sign measurement (S110 to S220 and S270 to S300) are proceeded.

In the vital sign measurement (S130 to S220 and S270 to S300), first, the pulse a is measured from the user' S finger through the pulse sensor 303a equipped at the operation button 335 (S110). Further, the ambient temperature T1 is measured by the ambient temperature measuring means 301, the relative temperature T2 obtained from infrared rays detected from the user' S finger is measured by the infrared ray detecting means 302a equipped at the operation button 335 (S120, S130), and the body temperature b is calculated from the temperature difference between T1 and T2 by the body temperature calculating means 302b (S140). Then, the pressing force P of the user' S finger on the operation button 335 is detected by the pressing force detection device 303b provided at the operation button 335 (S150), and the blood pressure c is calculated by the blood pressure calculation device 303c from the pulse wave a and the pressing force P (S160). Next, a living body reaction signal is set/generated by the living body reaction signal generating device 304a based on the measured/calculated pulse wave a, body temperature b, and blood pressure c (S170). Next, in order to eliminate the disturbance, the biological response determination device 305B determines the magnitudes of the generated biological response signals a, B, and C and the predetermined thresholds C1, C2, and C3 (S180), and when the magnitudes are larger than the thresholds, the pulse rate a is set to a, the body temperature B is set to B, and the blood pressure C is set to C as the actual pulse rate, body temperature, and blood pressure (vital signs) that are not the disturbance (S190). Next, in order to use the vital sign information, the vital sign signal is generated by the vital sign signal generating device 304d (S200), recorded by the recording device 306 (S210), and transmitted to the outside by the transmitting device 307 (S220). After S220, the flow proceeds to S270 of the server 400 in fig. 6 (b).

In the server 400, the signal is received by the receiving device 408 (S270), and it is determined by the vital sign signal determining device 405a whether or not the received signal contains a vital sign signal transmitted from the portable gas suction device 300 of the present invention to the outside (S280). In the case where the vital sign signal is included, the vital sign signal is recorded by the recording device 406 (S290) and integrated into the past vital sign signal by the data integration device 409 (S300). Therefore, vital sign information of all users using the portable gas pumping device 300 of the present invention can be acquired by the server 400, and the vital sign information is made into a database and can be used as a platform for using vital sign information of the users.

Next, the gas release (S230 to S260) step performed simultaneously with the vital sign measurement (S130 to S220 and S270 to S300) step in the case where the operation button is ON will be explained. First, in order to release the gas, a power supply signal to the mesh electrode 17 is generated (S230), and the gas is generated by supplying power to the mesh electrode 17 from the battery 36 (S240). Then, the mesh electrode power supply signal generating device 304b generates a power supply signal for the LED substrate (S250), supplies power to the LED substrate, and causes the LED30b to emit light by the LED light emitting device 30a (S260). By emitting light from the LED, the user can confirm that the gas is released. Therefore, the user can surely suck the colorless and transparent gas by performing the suction operation while confirming the light emission of the LED.

In the portable gas suction device 300 of the present invention, since the vital sign can be acquired and the gas can be sucked, the influence of the gas suction of the user on the vital sign can be recorded as information. Thus, it is also possible to suggest a more effective gas pumping method to the user by feedback of the integrated information.

The embodiments of the portable gas suction device of the present invention have been described above. Next, another embodiment of the portable gas suction device of the present invention will be described with reference to fig. 4 (b), 5(b), and 7.

Fig. 4 (b) shows an example of the portable gas suction device 300 of the present invention, which is provided with a function of receiving a control command from a server, a portable terminal, or the like, and is provided with a glass substrate 330 instead of the LED substrate 30 in the portable gas suction device of fig. 4 (a). The user can confirm information of measured/calculated vital signs, the kind, amount, time (described later) of released gas received from a server, etc. through the display 330b equipped at the glass substrate 330.

Fig. 5(b) shows a block diagram of the portable gas suction device 300 of the present invention. As a structure different from the embodiment of fig. 5(a), the portable gas suction device 300 of the present invention has: a glass substrate 330, a receiving device 308, and a required gas signal determination device 305 c. Further, as a configuration different from the embodiment of fig. 5(a), the server 400 includes: a transmitter 407, a gas signal generator 404a, an integrated data signal generator 404b, an integrated data signal determiner 405b, a data call device 410, and a desired gas calculating device 500.

Fig. 7 is a diagram showing an implementation flow of another example of the portable gas pumping device 300 of the present invention. Next, another embodiment of the portable gas suction apparatus 300 according to the present invention will be described with reference to fig. 5(b) and mainly with reference to fig. 7(a) to 7 (c).

In the flowchart of fig. 7, steps S100 to S210 of a part of vital sign measurement are common as compared with the flowchart of fig. 6, however, the gas generation and LED light emission steps (S230 to S260) and steps S270 to S300 in the server 400 are not provided, but the flows of fig. 7(b) and 7(c) are added instead. The following describes the flow after S210 (recording of vital sign signals).

In fig. 7(a), in the portable gas pumping device 300 of the present invention, after the vital sign signal is recorded, the power supply signal to the glass substrate 330 is generated by the display electrode power supply signal generating device 304c (S211), the glass substrate 320 is supplied with power based on the recorded vital sign signal, and the display 330 is displayed by the display light emitting device 330a (S212). Thus, the user can confirm the vital sign. After that, the signal is transmitted to the outside (S220). After S220, the process proceeds to S310 in fig. 7 (b).

Next, in fig. 7(b), the following flow is explained: in the server 400, the server 400 acquires the vital sign information transmitted from the portable gas pumping device 300 of the present invention, calculates the type, amount, and time of the gas required for the user, and transmits the calculated result to the portable gas pumping device 300 of the present invention again.

First, a signal is received by the receiving device 409 (S310), and it is determined whether there is a vital sign signal transmitted from the portable gas pumping device 300 of the present invention (S320). When the vital sign signal is present, the calculation device 500 and the registration data calling device 410a are used to calculate the type, amount, and time of the gas based on the vital sign signal (S330, fig. 8, and fig. 9 are used to be described in detail later). After the calculation, a gas signal generating device 404a generates a desired gas signal indicating gas information desired for the user (S340). Next, the vital sign signal and the desired gas signal are recorded in the server 400 (S350) and transmitted to the outside (the portable gas suction device 300 of the present invention) through the transmitting device 407 (S360). After S190, S400 in fig. 7(c) is entered.

Next, in fig. 7(c), the following flow is explained: the portable gas suction device 300 of the present invention receives the desired gas signal transmitted from the server 400, and releases the gas suitable for the kind, amount, and time of the user.

First, a signal is received by the receiving device 308 (S400). Then, the required gas signal determination device 305c determines whether or not the received signal includes a required gas signal (S410a), and further determines whether or not the operation button is ON/OFF when the required gas signal is included (S420), and determines that the user is in a state of using the portable gas suction device 300 when the operation button is ON. Next, the received desired gas signal is amplified by an amplifier (not shown) and AD-converted by an AD converter (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). Then, a power supply signal to the glass substrate 330 is generated (S460), power is supplied to the glass substrate 330, and information of the required gas is displayed on the display 330 (S470). The type, amount and time of the released gas can be confirmed by the user together with vital signs through the display.

When there is no signal in the determination of S410a or S420, the release of gas is not performed.

The flow of another embodiment of the portable gas suction device 300 according to the present invention is described above. Next, the calculation of the type, amount, and time of the gas based on the vital sign signal (S330) using the calculation device 500 and the registration data call device 410a in the above-described flow will be described in detail with reference to fig. 8(a), 8(b), and 9.

The user registers information on the sex, date of birth, and the like of the user himself or herself on the portable gas suction device 300 or a homepage via the internet, and also appropriately registers information on changes in weight, height, and food consumption after starting using the portable gas suction device 300 of the present invention. Based on this information and on the information based on the most recent vital sign signals, information suitable for the gas of the user is calculated in the server 400.

Specifically, in the server 400, first, the registration information calling device 410a calls and sets the registration information (D) of the weight, height, and food consumption and the registration information (E) of the sex, year, month, and day of birth of the user, which cannot be measured in the portable gas pumping device 300 of the present invention (S500, S510), and then, determines whether or not an integrated data signal (described later in fig. 8 (b)) obtained by integrating and databasing the past information of the user is received (S520), and if so, sets the signal information as the signal information F (S530). Next, the required gas calculation table is generated by the required gas table generation device 500a based on the set information D, E (F) (S540). The required gas calculation table is a program set to calculate required gas/amount/time suitable for vital signs at each time for input/registration information or the like of each user. The vital signs of the user, i.e., the pulse wave a, the body temperature B, and the blood pressure C, are set as the vital X (S550), and the table determination device 500B searches (calculates) the table of the calculation of the gas demand to determine the gas demand/amount/time (S560).

In the determination using the required gas calculation table, gas information corresponding to "room" based on setting information of each vital sign and the like is set as required gas schematically, for example, as shown in fig. 9. In the example of fig. 9, for the sake of simplifying the display, a case where the vital signs and the registered information are only three items, i.e., the pulse wave a, the body temperature B, and the body weight D, will be described (actually, other setting information such as the blood pressure and the sex is considered). For example, when the pulse a, the body temperature B, and the body weight D are a1, B1, and D1, respectively, "room" of r1 in the space is determined/selected. The gas information corresponding to the "room" determined/selected based on the setting information is set as the gas required for the user.

Next, the determination and setting (S520, S530) of the integrated data signal will be described with reference to fig. 8 (b). Fig. 8(b) shows a flow of generating an integrated data signal in the server 400 to calculate information more suitable for the gas of the user with reference to the past integrated information of the user.

First, the server 400 receives the latest signal (S600), and then, the past integrated data is called by the integrated data calling device 410b (S610), and as the latest signal (data) and the past integrated data, a signal related to the system of the portable gas pumping device 300 of the present invention is set, which is a vital sign signal, a desired gas signal, a signal of user input information, a signal of user registration information registered in advance, and the like (S620). Next, based on the received latest information, the past integration data is updated (S630), and the new integration data is signaled by the integration data signal generation means 404b (S640). The integrated data is updated at any time as users around the world use it. Further, the generation of the desired gas calculation table using the integrated data signal (S540 of fig. 8 (a)) is performed by deep learning by AI, thereby being optimized and speeded up.

Although two embodiments of the portable gas suction device 300 according to the present invention have been described above, the present invention is not limited to the above embodiments, and may be modified as appropriate. For example, a structure may be considered: if the portable gas suction device 300 of the present invention is provided with the abnormality determination device and the abnormality signal generation device for determining that there is a life abnormality and performing LED lighting or display on a display when the vital sign pulse a, the body temperature B, and the blood pressure C are greater than the predetermined threshold values C4, C5, and C6, the gas suction can be performed based on whether or not the abnormality is eliminated when there is an abnormality in the life of the user.

Description of the reference numerals

1 Main body cover

2 Mixer

5 suction nozzle

10 electrolytic cell

13 sealing element

14 nut

16 titanium electrode

17 mesh electrode (Positive and negative electrode)

18 ventilating filter

20O-ring

23 umbrella valve

28 terminal substrate

33 control substrate

42 control substrate

100. 300 portable gas suction device

304. 404 signal generating device

305. 405 judging device

307 transmitting apparatus

308 receiving device

335 operating button (operating device)

500 computing device

Claims

1. A portable gas suction device is provided with: a battery; an operating device which is touched or pressed by a user's finger to transmit a control signal requesting generation of hydrogen and/or oxygen; a control substrate that controls power supply from the battery; a pair of positive and negative electrodes for supplying or interrupting power from the battery through the control board; an electrolytic bath capable of storing water, the pair of positive and negative electrodes being inserted into the interior thereof; and a suction nozzle capable of flowing a predetermined gas inside the electrolytic cell and sucking the gas, wherein,

when the user touches or presses the operating device by a finger, the operating device detects the digitized vital sign of the user.

2. A portable gas pumping apparatus according to claim 1, wherein the operating means sends a control signal to the control substrate based on the detected vital signs, the control signal requesting the generation of a predetermined amount of hydrogen and/or oxygen, which is set in advance.

3. The portable gas suction device according to claim 1 or 2, comprising:

a vital sign transmission device that transmits the vital sign detected by the operation device to the outside; and

and a power signal receiving device for receiving a control signal for controlling the supply of power from the battery to the pair of positive and negative electrodes via the control board from the outside and transmitting the control signal to the control board.