SUMMERY OF THE UTILITY MODEL
In order to overcome the not enough of prior art, the utility model provides a hydrogen physiotherapy cabin can carry out the physiotherapy through the gas mode that has hydrogen to providing the user mixture, need not to drink hydrogen water in a large number, has avoided the not good problem of hydrogen-rich water compliance, and the physiotherapy mode is simple, is applicable to most people and uses, and can monitor hydrogen concentration, has guaranteed the safety in hydrogen physiotherapy cabin, has improved user experience degree.
In order to solve the above problem, the utility model discloses a technical scheme do: a hydrogen physiotherapy cabin comprises a physiotherapy cabin body and a control cabin arranged on the physiotherapy cabin body, wherein the control cabin comprises a hydrogen production unit, a circulation unit, a power supply unit, a monitoring unit and a control unit; the physiotherapy cabin body is used for accommodating a user who performs hydrogen physiotherapy; the power supply unit is respectively connected with the hydrogen production unit, the circulation unit, the monitoring unit and the control unit, and the power supply unit supplies power to the hydrogen physical therapy cabin: the circulation unit is respectively connected with the hydrogen production unit and the control unit, hydrogen produced by the hydrogen production unit and air are mixed and input into the physical therapy cabin body through the circulation unit, and water is supplied to the hydrogen production unit through the circulation unit; the monitoring unit is arranged in the physical therapy cabin body, and the hydrogen concentration in the physical therapy cabin body is monitored through the monitoring unit; the control unit is respectively connected with the monitoring unit and the hydrogen production unit, the monitoring unit is used for acquiring the hydrogen concentration in the physical therapy cabin, and when the hydrogen concentration is greater than a first preset value or less than a second preset value, an instruction is sent to the hydrogen production unit to adjust the hydrogen production amount of the hydrogen production unit.
Furthermore, the control cabin also comprises a heat dissipation unit, the heat dissipation unit is connected with the control unit, the heat dissipation unit comprises at least one circulating heat dissipation fan, and heat in the physiotherapy cabin body is discharged through the circulating heat dissipation fan.
Further, the physiotherapy cabin body comprises a physiotherapy cabin cover and a physiotherapy bed, one end of the physiotherapy cabin cover is rotatably connected with the physiotherapy cabin body, and the physiotherapy cabin cover is buckled on the physiotherapy bed to form a space for accommodating a user.
Further, the monitoring unit comprises a hydrogen monitoring probe, the hydrogen monitoring probe is arranged on one side of the physiotherapy cabin cover opposite to the physiotherapy bed, and the monitoring unit acquires the hydrogen concentration in the space through the hydrogen monitoring probe.
Further, the hydrogen physiotherapy cabin still includes at least one atmosphere regulation lamp, the atmosphere regulation lamp sets up physiotherapy cabin cover orientation physiotherapy bed one side, with the control unit is connected, the control unit passes through the atmosphere regulation lamp is adjusted the atmosphere in the space.
Further, the circulation unit includes an air outlet provided at a side of the physiotherapy cabin cover and the physiotherapy couch opposite to each other, and the circulation unit inputs a mixed gas generated by mixing hydrogen gas and air into the space through the air outlet.
Furthermore, the circulation unit also comprises a gas circuit circulation module, the gas circuit circulation module comprises a gas circuit pipeline connected with the gas outlet, and the gas circuit circulation module is used for mixing the hydrogen generated by the hydrogen production unit with air and then inputting the mixture into the space through the gas circuit pipeline.
Furthermore, the circulation unit also comprises a waterway circulation module and a water tank, wherein the waterway circulation module is respectively connected with the hydrogen production unit and the water tank, and the waterway circulation unit is used for inputting water in the water tank into the hydrogen production unit and discharging oxygen generated by the hydrogen production unit into the water tank to be discharged out of the hydrogen physical therapy cabin.
Further, the hydrogen production unit comprises at least one group of SPE solid electrolytic tanks, and hydrogen is produced through the SPE solid electrolytic tanks.
Furthermore, the hydrogen physiotherapy cabin still includes input/output unit, input/output unit with the control unit is connected, the control unit passes through input/output unit shows the operating information in hydrogen physiotherapy cabin to pass through input/output unit receives the instruction of input, according to instruction control the operating condition in hydrogen physiotherapy cabin.
Compared with the prior art, the beneficial effects of the utility model reside in that: the utility model discloses it is internal to arrange the user in the physiotherapy cabin, provide hydrogen to the user through hydrogen manufacturing unit to utilize monitoring unit and the monitoring of the control unit and control hydrogen physiotherapy hydrogen concentration in the cabin, the utility model discloses can have the gaseous mode of hydrogen to mix to the user to carry out the physiotherapy, need not a large amount of hydrogen water of drinking, avoided the not good problem of hydrogen-rich water compliance, the physiotherapy mode is simple, is applicable to most people and uses, and can monitor hydrogen concentration, has guaranteed the safety in hydrogen physiotherapy cabin, has improved user experience degree.
Detailed Description
The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.
Referring to fig. 1-3, fig. 1 is a side view of an embodiment of the hydrogen physiotherapy cabin of the present invention; FIG. 2 is a structural diagram of an embodiment of the hydrogen physiotherapy cabin of the present invention; fig. 3 is a structural diagram of an embodiment of a control cabin of the hydrogen physiotherapy cabin of the utility model. The hydrogen physical therapy cabin of the utility model is explained in detail with the attached drawings 1-3.
Because hydrogen is the smallest molecule in the nature, the penetrating power is extremely strong, and the whole body physical therapy can be carried out through human skin, blood vessels and even blood brain barriers. Therefore, the user can carry out physical therapy in the hydrogen physical therapy cabin without any undressing precursor, and the hydrogen physical therapy cabin is convenient to use and has an excellent effect.
In this embodiment, the hydrogen physiotherapy cabin includes: the physiotherapy cabin body and the control cabin 3 arranged on the physiotherapy cabin body, wherein the control cabin 3 comprises a hydrogen production unit 36, a circulation unit 37, a power supply unit 31, a monitoring unit 35 and a control unit 32; the physiotherapy cabin body is used for accommodating a user who performs hydrogen physiotherapy; the power supply unit 31 is respectively connected with the hydrogen production unit 36, the circulation unit 37, the monitoring unit 35 and the control unit 32, and realizes power supply to the hydrogen physical therapy cabin through the power supply unit 31: the circulating unit 37 is respectively connected with the hydrogen production unit 36 and the control unit 32, hydrogen produced by the hydrogen production unit 36 is mixed with air and input into the physical therapy cabin body through the circulating unit 37, and water is supplied to the hydrogen production unit 36 through the circulating unit 37; the monitoring unit 35 is arranged in the physical therapy cabin body, and the hydrogen concentration in the physical therapy cabin body is monitored through the monitoring unit 35; the control unit 32 is connected with the monitoring unit 35 and the hydrogen production unit 36 respectively, acquires the hydrogen concentration in the physical therapy cabin through the monitoring unit 35, and sends an instruction to the hydrogen production unit 36 to adjust the hydrogen production amount of the hydrogen production unit 36 when the hydrogen concentration is greater than a first preset value or less than a second preset value.
In this embodiment, the control cabin 3 is disposed at the bottom of the physiotherapy cabin body, and the control cabin 3 controls the hydrogen concentration in the physiotherapy cabin body and adjusts the working state of the hydrogen physiotherapy cabin.
In this embodiment, the control unit 32 may be a single chip, a chip, an Intel processor, or other devices capable of adjusting the hydrogen production rate of the hydrogen production unit 36 according to the hydrogen concentration, and is not limited herein.
In the present embodiment, the power supply unit 31 is connected to a household 220V power supply, and converts the 220V high voltage into 12V, 9V and other low voltage direct current, so as to supply power to the hydrogen production unit 36, the circulation unit 37, the monitoring unit 35 and the control unit 32.
The explosion limit of hydrogen is about 4.2-74.2%, and research shows that the hydrogen concentration of about 2% has therapeutic effect on more than 300 chronic diseases.
In order to ensure the safe use of the hydrogen physiotherapy cabin and achieve the best treatment effect, the first preset value is 3%, the second preset value is 2%, and when the hydrogen concentration in the physiotherapy cabin is not between the first preset value and the second preset value, the hydrogen generation amount of the hydrogen production unit 36 is adjusted to enable the hydrogen concentration to be between the first preset value and the second preset value.
In other embodiments, the first preset value and the second preset value may also be other values around 2%, and only the treatment effect can be achieved and the use safety of the hydrogen physiotherapy cabin is ensured, which is not limited herein.
In this embodiment, the control cabin 3 includes a heat dissipation unit 34, the heat dissipation unit 34 is connected to the control unit 32, and the heat dissipation unit 34 includes at least one circulation heat dissipation fan, and the circulation heat dissipation fan facilitates heat exchange between air inside the physiotherapy cabin and the outside to discharge heat inside the physiotherapy cabin.
In other embodiments, the heat dissipation unit 34 may also be an air conditioner, which is connected to a space inside the physiotherapy cabin where the user is located, and by which the temperature of the space is adjusted.
In this embodiment, the physiotherapy cabin body includes physiotherapy cabin cover 1, physiotherapy bed 2, physiotherapy cabin cover 1 one end with physiotherapy cabin body swivelling joint, and 1 lock of physiotherapy cabin cover is in form the space of holding the user on the physiotherapy bed 2.
In this embodiment, the physiotherapy cabin cover 1 and the physiotherapy couch 2 can be connected by clamping, screwing, coupling, or other methods, and only the physiotherapy cabin cover 1 needs to be rotated relative to the physiotherapy couch 2, which is not limited herein.
The physiotherapy cabin cover 1 extends towards the direction far away from the physiotherapy couch 2 to form a space for accommodating a user, and a window is further arranged on the physiotherapy cabin cover 1 and arranged on the side surface of the physiotherapy cabin cover 1.
In this embodiment, the monitoring unit 35 includes a hydrogen monitoring probe 351, the hydrogen monitoring probe 351 is disposed at a side of the physiotherapy cabin cover 1 and the physiotherapy couch 2 opposite to each other, and the monitoring unit 35 acquires the hydrogen concentration in the space through the hydrogen monitoring probe 351.
In a specific embodiment, the hydrogen monitoring probes 351 are arranged in the middle of the physiotherapy cabin cover 1 and on two sides of the area of the physiotherapy couch 2 covered by the physiotherapy cabin cover 1, and the hydrogen monitoring probes 351 monitor the hydrogen concentration in the space formed by buckling the physiotherapy cabin cover 1 and the physiotherapy couch 2 after the physiotherapy cabin cover 1 is buckled on the physiotherapy couch 2, and send the hydrogen concentration information to the control unit 32.
In this embodiment, the hydrogen physiotherapy cabin still includes at least one atmosphere regulation lamp, and the atmosphere regulation lamp sets up in physiotherapy cabin cover 1 towards physiotherapy bed 2 one side, is connected with the control unit 32, and the control unit 32 adjusts at least one in order to adjust the atmosphere in the space that physiotherapy cabin cover 1 and physiotherapy bed 2 lock formed through the atmosphere regulation lamp in the atmosphere regulation lamp luminance, colour and frequency.
In a specific embodiment, the atmosphere control lamps are plural and arranged in a row on the side of the physiotherapy couch 2 facing the physiotherapy couch cover 1.
In this embodiment, the circulation unit 37 includes an air outlet provided at a side of the physiotherapy cabin cover 1 and the physiotherapy couch 2 opposite to each other, and the circulation unit 37 introduces a mixed gas generated by mixing hydrogen gas and air into the space through the air outlet.
In a specific embodiment, the air outlets are arranged at two sides of the hydrogen monitoring probe 351 on the physiotherapy cabin cover 1, and the air outlets on the physiotherapy couch 2 are also arranged at two sides of the hydrogen monitoring probe 351 and are arranged at two sides of the physiotherapy couch 2 together with the hydrogen monitoring probe 351.
In this embodiment, circulation unit 37 still includes gas circuit circulation module 372, and gas circuit circulation module 372 includes the gas circuit pipeline of being connected with the gas outlet, and the gas circuit pipeline sets up in physiotherapy bed 2 and physiotherapy cabin cover 1, and gas circuit circulation module 372 is arranged in the space that forms through gas circuit pipeline input physiotherapy cabin cover 1 and the lock of physiotherapy bed 2 after hydrogen that hydrogen manufacturing unit 36 produced and air mix to provide the hydrogen of safe concentration scope to the user.
In this embodiment, the circulating unit 37 further includes a water path circulating module 371 and a water tank, the water path circulating module 371 is respectively connected to the hydrogen producing unit 36 and the water tank, and the water path circulating unit 37 is configured to input water in the water tank into the hydrogen producing unit 36, and discharge oxygen generated by the hydrogen producing unit 36 into the water tank to discharge the hydrogen physical therapy cabin.
Wherein, waterway circulation module 371 includes waterway pipeline and circulating water pump, and waterway pipeline is connected with water tank, hydrogen manufacturing unit 36 respectively, and waterway circulation module 371 control circulating water pump to go into hydrogen manufacturing unit 36 with the water pump in the water tank to after hydrogen manufacturing unit 36 electrolysis aquatic product produced hydrogen, discharge into the water tank with discharge hydrogen physiotherapy cabin through the waterway pipeline with accessory substance oxygen.
In the above embodiment, the gas circuit circulation module 372 also includes an air pump, and the hydrogen gas and the air are mixed by the air pump, and the mixed gas is pumped into the gas circuit pipeline to be supplied to the user.
In this embodiment, hydrogen-producing unit 36 includes at least one bank of SPE solid state electrolytic cells through which hydrogen-producing unit 36 electrolyzes water to produce hydrogen. The SPE solid electrolytic tank adopts a pure water electrolysis mode, and compared with the traditional alkaline electrolyte electrolysis, the SPE solid electrolytic tank has no corrosion and pollution. Meanwhile, the traditional alkaline electrolyte electrolysis is generated by mixing hydrogen and oxygen, and the SPE solid electrolytic cell can realize the separation and discharge of hydrogen and oxygen, so that the process is safer.
In other embodiments, the hydrogen production unit 36 may also be other solid-state electrolytic cells in the prior art, which only needs to be able to separate and discharge hydrogen and oxygen, and adjust the hydrogen concentration by adjusting the hydrogen generation rate of the electrolyzed water according to the instruction of the control unit 32, which is not limited herein.
In this embodiment, the hydrogen physiotherapy cabin further includes an input/output unit 33, the input/output unit 33 is connected to the control unit 32, and the control unit 32 displays the working information of the hydrogen physiotherapy cabin through the input/output unit 33, receives an input instruction through the input/output unit 33, and controls the working state of the hydrogen physiotherapy cabin according to the instruction.
In the present embodiment, the user can input instructions such as timing, adjusting the atmosphere lamp 4, changing the operation mode, and the like to the control unit 32 through the input-output unit 33. Meanwhile, the input and output unit 33 can also display information such as the working state of the hydrogen physical therapy cabin, the hydrogen concentration of the cabin body, the physical therapy time and the like.
In a specific embodiment, the input/output unit 33 is a control panel, the control panel displays the working state of the hydrogen physiotherapy cabin, the user selects different working modes through the control panel, the control panel inputs corresponding instructions to the control unit 32 according to the selection of the user, and the control unit 32 adjusts the working modes of the hydrogen physiotherapy cabin according to the instructions.
In this embodiment, the monitoring unit 35 further includes a water level monitoring probe, the monitoring probe obtains the water level in the water tank through the water level monitoring probe, and feeds back a water level signal to the control unit 32, and the control unit 32 displays the water level of the water tank through the input/output unit 33 to prompt the water level condition.
Has the advantages that: the utility model discloses it is internal to arrange the user in the physiotherapy cabin, provide hydrogen to the user through hydrogen manufacturing unit to utilize monitoring unit and the monitoring of the control unit and control hydrogen physiotherapy hydrogen concentration in the cabin, the utility model discloses can have the gaseous mode of hydrogen to mix to the user to carry out the physiotherapy, need not a large amount of hydrogen water of drinking, avoided the not good problem of hydrogen-rich water compliance, the physiotherapy mode is simple, is applicable to most people and uses, and can monitor hydrogen concentration, has guaranteed the safety in hydrogen physiotherapy cabin, has improved user experience degree.
In the several embodiments provided in the present disclosure, it should be understood that the disclosed system, apparatus, and method may be implemented in other manners. For example, the above-described apparatus embodiments are merely illustrative, and for example, the modules or partitions may be merely logical partitions, and may be implemented in other ways, e.g., multiple modules or components may be combined or integrated into another system, or some features may be omitted, or not implemented. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be through some interfaces, devices or indirect coupling or communication connection, and may be in an electrical, mechanical or other form.
The components described as separate parts may or may not be physically separate, and the components shown may or may not be physical, that is, may be located in one place, or may be distributed on a plurality of networks. Some or all of them can be selected according to actual needs to achieve the purpose of the embodiment.
The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.