WO2021121076A1 - 纳米氢气水制备系统及洗浴装置 - Google Patents
纳米氢气水制备系统及洗浴装置 Download PDFInfo
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- WO2021121076A1 WO2021121076A1 PCT/CN2020/134474 CN2020134474W WO2021121076A1 WO 2021121076 A1 WO2021121076 A1 WO 2021121076A1 CN 2020134474 W CN2020134474 W CN 2020134474W WO 2021121076 A1 WO2021121076 A1 WO 2021121076A1
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- gas
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F33/00—Other mixers; Mixing plants; Combinations of mixers
- B01F33/80—Mixing plants; Combinations of mixers
- B01F33/82—Combinations of dissimilar mixers
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61H—PHYSICAL THERAPY APPARATUS, e.g. DEVICES FOR LOCATING OR STIMULATING REFLEX POINTS IN THE BODY; ARTIFICIAL RESPIRATION; MASSAGE; BATHING DEVICES FOR SPECIAL THERAPEUTIC OR HYGIENIC PURPOSES OR SPECIFIC PARTS OF THE BODY
- A61H33/00—Bathing devices for special therapeutic or hygienic purposes
- A61H33/02—Bathing devices for use with gas-containing liquid, or liquid in which gas is led or generated, e.g. carbon dioxide baths
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61H—PHYSICAL THERAPY APPARATUS, e.g. DEVICES FOR LOCATING OR STIMULATING REFLEX POINTS IN THE BODY; ARTIFICIAL RESPIRATION; MASSAGE; BATHING DEVICES FOR SPECIAL THERAPEUTIC OR HYGIENIC PURPOSES OR SPECIFIC PARTS OF THE BODY
- A61H33/00—Bathing devices for special therapeutic or hygienic purposes
- A61H33/60—Components specifically designed for the therapeutic baths of groups A61H33/00
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F23/00—Mixing according to the phases to be mixed, e.g. dispersing or emulsifying
- B01F23/20—Mixing gases with liquids
- B01F23/29—Mixing systems, i.e. flow charts or diagrams
Definitions
- the invention relates to the technical field of hydrogen bath devices, in particular to a nano-hydrogen water preparation system and a bathing device.
- This fashionable bathing method does not need to add milk, but uses high-tech technology to convert ordinary water into milky white nano-high hydrogen-containing water.
- the principle of the nano-hydrogen water preparation system is to use molecular collision and ultra-high-frequency magnetic wave cutting to make the water molecules and microbubbles close to nanometer, thereby producing a large amount of milky white, high-concentration micro-nano-level hydrogen-rich water. As it is close to nanometerization, negative ions and water molecules can quickly penetrate the skin pores, remove dirt from the pores, and deeply clean the skin.
- the existing nano-hydrogen water production system includes a bathing vessel, a dissolved hydrogen water system, and a nano-bubble generating system.
- the dissolved hydrogen water system and the nano-bubbling generating system are two independent systems connected to the bathing vessel. , Resulting in many components and complex structure, relatively high cost, and undissolved hydrogen cannot be reused, resulting in a waste of hydrogen.
- one of the objectives of the present invention is to provide a nano-hydrogen water preparation system, which simplifies the system structure, reduces the cost, and can also reuse undissolved hydrogen to avoid wasting resources.
- the second objective of the present invention is to provide a bathing device using the above-mentioned nano-hydrogen water production system.
- the nano-hydrogen water preparation system includes a water inlet connector, a gas-liquid mixing pump, a first gas-liquid separator, a hydrogen generator, a second gas-liquid separator, a Venturi module, and a water outlet connector.
- the water inlet connector and the water outlet connector are both It is used to communicate with an external bath container, the water inlet connector is used for the water in the bath container to enter the nano-hydrogen water production system, and the water outlet connector is used for the nano-hydrogen water production system in the nano-hydrogen water production system.
- Hydrogen water enters the bath container, the water inlet connector is connected with the first inlet of the gas-liquid mixing pump, the outlet of the gas-liquid mixing pump is connected with the inlet of the first gas-liquid separator, the The first outlet of the first gas-liquid separator is in communication with the first inlet of the second gas-liquid separator, the outlet of the hydrogen generating device is in communication with the second inlet of the second gas-liquid separator, and the first The first outlet of the two gas-liquid separators is in communication with the second inlet of the gas-liquid mixing pump.
- the second gas-liquid separator has a second outlet for discharging water and liquid inside.
- the first gas-liquid The second outlet of the separator is in communication with the inlet of the Venturi module, and the outlet of the Venturi module is in communication with the water outlet joint.
- the hydrogen generating device is a first hydrogen production electrolytic cell
- the nano-hydrogen water production system further includes a second hydrogen production electrolytic cell and a raw water tank for storing water.
- the raw water tank has a first hydrogen production electrolytic tank.
- a water inlet, the anode chamber water inlet of the first hydrogen production electrolytic cell and the anode chamber water inlet of the second hydrogen production electrolytic cell are both connected with the water outlet of the raw water tank, and the first hydrogen production electrolytic cell
- the water outlet of the anode chamber and the water outlet of the anode chamber of the second hydrogen production electrolytic cell are both in communication with the second water inlet of the raw water tank, and the gas outlet of the first hydrogen production electrolytic cell is connected to the second gas-liquid
- the second inlet of the separator is in communication, and the gas outlet of the second hydrogen production electrolysis tank is in communication with an external hydrogen pipeline.
- the nano-hydrogen water preparation system further includes a third gas-liquid separator, the inlet of the third gas-liquid separator is in communication with the gas outlet of the second hydrogen production electrolyzer, and the third gas-liquid separator The first outlet of the device is in communication with the external hydrogen pipeline.
- the second outlet of the third gas-liquid separator is in communication with the inlet of the raw water tank, and a pipe between the second outlet of the third gas-liquid separator and the inlet of the raw water tank is provided There are water pumps.
- the pipeline between the second outlet of the third gas-liquid separator and the inlet of the raw water tank is also provided with a first solenoid valve, and the first solenoid valve is located between the water pump and the third Between the second outlets of the gas-liquid separator, the third gas-liquid separator is provided with a first high liquid level sensor and a first low liquid level sensor.
- a second low liquid level sensor is provided in the raw water tank.
- the second outlet of the second gas-liquid separator is in communication with an external drainage system.
- a second solenoid valve is provided between the first outlet of the second gas-liquid separator and the second inlet of the gas-liquid mixing pump.
- a first one-way valve is provided between the water inlet connector and the first inlet of the gas-liquid mixing pump.
- first outlet pipe of the first gas-liquid separator is provided with a second one-way valve.
- venturi module is a venturi tube or a venturi mixer.
- the bathing device includes the above-mentioned nano hydrogen water preparation system and bathing container.
- the bathing device is also provided with a hydrogen absorption pipeline and a pipe joint, and the hydrogen absorption pipeline and the hydrogen pipeline of the nano-hydrogen water preparation system operate independently without interference with each other.
- a second high liquid level sensor is further provided in the bathing container, and the liquid level sensor monitors that the water level is higher than the water inlet joint.
- the water inlet connector and the water outlet connector are respectively arranged on two opposite side walls of the bathing container or connected to the water inlet connector and the water outlet connector in the form of water receiving pipes, and the water inlet and outlet pipes are put into the opposite sides of the bathing container.
- the height difference between the highest liquid level in the bath container and the first inlet of the gas-liquid mixing pump is preferably controlled to h ⁇ 50cm.
- the present invention has the following beneficial effects:
- the nano-hydrogen water preparation system combines the dissolved water hydrogen system and the nano-bubble generation system into one to form a nano-hydrogen water system.
- nano-hydrogen water system nano-hydrogen hydrogen-rich water can be formed, which simplifies the system structure. Therefore, the overall cost of the nano-hydrogen water preparation system can be reduced.
- the nano-hydrogen water preparation system can also realize that undissolved hydrogen can be reused without causing waste of resources and further reducing costs.
- Fig. 1 is a schematic diagram of the structure of the nano hydrogen water preparation system of the present invention.
- the bathing device includes a nano-hydrogen water production system and a bathing container 1.
- the bathing container 1 may specifically be a bathtub or a bathing pool or basin that can be used for bathing.
- the bottom of the bathing container 1 may be provided with a drainage port, and the side may be provided with a water inlet.
- the water outlet is used to communicate with the external drainage system, the water inlet is connected with the external water source system through a water inlet pipe, and the bath container 1 is also provided with a second high liquid level sensor, the second high liquid level sensor
- the monitoring water level is equal to or higher than the water inlet connector 21.
- the nano hydrogen water preparation system includes a water inlet connector 21, a water outlet connector 22, a first check valve 31, a gas-liquid mixing pump 23, a first gas-liquid separator 24, a second check valve 34, The hydrogen generating device, the second one-way valve 34, the second gas-liquid separator 25, the second solenoid valve 33, and the Venturi module 26.
- the water inlet connector 21 and the water outlet connector 22 are all set on the bath container 1 and connected to each other.
- the interior of the bath container 1 is connected, wherein the water inlet connector 21 is used for the water in the bath container 1 to enter the nano hydrogen water system, and the water outlet connector 22 is used for the water inlet of the nano hydrogen water system.
- Nano hydrogen water enters the bath container 1, the water inlet connector 21 is in communication with the first inlet of the gas-liquid mixing pump 23, and between the first inlet of the gas-liquid mixing pump 23 and the water inlet connector 21
- the first one-way valve 31 is provided on the pipe between the two, so that the water in the bath container 1 can enter the nano-hydrogen water system through the water inlet connector 21, and the water in the nano-hydrogen water system cannot flow back to the nano-hydrogen water system through the nano-hydrogen water inlet.
- the outlet of the gas-liquid mixing pump 23 is in communication with the inlet of the first gas-liquid separator 24, and the outlet of the gas-liquid mixing pump 23 is connected to the first gas-liquid separator 24.
- the pipe between the inlets is equipped with a water flow switch.
- the first outlet of the first gas-liquid separator 24 communicates with the first inlet of the second gas-liquid separator 25, and the first gas-liquid separator 24 is connected to the first inlet of the second gas-liquid separator.
- the pipeline of the second gas-liquid separator 25 is provided with a second one-way valve 34, the second inlet of the second gas-liquid separator 25 is connected with the outlet of the hydrogen generating device, and the second gas-liquid separator
- the first outlet of 25 is in communication with the second inlet of the gas-liquid mixing pump 23, and there is a pipeline between the first outlet of the second gas-liquid separator 25 and the second inlet of the gas-liquid mixing pump 23
- a second solenoid valve 33 and a third one-way valve 32 are provided.
- the second solenoid valve 33 is a normally open solenoid valve.
- the second outlet of the second gas-liquid separator 25 is connected to the external drainage system through a pipeline.
- the inlet of the Venturi module 26 communicates with the second outlet of the first gas-liquid separator 24 through a first pipe, and the outlet of the Venturi module 26 communicates with the water outlet connector 22 through a second pipe.
- the nano-hydrogen water preparation system combines the dissolved water hydrogen system and the nano-bubble generation system into one to form a nano-hydrogen water system, and fluidly communicates the nano-hydrogen water system with the bath container 1 through a pipeline system, and
- the nano-hydrogen water system can form nano-hydrogen hydrogen-rich water, which simplifies the system structure, so that the overall cost of the nano-hydrogen water preparation system can be reduced.
- the nano-hydrogen water preparation system can also realize that undissolved hydrogen can be reused. Will cause waste of resources and further reduce costs.
- the hydrogen generating device is a first hydrogen production electrolytic cell 27, and the nano-hydrogen water production system further includes a second hydrogen production electrolytic cell 28 ,
- the raw water tank 29 for water storage and the third gas-liquid separator 30, the anode chamber water inlet of the first hydrogen production electrolytic cell 27 and the anode chamber water inlet of the second hydrogen production electrolytic cell 28 are all connected to the The water outlet of the raw water tank 29 is in communication, the inlet of the third gas-liquid separator 30 is in communication with the outlet of the second hydrogen production electrolyzer 28, and the anode chamber water outlet of the first hydrogen production electrolyzer 27 and The water outlets of the anode chamber of the second hydrogen production electrolyzer 28 are all connected with the second water inlet of the raw water tank 29, and the first outlet of the third gas-liquid separator 30 is connected with an external hydrogen pipeline 37.
- the hydrogen produced by the second hydrogen production electrolyzer 28 can be supplied to the user for direct absorption.
- the absorption of hydrogen can make the internal organs more directly use the reduction effect of hydrogen, and improve the internal organs of the human body, especially for human respiratory diseases and cardiovascular diseases. It has an excellent improving effect.
- the nano-hydrogen water preparation system has a nano-hydrogen water preparation function and a hydrogen absorption function, so that users have more diverse choices. More importantly, it can also realize the recycling of undissolved hydrogen and avoid waste of resources.
- the nano-hydrogen water production system of the present invention can connect the electrical components through the control system, and configure the corresponding function keys to start or close the nano-hydrogen water production system.
- the nano-hydrogen water production system can be configured. There are three buttons for "Hydrogen Bath”, “Hydrogen Absorption” and "Stop”.
- Start the nano-hydrogen milk bath function click the "hydrogen bath” button to start the system, the water inlet opens, and the bath container 1 starts to add water; when the second high level sensor detects that the liquid level of bath container 1 is higher than the water inlet connector 21, The normally open solenoid valve is closed for a certain period of time. For example, if it is set to 45 seconds, the gas-liquid mixing pump 23 is started, and the first hydrogen production electrolyzer 27 is also started; at this time, the gas-liquid mixing pump 23 draws in the water in the bath container 1 and passes through the first A one-way valve 31, a gas-liquid mixing pump 23, a first gas-liquid separator 24, and a venturi module 26 flow back to the bath container 1 from the water outlet connector 22.
- the water path is under the action of the venturi module 26, and the gas-liquid mixing pump 23
- the pump chamber can form a pressure of 4 kg to 8 kg; after 45 seconds, the normally open solenoid valve is opened, and the hydrogen generated in the first hydrogen production electrolyzer 27 passes through the second gas-liquid separator 25 and the normally-open solenoid valve and then enters the gas-liquid
- the large-bubble hydrogen is separated from the water under the separation action of the first gas-liquid separator 24.
- the newly generated hydrogen from the first hydrogen production electrolyzer 27 enters the second gas-liquid separator 25 together, and the second gas-liquid separator 25 separates water and hydrogen.
- the hydrogen repeats the previous path, often opening the solenoid valve to return
- the gas-liquid mixing pump 23 is re-mixed into hydrogen-rich water, which continues to circulate, and the water and gas are discharged to the outside drainage system through the pipeline; the hydrogen-rich water enters the venturi module 26 after passing through the first gas-liquid separator 24, and then enters the venturi module 26 Under the combined action of the gas-liquid mixing pump 23, the hydrogen-rich water comes out of the venturi module 26 to form nano-hydrogen hydrogen-rich water, and the water is milky.
- the essence is that the water contains a large number of nano-level hydrogen bubbles, and the water will appear as milk. color. At this point, the system completes a cycle of water and gas paths.
- the system During the set time, the system has been continuously performing cyclic work, and the water in the entire bath container 1 is hydrogen-rich water rich in hydrogen.
- the water passages of the anode chamber of the first hydrogen production electrolysis cell 27 and the second hydrogen production electrolysis cell 28 of the present invention can realize self-circulation, and a part of the water in the anode chamber will be transported to the cathode chamber during the working process. If the water level is lower than the low level, the system stops and warns the user to make up water.
- the system is equipped with leakage safety protection, and people can enter the bath container 1 to take a bath without worry, and the entry of personnel will not affect the work of the system, and the system will not cause personnel accidents.
- the nano-hydrogen milk bath system and the hydrogen absorption system are organically combined. They can be used alone or at the same time.
- the hydrogen content in the skin and blood is increased. Remove harmful free radicals, slow down skin aging, activate cells, expel toxins from the body, promote blood circulation, remove dirt, whiten and clean the skin, and at the same time, the absorbed hydrogen continuously penetrates into all parts of the human body, blood, organs, and cells. Achieve the effect of removing certain harmful free radicals from the human body.
- the second outlet of the third gas-liquid separator 30 is in communication with the inlet of the raw water tank 29, and the second outlet of the third gas-liquid separator 30 is
- a water pump 35 is provided on the pipeline between the inlet of the raw water tank 29 and the second outlet of the third gas-liquid separator 30 and the inlet of the raw water tank 29 is also provided with a first electromagnetic Valve 36
- the first solenoid valve 36 is a normally closed solenoid valve
- the first solenoid valve 36 is located between the water pump 35 and the second outlet of the third gas-liquid separator 30, the third gas-liquid
- the separator 30 is provided with a first high liquid level sensor and a first low liquid level sensor.
- the first solenoid valve 36 When the first high liquid level sensor detects the highest water level, the first solenoid valve 36 is opened, and the water in the third gas-liquid separator 30 flows to the raw water tank 29 under the action of the water pump 35, To reuse water and avoid waste, when the first low level sensor detects a low water level, the water pump 35 and the first solenoid valve 36 are closed.
- a second low liquid level sensor is installed in the raw water tank 29.
- the nano-hydrogen water production system stops and a user replenishment alarm is issued.
- the water in the raw water tank 29 is water with a TDS value below 1, such as Cestbon pure drinking water or deionized water.
- a filter device (such as a filter screen) is provided on the water inlet connector 21 to prevent the system from clogging.
- the height difference between the highest liquid level in the bath container 1 and the first inlet of the gas-liquid mixing pump 23 is preferably controlled to h ⁇ 50cm. It is ensured that the hydrogen in the second gas-liquid separator 25 can enter the gas-liquid mixing pump 23.
- the first gas-liquid separator 24, the second gas-liquid separator 25, and the third gas-liquid separator 30 may all be gas-liquid separation tanks or gas-liquid separation pumps.
- a gas-liquid separator 24 is a gas-liquid separation valve, and the second gas-liquid separator 25 and the third gas-liquid separator 30 are gas-liquid separation tanks.
- the hydrogen generating device may also be a hydrogen storage tank.
- the first hydrogen production electrolysis tank 27 and the second hydrogen production electrolysis tank 28 both include an anode chamber for generating oxygen and a cathode chamber for generating oxygen, and the first hydrogen production electrolysis tank 27 and the second hydrogen production electrolysis tank
- the tank 28 is respectively equipped with a first power source 271 and a second power source 281.
- the anode chamber water circuit can realize self-circulation. Part of the water in the anode chamber will be transported to the cathode chamber during operation.
- the system stops and warns the user to replenish water.
- the oxygen generated in the anode chamber is discharged through the oxygen discharge port.
- the bathing container 1 has its conventional functions, such as surfing, lighting, heating, etc.
- the nano-hydrogen water system will not interfere with the conventional functions of the bathing container 1.
- the Venturi module 26 is a Venturi tube or a Venturi mixer.
- the second outlet of the second gas-liquid separator 25 is in communication with the waste water tank 38 through a pipe.
- the waste water tank 38 is equipped with a third high level sensor, and the waste water tank 38 is also equipped with exhaust gas.
- the pipe 382 and the drain pipe 381 connected to the external drainage system.
- the drain pipe 381 is equipped with a normally closed solenoid valve. When the third liquid level sensor detects a high liquid level, the normally closed solenoid valve opens to make the waste water tank 38 The water is discharged to the external drainage system.
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Abstract
一种纳米氢气水制备系统,包括进水接头(21)、气液混合泵(23)、第一气液分离器(24)、氢气发生装置、第二气液分离器(25)、文丘里模块(26)以及出水接头(22),气液混合泵(23)的第一入口与进水接头(21)连通,气液混合泵(23)的出口与第一气液分离器(24)的入口连通,第一气液分离器(24)的第一出口与第二气液分离器(25)的第一入口连通,氢气发生装置的出口与第二气液分离器(25)的第二入口连通,第二气液分离器(25)的第一出口与气液混合泵(23)的第二入口连通,第二气液分离器(25)具有供其内部的水液排出的第二出口,文丘里模块(26)的入口与第一气液分离器(24)的第二出口连通。该纳米氢气水制备系统简化了系统结构,使成本得以降低,并且还能够重复利用未溶解氢气,避免浪费资源。
Description
本发明涉及氢气浴装置技术领域,尤其涉及一种纳米氢气水制备系统及洗浴装置。
随着氢的作用不断被科学证实,氢养生、氢美容逐渐被普及开来,比如纳米牛奶氢气浴技术也越来越广泛地被人们所知悉。
这种时尚沐浴方式不用加牛奶,而是通过高科技技术,将普通水转换为乳白色的纳米高含氢水。纳米氢气水制备系统的原理就是运用分子对撞,再用超高频磁波切割,使水分子与微气泡接近纳米化,从而制作出大量乳白色的、高浓度的微纳米级富氢水。由于接近纳米化,负离子、水分子因此得以迅速渗透肌肤毛细孔,去除毛孔中的污垢,深度清洁肌肤。高含氢的水分子深入肌肤毛细孔后,增加肌肤及血液中的含氢量,去除有害自由基,减缓皮肤衰老,活化细胞,排出体内毒素,促进血液循环,可起到清除污垢、美白洁肤的作用。
目前,现有的纳米氢气水制备系统包括浸浴容器、溶解氢气水系统以及纳米起泡发生系统,但由于溶解氢气水系统以及纳米起泡发生系统为两个分别与浸浴容器连通的独立系统,导致其构件多并且结构复杂,成本较为高昂,并且未溶解氢气无法重复利用,造成氢气的浪费。
发明内容
为了克服现有技术的不足,本发明的目的之一在于提供一种纳米氢气水制备系统,其简化了系统结构,使成本得以降低,并且还能够重复利用未溶解氢气,避免浪费资源。
本发明的目的之二在于提供一种应用有上述的纳米氢气水制备系统的洗浴装置。
本发明的目的采用如下技术方案实现:
纳米氢气水制备系统,包括进水接头、气液混合泵、第一气液分离器、氢气发生装置、第二气液分离器、文丘里模块以及出水接头,所述进水接头以及出水接头均用于与外部的洗浴容器连通,所述进水接头用于供所述洗浴容器内的水进入所述纳米氢气水制备系统,所述出水接头用于供所述纳米氢气水制备系统内的纳米氢气水进入所述洗浴容器内,所述进水接头与所述气液混合泵的第一入口连通,所述气液混合泵的出口与所述第一气液分离器的入口连通,所述第一气液分离器的第一出口与所述第二气液分离器的第一入口连通,所述氢气发生装置的出口与所述第二气液分离器的第二入口连通,所述第二气液分离器的第一出口与所述气液混合泵的第二入口连通,所述第二气液分离器具有用于供其内部的水液排出的第二出口,所述第一气液分离器的第二出口与所述文丘里模块的入口连通,所述文丘里模块的出口与所述出水接头连通。
进一步地,所述氢气发生装置为第一制氢电解槽,所述纳米氢气水制备系统还包括第二制氢电解槽以及用于储水的原水箱,所述原水箱具有用于加水的第一入水口,所述第一制氢电解槽的阳极室进水口以及所述第二制氢电解槽的阳极室进水口均与所述原水箱的出水口连通,所述第一制氢电解槽的阳极室出水口以及所述第二制氢电解槽的阳极室出水口均与所述原水箱的第二入水口连通,所述第一制氢电解槽的出气口与所述第二气液分离器的第二入口连通,所述第二制氢电解槽的出气口与外部的氢气管道连通。
进一步地,所述纳米氢气水制备系统还包括第三气液分离器,所述第三气液分离器的入口与所述第二制氢电解槽的出气口连通,所述第三气液分离器的 第一出口与外部的氢气管道连通。
进一步地,所述第三气液分离器的第二出口与所述原水箱的入口连通,并且所述第三气液分离器的第二出口与所述原水箱的入口之间的管道上设置有水泵。
进一步地,所述第三气液分离器的第二出口与所述原水箱的入口之间的管道上还设置有第一电磁阀,所述第一电磁阀位于所述水泵和所述第三气液分离器的第二出口之间,所述第三气液分离器内设有第一高液位传感器以及第一低液位传感器。
进一步地,所述原水箱内设有第二低液位传感器。
进一步地,所述第二气液分离器的第二出口与外界的排水系统连通。
进一步地,所述第二气液分离器的第一出口和所述气液混合泵的第二入口之间设置有第二电磁阀。
进一步地,所述进水接头与所述气液混合泵的第一入口之间设置有第一单向阀。
进一步地,所述第一气液分离器的第一出口管道上设置有第二单向阀。
进一步地,所述文丘里模块为文丘里管或文丘里混合器。
洗浴装置,包括上述的纳米氢气水制备系统以及洗浴容器。
进一步地,所述洗浴装置还设置吸取氢气管路及管接头,吸氢管路与纳米氢气水制备系统氢气管路独立运行,互不干涉。
进一步地,所述洗浴容器内还设置有第二高液位传感器,所述液位传感器监测水位高于所述进水接头。
进一步地,所述进水接头和所述出水接头分别设置在洗浴容器的相对两侧壁或者以接水管的形式分别接好进水接头及出水接头,将进出水管放进洗浴容 器相对两侧。
进一步地,启动所述纳米氢气水系统时,所述洗浴容器内的最高液面与所述气液混合泵的第一入口两者的高度差控制h≤50cm为佳。
相比现有技术,本发明的有益效果在于:
该纳米氢气水制备系统通过将溶解水氢气系统和纳米起泡发生系统两者合二为一,形成纳米氢气水系统,通过该纳米氢气水系统即可形成纳米氢气富氢水,简化了系统结构,使得该纳米氢气水制备系统的整体成本得以降低,另外,该纳米氢气水制备系统还能够实现未溶解氢气能够重复利用,不会造成资源浪费,进一步降低成本。
图1为本发明的纳米氢气水制备系统的结构示意图。
图中:1、洗浴容器;21、进水接头;22、出水接头;23、气液混合泵;24、第一气液分离器;25、第二气液分离器;26、文丘里模块;27、第一制氢电解槽;271、第一电源;28、第二制氢电解槽;281、第二电源;29、原水箱;30、第三气液分离器;31、第一单向阀;32、第三单向阀;33、第二电磁阀;34、第二单向阀;35、水泵;36、第一电磁阀;37、氢气管道;38、废水箱;381、排水管;382、排气管。
下面,结合附图以及具体实施方式,对本发明做进一步描述,需要说明的是,在不相冲突的前提下,以下描述的各实施例之间或各技术特征之间可以任意组合形成新的实施例。
参见图1,示出了本发明一较佳实施例的一种洗浴装置,该洗浴装置包括纳 米氢气水制备系统以及洗浴容器1。
作为优选的实施方式,所述洗浴容器1具体可以为浴缸或可用于洗浴的洗浴池或洗浴盆等,该洗浴容器1的底部可以开设有排水口,其侧部可以开设有进水口,所述排水口用于与外界的排水系统连通,所述进水口通过可以进水管与外界的水源系统连通,所述洗浴容器1内还设置有第二高液位传感器,所述第二高液位传感器监测水位等于或高于进水接头21。
继续参见图1,所述纳米氢气水制备系统包括进水接头21、出水接头22、第一单向阀31、气液混合泵23、第一气液分离器24、第二单向阀34、氢气发生装置、第二单向阀34、第二气液分离器25、第二电磁阀33以及文丘里模块26,所述进水接头21以及出水接头22均设置在洗浴容器1上并与所述洗浴容器1的内部连通,其中,所述进水接头21用于供所述洗浴容器1内的水进入所述纳米氢气水系统,所述出水接头22用于供所述纳米氢气水系统的纳米氢气水进入所述洗浴容器1内,所述进水接头21与所述气液混合泵23的第一入口连通,并在气液混合泵23的第一入口与所述进水接头21之间的管道上设置有第一单向阀31,使洗浴容器1内的水能够通过进水接头21进入纳米氢气水系统内,而不能使纳米氢气水系统内的水通过纳米氢气水入口回流至洗浴容器1内,所述气液混合泵23的出口与所述第一气液分离器24的入口连通,并在所述气液混合泵23的出口与所述第一气液分离器24的入口之间的管道上配置水流开关,所述第一气液分离器24的第一出口与第二气液分离器25的第一入口连通,并在连通所述第一气液分离器24与所述第二气液分离器25的管道上设置有第二单向阀34,第二气液分离器25的第二入口与所述氢气发生装置的出口连通,所述第二气液分离器25的第一出口与所述气液混合泵23的第二入口连通,并且在所述第二气液分离器25的第一出口和所述气液混合泵23的第二入口之间的 管道设置有第二电磁阀33以及第三单向阀32,该第二电磁阀33为常开电磁阀,所述第二气液分离器25的第二出口通过管道与外界的排水系统连通,所述文丘里模块26的入口通过第一管道与所述第一气液分离器24的第二出口连通,所述文丘里模块26的出口通过第二管道与出水接头22连通。
该纳米氢气水制备系统通过将溶解水氢气系统和纳米起泡发生系统两者合二为一,形成纳米氢气水系统,并使纳米氢气水系统与洗浴容器1通过管路系统流体连通,通过该纳米氢气水系统即可形成纳米氢气富氢水,简化了系统结构,使得该纳米氢气水制备系统的整体成本得以降低,另外,该纳米氢气水制备系统还能够实现未溶解氢气能够重复利用,不会造成资源浪费,进一步降低成本。
为使该纳米氢气水制备系统的功能更丰富多样,作为优选的实施方式,所述氢气发生装置为第一制氢电解槽27,所述纳米氢气水制备系统还包括第二制氢电解槽28、用于储水的原水箱29以及第三气液分离器30,所述第一制氢电解槽27的阳极室进水口以及所述第二制氢电解槽28的阳极室进水口均与所述原水箱29的出水口连通,所述第三气液分离器30的入口与所述第二制氢电解槽28的出气口连通,所述第一制氢电解槽27的阳极室出水口以及所述第二制氢电解槽28的阳极室出水口均与所述原水箱29的第二入水口连通,所述第三气液分离器30的第一出口与外部的氢气管道37连通。第二制氢电解槽28产生的氢气可以供给用户直接吸取,吸氢能够让人体内脏可以更直接地利用氢的还原作用,使人体内脏器官得到改善,特别是对人体呼吸系统疾病、心血管疾病等有优良改善作用。
综上,该纳米氢气水制备系统具备纳米氢气水制备功能以及吸氢功能,使用户的选择更丰富多样,更为重要的是,还能够实现未溶解氢气的循环利用, 避免造成资源浪费。
另外,本发明的纳米氢气水制备系统能够通过控制系统将各电气部件联系在一起,并配置对应的功能按键而启动或关闭该纳米氢气水制备系统,比如,该纳米氢气水制备系统可配置“氢浴”、“吸氢”以及“停止”三个按键。
具体实施过程如下:
纳米氢气牛奶浴功能的启动:点击“氢浴”按键,启动系统,进水口打开,洗浴容器1开始加水;当第二高液位传感器监测到洗浴容器1液位高于进水接头21时,常开电磁阀关闭一定时间,比如设定45秒,气液混合泵23启动,第一制氢电解槽27也启动;此时气液混合泵23将洗浴容器1里的水抽进来,经过第一单向阀31、气液混合泵23、第一气液分离器24、文丘里模块26,从出水接头22流回洗浴容器1,水路在文丘里模块26的作用下,气液混合泵23的泵腔可形成4公斤至8公斤的压力;45秒后,常开电磁阀打开,第一制氢电解槽27生成的氢气经过第二气液分离器25、常开电磁阀后进入气液混合泵23,在气液混合泵23的高速旋转切割下,以及气液混合泵23泵腔形成的4至8公斤压力作用下,氢气迅速溶解于水中,形成富含氢气的富氢水,富氢水中同时有未溶解于水的氢气,其会聚集成大气泡,在经过第一气液分离器24时,在第一气液分离器24的分离作用下,大气泡氢气从水中分离出来,与第一制氢电解槽27新生成的氢气一起进入第二气液分离器25,第二气液分离器25实现将水气与氢气分离,这些氢气再重复之前的路径,经常开电磁阀回到气液混合泵23重新混合成富氢水,一直循环进行,而水气通过管道排至外界的排水系统;富氢水经过第一气液分离器24之后进入文丘里模块26,在文丘里模块26及气液混合泵23的组合作用下,富氢水从文丘里模块26出来后形成纳米氢气富氢水,并且水呈牛奶色,实质是水中含有大量的纳米级别氢气泡,水才会呈现牛奶色。 至此,系统完成水路及气路的一个循环,在设定的时间内,系统一直不断进行循环工作,并且实现整个洗浴容器1的水为富含氢气的富氢水。系统运行时间越长,富氢水越浓,具体可根据实际需要设定运行时间。
吸氢功能的启动:点击“吸氢”按键,吸氢系统启动,第二制氢电解槽28启动,氢气从第二制氢电解槽28的阴极室排出,经过第三气液分离器30的分离作用后,从吸氢管道排出,供用户使用,吸氢时间具体可根据实际需要设定运行时间。
可以理解的是,本发明的第一制氢电解槽27以及第二制氢电解槽28的阳极室水路可以实现自循环,阳极室的一部分水会在工作过程中搬运至阴极室,当阳极室水位低于低液位,系统停止并警告提醒用户补水。
系统工作过程中,系统设置有漏电安全保护,人可放心进入洗浴容器1泡澡,人员进入不会影响系统工作,系统也不会造成人员事故。纳米氢气牛奶浴系统与吸氢系统两者有机结合,可以单独使用也可同时使用,系统循环工作过程中,高含氢的水分子深入肌肤毛细孔后,增加肌肤及血液中的含氢量,去除有害自由基,减缓皮肤衰老,活化细胞,排出体内毒素,促进血液循环,起到清除污垢、美白洁肤的作用,同时,吸取的氢气不断渗透到人体各个部位,血液、器官、细胞,可达到清除一定的人体有害自由基的作用。
作为优选的实施方式,为能够循环利用水资源,所述第三气液分离器30的第二出口与所述原水箱29的入口连通,并且所述第三气液分离器30的第二出口与所述原水箱29的入口之间的管道上设置有水泵35,所述第三气液分离器30的第二出口与所述原水箱29的入口之间的管道上还设置有第一电磁阀36,该第一电磁阀36为常闭电磁阀,所述第一电磁阀36位于所述水泵35和所述第三气液分离器30的第二出口之间,所述第三气液分离器30内设有第一高液位 传感器以及第一低液位传感器。当第一高液位传感器检测到最高水位时,所述第一电磁阀36打开,所述第三气液分离器30内的水液在所述水泵35的作用下流至所述原水箱29,以重复利用水液,避免造成浪费,当所述第一低液位传感器检测到低水位时,所述水泵35以及第一电磁阀36关闭。
作为优选的实施方式,原水箱29内安装有第二低液位传感器,当原水箱29内的第二低液位传感器检测到低水位时,该纳米氢气水制备系统停止并给发出用户补水警报,值得注意的是,原水箱29内水液为TDS值为1以下的水,比如怡宝饮用纯净水或者去离子水。作为优选的实施方式,所述进水接头21上设置有过滤装置(比如过滤网),防止系统堵塞。作为优选的实施方式,启动所述纳米氢气水系统时,所述洗浴容器1内的最高液面与所述气液混合泵23的第一入口两者的高度差控制h≤50cm为佳,以保证第二气液分离器25的氢气能够进入到气液混合泵23中。
作为优选的实施方式,所述第一气液分离器24、第二气液分离器25以及第三气液分离器30均可以为气液分离罐或气液分离泵,在本实施当中,第一气液分离器24为气液分离阀,第二气液分离器25以及第三气液分离器30为气液分离罐。
作为优选的实施方式,所述氢气发生装置还可以为氢气储罐。
具体地,第一制氢电解槽27以及第二制氢电解槽28均包括用于产生氧气的阳极室以及用于产生氧气的阴极室,并且第一制氢电解槽27和第二制氢电解槽28分别配置有第一电源271以及第二电源281,阳极室水路可以实现自循环,阳极室的水分会在工作过程中一部分搬运到阴极室,当原水箱29水位低于低液位时,系统停止并警告提醒用户补水。阳极室产生的氧气通过氧气排放口排出。
洗浴容器1具备其常规功能,比如冲浪、灯光、加热等功能,纳米氢气水 系统与洗浴容器1常规功能不会干扰。
作为优选的实施方式,所述文丘里模块26为文丘里管或文丘里混合器。
作为优选的实施方式,所述第二气液分离器25的第二出口通过管道与废水箱38连通,废水箱38内配置有第三高液位传感器,该废水箱38上还配置有排气管382以及与外部的排水系统连通的排水管381,该排水管381上配置有常闭电磁阀,当第三液位传感器检测到高液位时,常闭电磁阀打开而使废水箱38内的水排至外部的排水系统。
上述实施方式仅为本发明的优选实施方式,不能以此来限定本发明保护的范围,本领域的技术人员在本发明的基础上所做的任何非实质性的变化及替换均属于本发明所要求保护的范围。
Claims (12)
- 纳米氢气水制备系统,其特征在于,包括进水接头、气液混合泵、第一气液分离器、氢气发生装置、第二气液分离器、文丘里模块以及出水接头,所述进水接头用于供外部的水液进入所述纳米氢气水制备系统,所述出水接头用于供所述纳米氢气水制备系统内的纳米氢气水流出,所述进水接头与所述气液混合泵的第一入口连通,所述气液混合泵的出口与所述第一气液分离器的入口连通,所述第一气液分离器的第一出口与所述第二气液分离器的第一入口连通,所述氢气发生装置的出口与所述第二气液分离器的第二入口连通,所述第二气液分离器的第一出口与所述气液混合泵的第二入口连通,所述第二气液分离器还具有用于供其内部的水液排出的第二出口,所述第一气液分离器的第二出口与所述文丘里模块的入口连通,所述文丘里模块的出口与所述出水接头连通。
- 如权利要求1所述的纳米氢气水制备系统,其特征在于,所述氢气发生装置为第一制氢电解槽,所述纳米氢气水制备系统还包括第二制氢电解槽以及用于储水的原水箱,所述原水箱开设有用于加水的第一入水口,所述第一制氢电解槽的阳极室进水口以及所述第二制氢电解槽的阳极室进水口均与所述原水箱的出水口连通,所述第一制氢电解槽的阳极室出水口以及所述第二制氢电解槽的阳极室出水口均与所述原水箱的第二入水口连通,所述第一制氢电解槽的出气口与所述第二气液分离器的第二入口连通,所述第二制氢电解槽的出气口与外部的氢气管道连通。
- 如权利要求2所述的纳米氢气水制备系统,其特征在于,所述纳米氢气水制备系统还包括第三气液分离器,所述第三气液分离器的入口与所述第二制氢电解槽的出气口连通,所述第三气液分离器的第一出口与外部的氢气管道连通。
- 如权利要求3所述的纳米氢气水制备系统,其特征在于,所述第三气液分 离器的第二出口与所述原水箱的入口连通,并且所述第三气液分离器的第二出口与所述原水箱的入口之间的管道上设置有水泵。
- 如权利要求4所述的纳米氢气水制备系统,其特征在于,所述第三气液分离器的第二出口与所述原水箱的入口之间的管道上还设置有第一电磁阀,所述第一电磁阀位于所述水泵和所述第三气液分离器的第二出口之间,所述第三气液分离器内设有第一高液位传感器以及第一低液位传感器。
- 如权利要求2所述的纳米氢气水制备系统,其特征在于,所述原水箱内设有第二低液位传感器。
- 如权利要求1所述的纳米氢气水制备系统,其特征在于,所述第二气液分离器的第二出口与外界的排水系统连通。
- 如权利要求1所述的纳米氢气水制备系统,其特征在于,所述第二气液分离器的第一出口和所述气液混合泵的第二入口之间设置有第二电磁阀。
- 如权利要求1所述的纳米氢气水制备系统,其特征在于,所述进水接头与所述气液混合泵的第一入口之间设置有第一单向阀。
- 如权利要求1所述的纳米氢气水制备系统,其特征在于,所述第一气液分离器的第一出口管道上设置有第二单向阀。
- 如权利要求1所述的纳米氢气水制备系统,其特征在于,所述文丘里模块为文丘里管或文丘里混合器。
- 洗浴装置,其特征在于,包括权利要求1-11中任一项所述的纳米氢气水制备系统以及洗浴容器,所述进水接头以及出水接头均与所述洗浴容器连通。
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Application Number | Priority Date | Filing Date | Title |
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