CN112263766B

CN112263766B - Large-capacity oxyhydrogen machine

Info

Publication number: CN112263766B
Application number: CN202011145761.8A
Authority: CN
Inventors: 杨锦邦; 阮超; 周缘缘; 阮笑芬; 徐子亮
Original assignee: Ziliangliangzi Shixing Medical Instrument Shanghai Co ltd
Current assignee: Shanghai Jiuweite biomedical engineering Co.,Ltd.
Priority date: 2020-10-23
Filing date: 2020-10-23
Publication date: 2022-12-06
Anticipated expiration: 2040-10-23
Also published as: CN112263766A

Abstract

The invention discloses a high-capacity oxyhydrogen machine, which belongs to the field of hydrogen absorption and comprises a machine shell, a water storage tank, an electrolytic tank, a gas-water separator, a mixer, a buffer tank, a gas storage tank and a respirator, wherein the water storage tank, the electrolytic tank, the gas-water separator, the mixer, the buffer tank, the gas storage tank and the respirator are arranged in the machine shell and are sequentially connected; wherein the internal piston that has of jar of buffer tank, install the pressure device who is connected with the piston on the casing, this pressure device is arranged in pressurizing and carrying the gas holder to the oxyhydrogen gas mixture in the buffer tank, and installs the check valve on the one-way gas-supply pipe of connection between gas holder and buffer tank, installs the stop valve on the pipeline that ends of connection between buffer tank and blender, and the respirator disposes the governing valve. The invention has reasonable design and larger capacity, not only can store a certain amount of oxyhydrogen for use at any time in advance, but also can adjust the air suction flow and supply the oxyhydrogen to a plurality of people for use at the same time.

Description

Large-capacity oxyhydrogen machine

Technical Field

The invention relates to the technical field of hydrogen absorption, in particular to a high-capacity oxyhydrogen absorption machine.

Background

The research of hydrogen molecules is a new field, the research has stronger antioxidation, a plurality of tumors and the like are chronic inflammation processes, the antioxidation is always a hot subject, and the hydrogen molecules are a new antioxidation tool and have better application prospect. The hydrogen molecules mainly aim at chronic diseases, the most basic is the strengthening effect of the oxidation stress resistance, the simple repairing effect is not, the matrix recovery is facilitated, and the idea is that the symptomatic treatment is not the treatment, for example, the oncology says that the oxidation stress is strengthened, the oxidation stress is removed, and the tumor is difficult to grow. Traffic police and sanitation workers working outdoors for a long time can promote the removal of oxidation free radicals from haze through hydrogen intake, and can generate oxidation stress action even if polluted air is sucked.

In this regard, hydrogen absorbers dedicated to hydrogen absorption or oxyhydrogen absorbers that simultaneously supply hydrogen and oxygen are available on the market. However, most of such devices are used in real time and have small capacity, that is, when the device is used, hydrogen and oxygen are generated first, and a user can absorb hydrogen and oxygen, so that a certain waiting time is required, and a large amount of hydrogen and oxygen cannot be stored in advance, so that the device cannot be used at any time. Moreover, the amount of the absorbed hydrogen and oxygen is limited by the gas production efficiency of the machine, and it is difficult to provide the hydrogen and oxygen for multiple users at the same time.

Disclosure of Invention

Aiming at the problem of small capacity of the hydrogen and oxygen absorption machine in the prior art, the invention aims to provide a large-capacity hydrogen and oxygen absorption machine.

In order to achieve the purpose, the technical scheme of the invention is as follows:

a high-capacity oxyhydrogen machine comprises a machine shell;

the water storage tank is fixedly arranged in the shell to store water;

the electrolytic cell is fixedly arranged in the shell and is connected with the water storage tank through a water conveying pipe so as to electrolyze input water after being electrified;

the gas-water separator is fixedly arranged in the shell, the inlet end of the gas-water separator is connected with the gas production end of the electrolytic cell to receive hydrogen and oxygen generated by electrolysis, and the outlet end of the gas-water separator obtains dry hydrogen and oxygen;

the gas inlet end of the mixer is connected with the outlet end of the gas-water separator to receive the dried hydrogen and oxygen, and the gas outlet end of the mixer obtains hydrogen-oxygen mixed gas;

the gas inlet of the buffer tank is connected with the gas outlet end of the mixer to receive the oxyhydrogen mixed gas, a piston is arranged in a tank body of the buffer tank, and a pressurizing device connected with the piston is arranged on the machine shell and used for pressurizing and conveying the oxyhydrogen mixed gas in the buffer tank;

the gas storage tank is connected with the gas outlet of the buffer tank through a one-way gas pipe to receive and store the oxyhydrogen mixed gas, and the one-way gas pipe is provided with a one-way valve; and

a respirator connected to the gas tank to provide a breathable oxyhydrogen mixture, the respirator being configured with a regulating valve.

Preferably, one side of the piston is connected with a piston rod, the free end of the piston rod penetrates through one end of the tank body and then is connected with the output end of the pressurizing device, and the air inlet and the air outlet are both arranged at the other end of the tank body.

Furthermore, the air inlet of the buffer tank is connected with the air outlet end of the mixer through a stop pipeline, and a stop valve is installed on the stop pipeline.

Further, the humidifying device also comprises a humidifying bottle which is fixedly arranged on the outer wall of the shell, and the respirator is connected with the air storage tank through the humidifying bottle.

Further, the gas storage tank is connected with the humidification bottle through an adjusting pipe, and the adjusting valve is installed on the adjusting pipe.

Furthermore, a pressure sensor for detecting the internal pressure of the buffer tank and the internal pressure of the gas storage tank is installed in the machine shell.

Preferably, the buffer tank is arranged horizontally, and the pressurizing device comprises a motor and a crank-slider mechanism driven by the motor.

Furthermore, an elastic reset piece is fixedly installed in the machine shell, and elastic potential energy for resetting the piston is stored in the elastic reset piece.

Preferably, the respirator is a breathing mask or an inhalation tube.

Preferably, the water storage tank is connected with the electrolytic cell through gravity self-flow; or a water delivery pump is arranged between the water storage tank and the electrolytic bath.

By adopting the technical scheme, due to the arrangement of the buffer tank, the gas storage tank and the pressurizing device, the electrolytic cell generates hydrogen and oxygen, and after the hydrogen and oxygen are conveyed to the buffer tank, the hydrogen and oxygen can be conveyed into the gas storage tank serving as a pressure storage container by the pressurizing device in a high-pressure conveying mode for storage, so that the large storage capacity is realized, the hydrogen and oxygen absorption machine can be ensured to store a certain amount of mixed gas of hydrogen and oxygen at any time, the hydrogen and oxygen absorption service can be provided at any time, and the simultaneous use of people can be easily realized.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure of the buffer tank of the present invention.

In the figure, 1-a machine shell, 2-a water storage tank, 3-an electrolytic tank, 4-a gas-water separator, 5-a mixer, 6-a buffer tank, 61-a tank body, 62-a piston, 63-a piston rod, 64-an air inlet, 65-an air outlet, 7-a pressurizing device, 8-a gas storage tank, 9-a one-way valve, 10-a respirator, 11-an elastic resetting piece, 12-a humidifying bottle, 13-a stop valve and 14-a regulating valve.

Detailed Description

The following description of the embodiments of the present invention will be made with reference to the accompanying drawings. It should be noted that the description of the embodiments is provided to help understanding of the present invention, and is not intended to limit the present invention. In addition, the technical features involved in the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

It should be noted that in the description of the present invention, the terms "upper", "lower", "left", "right", "front", "rear", and the like indicate orientations or positional relationships based on structures shown in the drawings, and are only used for convenience in describing the present invention, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

The terms "first" and "second" in the present technical solution are only used to distinguish the same or similar structures or the corresponding structures having similar functions, and are not the arrangement of the importance of the structures, nor are they the order, or comparison of the sizes, or other meanings.

In addition, unless expressly stated or limited otherwise, the terms "mounted" and "connected" are to be construed broadly, such that a connection may be fixed or removable or integral; can be mechanically or electrically connected; the two structures can be directly connected or indirectly connected through an intermediate medium, and the two structures can be communicated with each other. To those skilled in the art, the specific meanings of the above terms in the present invention can be understood in light of the present general concepts, in connection with the specific context of the scheme.

Example one

A large capacity oxyhydrogen inhalation machine is provided, as shown in figure 1, comprising a machine case 1, a water storage tank 2, an electrolytic bath 3, a gas-water separator 4, a mixer 5, a buffer tank 6, a pressurizing device 7, a gas storage tank 8, a one-way valve 9 and a breather 10 which are arranged on the machine case 1:

wherein, casing 1 is closed structure, and its inside has the accommodation space, and casing 1 is formed by metal or plastic frame and panel concatenation to panel passes through the bolt or connects the buckle can dismantle fixedly.

The water storage tank 2 is fixedly installed at one side (for example, the left side) of the lower portion in the cabinet 1 by bolts to store water, and the top of the cabinet 1 is provided with a water filling port which is communicated with the water storage tank 2 by a pipeline, and the lower portion of the cabinet 1 is further provided with a water outlet which is communicated with the bottom of the water storage tank 2 by a pipeline so as to be drained, and the water filling port and the water outlet are both provided with sealing plugs.

The electrolytic cell 3 is fixedly arranged at the lower part in the machine shell 1, and the electrolytic cell 3 is connected with the water storage tank 2 through a water delivery pipe so as to electrolyze the input water after the power is on; wherein, the electrolytic bath 3 can adopt one or more of three modes of alkaline electrolytic hydrogen production (AEC), solid polymer electrolytic hydrogen production (SPE) and solid oxide electrolytic hydrogen production (SOEC). In this embodiment, the electrolysis tank 3 is wholly located the below of water storage tank 2 to the water that the electrolysis was used is carried to electrolysis tank 3 to water storage tank 2 through the mode that gravity flows automatically, and, is provided with stop valve 13 on the raceway between water storage tank 2 and electrolysis tank 3, is convenient for control the break-make of electrolysis water.

In one embodiment, a water pump is provided between the water storage tank 2 and the electrolytic bath 3, so that the water for electrolysis in the water storage tank 2 is pumped to the electrolytic bath 3 by the water pump in a pressure pumping manner.

The gas-water separator 4 is fixedly arranged in the shell 1 and is positioned at the right side of the electrolytic cell 3, the gas-water separator 4 is used for separating gas and water which are mixed together, the inlet end of the gas-water separator 4 is connected with the gas production end of the electrolytic cell 3 to receive hydrogen and oxygen generated by electrolysis, and the outlet end of the gas-water separator 4 obtains dry hydrogen and oxygen.

The mixer 5 is fixedly arranged in the machine shell 1, is positioned at the right side of the electrolytic bath 3 and is arranged side by side with the gas-water separator 4. The inlet end of the mixer 5 is connected with the outlet end of the gas-water separator 4 to receive the dried hydrogen and oxygen obtained above, and the outlet end of the mixer 5 obtains the hydrogen-oxygen mixture. By the arrangement of the mixer 5, the hydrogen gas and the oxygen gas can be sufficiently mixed.

The buffer tank 6 is fixedly installed in the casing 1 and is positioned above the mixer 5. The air inlet of the buffer tank 6 is connected with the air outlet end of the mixer 5 to receive the fully mixed oxyhydrogen mixture. The buffer tank 6 specifically includes a tank body 61, a piston 62 located in the tank body 61, and a piston rod 63 fixed on the piston 62, as shown in fig. 2, the tank body 61 is horizontally arranged as a whole, a through hole for the free end of the piston rod 63 to pass through is provided on the end face side wall of the left end of the tank body, an air inlet 64 and an air outlet 65 are provided on the end face side wall of the right end of the tank body, the air inlet 64 is connected with the air outlet end of the mixer 5 through a cut-off pipeline, and the cut-off pipeline is also provided with a cut-off valve 13. In addition, a pressurizing device 7 is fixedly installed in the machine shell 1, the pressurizing device 7 is positioned above the buffer tank 6, the pressurizing device 7 is in driving connection with the piston 62 to drive the piston 62 to reciprocate, so as to pressurize and convey the oxyhydrogen mixture in the buffer tank 6 in a hurry way, for example, the pressurizing device 7 comprises a motor and a crank block mechanism driven by the motor, and the free end of the piston rod 63 is fixed on a block component of the crank block mechanism. In this embodiment, a speed reducer is further installed in the casing 1, an input end of the speed reducer is in driving connection with the motor, a flywheel is installed at an output end of the speed reducer, and the sliding block is connected to an eccentric position of the flywheel through a connecting rod.

The air storage tank 8 is fixedly arranged in the machine shell 1, in particular to the right side of the machine shell 1. The gas storage tank 8 is connected with the gas outlet 65 of the buffer tank 6 through a one-way gas pipe to receive and store the mixed hydrogen and oxygen gas, and the one-way gas pipe is provided with a one-way valve 9 which enables the mixed hydrogen and oxygen gas to flow to one side of the gas storage tank 8 from one side of the buffer tank 6.

The respirator 10 is connected to the reservoir 8 by a conduit to provide an inhalable mixture of hydrogen and oxygen, and the respirator 10 is provided with a regulator valve to facilitate the user's adjustment of the amount of inspiration. For example, the respirator 10 may be a respiratory mask or an inhalation tube.

When the device is used, electrolysis water is added into the water storage tank 2 in advance, the stop valve on the water pipeline enables the electrolysis water to flow into the electrolytic tank 3, the power supply of the electrolytic tank 3 is connected, the electrolytic tank 3 starts to generate hydrogen and oxygen, a fully mixed hydrogen-oxygen mixer is obtained under the separating and mixing actions of the gas-water separator 4 and the mixer 5, then the stop valve on the stop pipeline is opened, and the hydrogen-oxygen mixed gas enters the buffer tank 6 for buffering; when a certain amount of gas is stored in the buffer tank 6, the stop valve on the stop pipeline is closed, the pressurizing device 7 is started, the pressurizing device 7 drives the piston 62 to move so as to pressurize the hydrogen-oxygen mixed gas in the buffer tank 6, and the gas flows into the gas storage tank 8 to be stored after the one-way valve 9 on the one-way gas pipe is pushed open, and can be stored according to the capacity of the gas storage tank 8 so as to be used by one or even a plurality of users in real time; when a user needs to inhale oxygen and hydrogen, the respirator 10 is worn, and the flow of inhaling is adjusted by the adjusting valve, and then the mixed gas of oxygen and hydrogen stored in the gas storage tank 8 is continuously output for use. Therefore, the oxyhydrogen absorption machine in the embodiment can store the oxyhydrogen mixture, provide oxyhydrogen absorption service at any time, adjust flow and be used by multiple people.

It can be understood that, since the oxyhydrogen mixture discharged from the mixer 5 has no large pressure, in order to enable the piston 62 to return to the left side of the tank 61, in one embodiment, an elastic return member 11 is fixedly installed in the housing 1, and the elastic return member 11 stores elastic potential energy for driving the piston 62 from the right side to the left side of the tank 61. For example, the elastic restoring member 11 is a coil spring, one end of which is fixed to the housing 1 and the other end of which is fixed to the slider, and indirectly drives the piston 62 to restore by driving the slider to restore.

In one embodiment, a pressure sensor for detecting the internal pressure of the buffer tank 6 and the internal pressure of the gas storage tank 8 is installed in the machine case 1, and a user or a controller can determine whether to control the electrolytic tank 3 for the water electrolysis operation and whether to control the pressurizing device 7 for the pressurizing and delivering operation according to the detection data of the pressure sensor. For example, an operation panel is installed on the top surface or the side surface of the casing 1, the operation panel is in communication connection with the pressure sensor to receive the pressure signal, and is in electrical connection with the stop valve, the pump, the motor and the electrolytic tank to control the working state of the operation panel, and meanwhile, the operation panel is provided with a control button to facilitate the operation of a user.

In one embodiment, a heat dissipation fan is disposed in the casing 1 for heat dissipation, and an air inlet and an air outlet are disposed on the side wall of the casing 1.

In one embodiment, a water level window for observing the water level of the water storage tank 2 is provided on a side wall of the housing 1.

Example two

The difference from the first embodiment is that: in this embodiment, in order to ensure the mixing effect of the hydrogen and oxygen inhaled by the user, a mixer is additionally disposed between the respirator 10 and the gas storage tank 8, and the mixer is installed inside the cabinet 1, for example, above the gas storage tank 8. Via which the respirator 10 is connected to the air reservoir 8.

In one embodiment, the humidifying device further comprises a humidifying bottle 12, the humidifying bottle 12 is fixedly arranged on the outer wall of the right side of the machine shell 1, and the respirator 10 is connected with the air storage tank 8 through the humidifying bottle 12. The gas reservoir 8 is now connected to the humidification bottle 12 via a control tube, on which the above-mentioned control valve 14 is mounted.

The embodiments of the present invention have been described in detail above with reference to the accompanying drawings, but the present invention is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, and the scope of protection is still within the scope of the invention.

Claims

1. A high-capacity oxyhydrogen machine is characterized in that: comprises a casing;

the water storage tank is fixedly arranged in the shell to store water;

the gas inlet of the buffer tank is connected with the gas outlet end of the mixer to receive the oxyhydrogen mixed gas, a piston is arranged in a tank body of the buffer tank, a pressurizing device connected with the piston is installed on the casing and used for pressurizing and conveying the oxyhydrogen mixed gas in the buffer tank, an elastic resetting piece is fixedly installed in the casing, and the elastic resetting piece stores elastic potential energy for resetting the piston;

2. A high capacity oxyhydrogen suction machine according to claim 1, characterized in that: one side of the piston is connected with a piston rod, the free end of the piston rod penetrates through one end of the tank body and then is connected with the output end of the pressurizing device, and the air inlet and the air outlet are arranged at the other end of the tank body.

3. A high capacity oxyhydrogen generator according to claim 1, characterized in that: the air inlet of the buffer tank is connected with the air outlet end of the mixer through a stop pipeline, and a stop valve is installed on the stop pipeline.

4. A high capacity oxyhydrogen generator according to claim 1, characterized in that: still include the humidifying bottle, humidifying bottle fixed mounting on the outer wall of casing, just the respirator via the humidifying bottle with gas holder connection.

5. The high capacity oxyhydrogen generator according to claim 4, characterized in that: the air storage tank is connected with the humidification bottle through an adjusting pipe, and the adjusting valve is installed on the adjusting pipe.

6. A high capacity oxyhydrogen suction machine according to claim 1, characterized in that: and a pressure sensor for detecting the internal pressure of the buffer tank and the internal pressure of the gas storage tank is arranged in the shell.

7. A high capacity oxyhydrogen suction machine according to claim 1, characterized in that: the buffer tank is horizontally arranged, and the pressurizing device comprises a motor and a crank-slider mechanism driven by the motor.

8. A high capacity oxyhydrogen suction machine according to claim 1, characterized in that: the respirator is a breathing mask or an air suction pipe.

9. A high capacity oxyhydrogen generator according to claim 1, characterized in that: the water storage tank is connected with the electrolytic cell through gravity self-flow; or a water delivery pump is arranged between the water storage tank and the electrolytic bath.