CN112665067A

CN112665067A - Graphite alkene far infrared physiotherapy air purifier

Info

Publication number: CN112665067A
Application number: CN202110066467.6A
Authority: CN
Inventors: 张永峰; 顾奕
Original assignee: Zhongke Haiyun Medical Technology Wuxi Co ltd
Current assignee: Zhongke Haiyun Medical Technology Wuxi Co ltd
Priority date: 2021-01-19
Filing date: 2021-01-19
Publication date: 2021-04-16

Abstract

The invention relates to a graphene far infrared physiotherapy air purifier which comprises a shell, a framework, a heating module, an ultrasonic module, a sensor module, a cylindrical high-efficiency filter screen, a water tank and a power connector, wherein the shell is provided with a heating surface; the shell comprises a front shell, a rear door, a base and an upper shell; the operation panel is arranged on the upper shell; the sensor module comprises a temperature sensor, a humidity sensor, a PM2.5 sensor, a VOC sensor and a negative oxygen ion concentration sensor; the framework is provided with a fan, an air duct, a silent water pump and a water pipe; the water tank is connected with the mute water pump through a water pipe, the mute water pump is connected with the ultrasonic module through a water pipe, and the ultrasonic module is connected with the heating module through an air duct; the ultrasonic module comprises an ultrasonic atomizer and a small fan; the heating module comprises a graphene heating sheet, polyimide fiber cloth and toughened glass. According to the invention, far infrared waves generated by the graphene heating sheet are utilized to irradiate water molecules, negative oxygen ions are generated, VOC molecules in air are adsorbed, and the far infrared waves are utilized for physical therapy.

Description

Graphite alkene far infrared physiotherapy air purifier

Technical Field

The invention relates to an air purifier, in particular to a graphene far infrared physiotherapy air purifier.

Background

The air purifier is a product capable of adsorbing, decomposing or converting various air pollutants and effectively improving the air cleanliness. The method has application in the fields of home, medical treatment and industry, the field of home is divided into a system type fresh air system (classified by two characters of heat exchange and no heat exchange) and a single machine, and the method mainly solves the problem of air pollution in rooms, underground spaces and vehicles caused by decoration or other reasons. Because of the persistent and uncertain nature of the release of airborne pollutants in relatively confined spaces, the use of air purifiers to purify indoor air is one of the internationally recognized methods of improving indoor air quality.

Air purifiers on the market, its principle has a variety, include: firstly, filtering materials and active carbon are adopted to filter, adsorb and remove impurities such as dust, VOC and the like in the air; secondly, a negative oxygen ion generator is adopted to ionize air by high voltage to generate negative oxygen ions, and the negative oxygen ions with charges are combined with micro particles and VOC in the air and then adsorbed on a plate with positive charges to achieve the aim of purifying the air.

Air purification of the above principle has some corresponding disadvantages: firstly, the air purifier adopting a filtering form can filter and adsorb certain dust and VOC molecules, but is influenced by a filtering material for filtering smaller dust; secondly, the negative oxygen ions are generated by high voltage electricity, and simultaneously, ozone is generated, and the ozone is harmful to human bodies after reaching a certain concentration.

A conventional air purifier, such as an automatic detection type air purifier disclosed in chinese patent CN112066485A, includes a purifier housing, in which an air purifying chamber is disposed; the two opposite sides of the purifier shell are respectively provided with an air inlet and an air outlet, and the air inlet and the air outlet are communicated with the air purification cavity; the filter device is arranged in an air purification cavity of the purifier shell and comprises a filter pipeline and a titanium oxide cluster layer, wherein the filter pipeline is filled with an air filter material, and the titanium oxide cluster layer is coated on the surface of the filter pipeline and the surface of the inner wall of the filter pipeline; the air quality monitoring sensing chip is arranged between the air inlet and the filtering device. This utility model is conventional air purifier structure, contains air intake, air outlet and purifies the chamber, and filterable molecular size receives filtering material's influence.

For physical therapy, a plurality of infrared ray physical therapy instruments are available in the market, and the purpose of physical therapy is achieved by irradiating characteristic parts of a human body with bulbs capable of emitting infrared rays, such as a philips infrared ray therapeutic instrument, but few physical therapy instruments which generate far infrared waves by utilizing graphene are available.

A commonly used infrared therapeutic apparatus, such as an infrared therapeutic apparatus disclosed in chinese patent CN110732090A, which comprises an infrared emitter, an upper branch pipe, a lower branch pipe and a base, which are connected at one time, wherein an adjusting shaft is arranged between the infrared emitter and the upper branch pipe, a joint shaft upper shell and a joint shaft lower shell which are arranged between the upper branch pipe and the lower branch pipe in a mutually rotating and matching manner, and a rotating shaft core. The utility model is a common infrared treatment device which can conveniently adjust the angle and the position, but the infrared lamp used by the utility model is a visible infrared lamp, the radiation frequency is high, the permeability is strong, and the infrared wave peak value is 1300 nm.

Therefore, how to design a physiotherapy air purifier which can absorb smaller molecular particle impurities, does not use high-voltage electricity to generate negative oxygen ions and does not use an infrared lamp is a very urgent matter to be solved, and has very important significance.

Disclosure of Invention

In view of this, the present application aims at providing a graphite alkene far infrared physiotherapy air purifier.

In order to achieve the above object, the present application provides the following technical solutions.

A graphene far infrared physiotherapy air purifier comprises a shell, a framework, a heating module, an ultrasonic module, a sensor module, a cylindrical efficient filter screen, a water tank and a power connector;

the framework is vertically arranged and provided with an upright post and a transverse baffle, and the framework is divided into an upper layer and a lower layer by the transverse baffle;

the heating module is arranged on the upper layer of the front end of the framework; the ultrasonic module and the sensor module are arranged on the upper layer of the rear end of the framework;

the water tank is arranged on the lower layer of the front end of the framework; the cylindrical high-efficiency filter screen is arranged at the lower layer of the rear end of the framework;

the ultrasonic wave module is connected with the heating module and the water tank.

The power connector is connected with the framework, the heating module, the ultrasonic module, the sensor module, the cylindrical efficient filter screen and the water tank.

Preferably, a water tank level sensor is arranged in the water tank, and a water level alarm is connected with the water tank level sensor;

preferably, an ultraviolet germicidal lamp is arranged in the water tank.

Preferably, the sensor module comprises a temperature sensor, a humidity sensor, a PM2.5 sensor, a VOC sensor and a negative oxygen ion concentration sensor.

Preferably, the framework is provided with a fan, an air duct, a silent water pump and a water pipe.

Preferably, the water tank leads to pipe to be connected with the silence water pump, and the silence water pump leads to pipe to be connected with the ultrasonic wave module, and the ultrasonic wave module passes through the wind channel to be connected with the module that generates heat.

Preferably, the ultrasonic wave module includes ultrasonic atomization ware, little fan and casing, and the ultrasonic atomization ware sets up the bottom in the casing, and little fan setting is inside the casing, is provided with the atomized water export on the casing, and the input of ultrasonic atomization ware links to each other with the water pipe, and the output of ultrasonic atomization ware links to each other with little fan, atomized water export, the atomized water export is connected with the wind channel.

Preferably, the heat generating module comprises a heat generating component and a housing; the heating assembly is arranged in the housing and comprises a graphene heating sheet, polyimide fiber cloth and toughened glass, and the toughened glass, the polyimide fiber cloth, the graphene heating sheet and the toughened glass are arranged from inside to outside in sequence; an opening is formed in the outer side of the housing, and a mask is arranged at the opening; the lower end of the inner side of the housing is provided with an atomized water inlet which is connected with the air duct.

Preferably, the heat generating module comprises a heat generating component and a housing; the heating assembly is arranged inside the housing and comprises a graphene heating sheet, polyimide fiber cloth and toughened glass, the whole heating assembly has a radian, the polyimide fiber cloth, the graphene heating sheet and the toughened glass are arranged from inside to outside in sequence, and the toughened glass is connected with the housing through aerogel; an opening is formed in the outer side of the housing, and a mask is arranged at the opening; the lower end of the inner side of the housing is provided with an atomized water inlet which is connected with the air duct.

In one embodiment, the overall structure of the heating element is circular arc, and the radian is preferably 1-3 radians, so that the irradiation area and the anion generation efficiency can be improved.

Preferably, the housing comprises a front shell, a rear door, a base and an upper shell; the base is connected with the bottom of the framework, and the upper shell is connected with the top of the framework; the front shell covers the front surface of the framework; the rear shell covers the upper end of the rear surface of the framework; the rear door covers the lower end of the rear surface of the framework; the upper end of the front shell is provided with a mesh enclosure; the lower end of the front shell is provided with a notch for installing a water tank; the power connector is arranged inside the rear door and is connected to the outside of the shell through the rear door; the operation panel is arranged on the upper shell; the sensor module is connected with the operation panel.

Preferably, the rear shell and the rear door are connected through a buckle, and the front shell, the rear shell and the heating module are connected together through a buckle.

Compared with the prior art, the technical scheme of the invention has the following beneficial effects:

(1) the invention has the functions of air purification, far infrared physiotherapy, negative oxygen ion generation and air humidification.

(2) According to the invention, water mist is formed outside the heating module by using the ultrasonic atomizer, electrons of water molecules are transited after being irradiated by far infrared waves, a certain number of negative oxygen ions are generated, VOC molecules in air can be captured for combination, and dust in the air and the captured VOC molecules are filtered by using the cylindrical high-efficiency filter screen, so that a more optimized and healthy air purification effect is realized.

(3) The graphene heating sheet in the heating module can generate far infrared waves to carry out far infrared physiotherapy on a human body.

(4) The water smoke that the ultrasonic atomization ware produced releases the external world through the face guard of the module that generates heat and the screen panel of shell, can carry out the humidification to the environment.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

Fig. 1 is an exploded view of a graphene far infrared physiotherapy air purifier provided by the present invention;

fig. 2 is a structural diagram of a framework in the graphene far infrared physiotherapy air purifier provided by the invention;

fig. 3 is a structural diagram of an ultrasonic module in the graphene far infrared physiotherapy air purifier provided by the invention;

fig. 4 is a structural diagram of a heating module in the graphene far infrared physiotherapy air purifier provided by the invention.

Reference numerals: 101. a front housing; 102. a rear housing; 103. a rear door; 104. a base; 105. an upper shell; 2. a framework; 201. an air duct; 202. a fan; 203. a silent water pump; 204. a water pipe; 3. a heating module; 301. a housing; 302. a face mask; 303. an atomized water inlet; 4. an ultrasonic module; 401. an atomized water outlet; 5. a sensor module; 6. a cylindrical high-efficiency filter screen; 7. a water tank.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. In the following description, specific details such as specific configurations and components are provided only to help the embodiments of the present application be fully understood. Accordingly, it will be apparent to those skilled in the art that various changes and modifications may be made to the embodiments described herein without departing from the scope and spirit of the present application. In addition, descriptions of well-known functions and constructions are omitted in the embodiments for clarity and conciseness.

It should be appreciated that reference throughout this specification to "one embodiment" or "the embodiment" means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present application. Thus, the appearances of the phrase "one embodiment" or "the present embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

Further, the present application may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.

The term "and/or" herein is merely an association describing an associated object, meaning that three relationships may exist, e.g., a and/or B, may mean: a exists alone, B exists alone, and A and B exist at the same time, and the term "/and" is used herein to describe another association object relationship, which means that two relationships may exist, for example, A/and B, may mean: a alone, and both a and B alone, and further, the character "/" in this document generally means that the former and latter associated objects are in an "or" relationship.

The term "at least one" herein is merely an association relationship describing an associated object, and means that there may be three relationships, for example, at least one of a and B, may mean: a exists alone, A and B exist simultaneously, and B exists alone.

It is further noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion.

Example 1

Referring to fig. 1, fig. 1 is an exploded view of a graphene far infrared physiotherapy air purifier, which shows that the graphene far infrared physiotherapy air purifier comprises a shell, a framework 2, a heating module 3, an ultrasonic module 4, a sensor module 5, a cylindrical high-efficiency filter screen 6, a water tank 7 and a power connector;

the framework 2 is vertically arranged and provided with a vertical column and a transverse baffle, and the framework 2 is divided into an upper layer and a lower layer by the transverse baffle;

the heating module 3 is arranged on the upper layer of the front end of the framework 2; the ultrasonic module 4 and the sensor module 5 are arranged on the upper layer of the rear end of the framework 2;

the water tank 7 is arranged at the lower layer of the front end of the framework 2; the cylindrical efficient filter screen 6 is arranged at the lower layer of the rear end of the framework;

the ultrasonic module 4 is connected with the heating module 3 and the water tank 7.

The power connector is connected with the framework 2, the heating module 3, the ultrasonic module 4, the sensor module 5, the cylindrical high-efficiency filter screen 6 and the water tank 7.

Further, the housing includes a front case 101, a rear case 102, a rear door 103, a base 104, and an upper case 105; the base 104 is connected with the bottom of the framework 2, and the upper shell 105 is connected with the top of the framework 2; the front shell 101 covers the front surface of the framework 2; the rear shell 102 covers the upper end of the rear surface of the framework 2; the rear door 103 covers the lower end of the rear surface of the framework 2; the upper end of the front shell 101 is provided with a mesh enclosure; the lower end of the front shell 101 is provided with a gap for installing the water tank 7; the power connector is arranged inside the rear door 103 and is connected to the outside of the housing through the rear door 103; an operation panel is provided on the upper case 105; the sensor module 5 is connected to the operation panel.

Further, the rear shell 102 and the rear door 103 are connected by a snap, and the front shell 101, the rear shell 102 and the heating module 3 are connected together by a snap.

Further, a water level sensor of the water tank 7 is arranged in the water tank 7 and is connected with a water level alarm;

further, an ultraviolet germicidal lamp is arranged in the water tank 7, and when the water tank is opened, the ultraviolet germicidal lamp is automatically powered off to prevent harm to people;

further, the sensor module 5 comprises a temperature sensor, a humidity sensor, a PM2.5 sensor, a VOC sensor and a negative oxygen ion concentration sensor.

Referring to fig. 2, fig. 2 is a structural diagram of a framework 2 in the graphene far infrared physiotherapy air purifier provided by the present invention, which shows that a fan 202, an air duct 201, a silent water pump 203 and a water pipe 204 are disposed on the framework 2.

Further, the water tank 7 is connected with the silence water pump 203 through a water pipe 204, the silence water pump 203 is connected with the ultrasonic module 4 through a water pipe 204, and the ultrasonic module 4 is connected with the heating module 3 through an air duct 201.

Referring to fig. 3, fig. 3 is a structural diagram of an ultrasonic module 4 in the graphene far infrared physiotherapy air purifier provided by the present invention, which shows that the ultrasonic module 4 includes an ultrasonic atomizer, a small fan and a housing, the ultrasonic atomizer is disposed at the bottom of the housing, the small fan is disposed inside the housing, the housing is provided with an atomized water outlet 401, an input end of the ultrasonic atomizer is connected to a water pipe 204, an output end of the ultrasonic atomizer is connected to the small fan and the atomized water outlet, and the atomized water outlet 401 is connected to an air duct 201.

Example 2

Based on above-mentioned embodiment 1, the structure of module 3 generates heat in graphite alkene far infrared physiotherapy air purifier has mainly been introduced to this embodiment.

Referring to fig. 4, fig. 4 is a structural diagram of a heating module 3 in the graphene far infrared physiotherapy air purifier provided by the present invention, which shows that the heating module 3 includes a heating component and a housing 301; heating element sets up inside housing 301, heating element includes graphite alkene piece, polyimide fiber cloth and two-layer toughened glass that generates heat, and heating element is toughened glass, polyimide fiber cloth, graphite alkene piece, toughened glass that generates heat from inside to outside in proper order. The heating component is arc-shaped in integral structure, and the radian is preferably 1-3 radians.

Furthermore, the toughened glass is high-temperature toughened glass which can resist temperature impact and does not crack.

Furthermore, the edge of the toughened glass is sealed by a sealant.

Furthermore, a plurality of fixing holes are formed in the periphery of the toughened glass, and the periphery of each fixing hole is fixed by sealant.

Furthermore, a layer of toughened glass that is located the outside is provided with a plurality of wire holes for graphite alkene generates heat the piece and is connected with the power cord.

Furthermore, cushion blocks are arranged on two sides of the fixing hole, and the radian of the cushion blocks leaning against the tempered glass is the same as that of the tempered glass at the fixing hole, so that the cushion blocks can perfectly fit with the tempered glass.

Further, the cover 301 is provided with an opening toward the outside.

Further, the housing 301 is provided with a connecting hole at the position of the tempered glass fixing hole.

Furthermore, at the position of the fixing hole, a stud penetrates through the cushion block to fix the toughened glass on the connecting hole, and the toughened glass is screwed and fixed outside the housing by a nut.

Furthermore, the contact surfaces of the connecting hole and the cushion block are mutually attached, and the cushion block and the inner ring of the connecting hole are provided with inner threads matched with the outer threads of the stud.

Further, the outer surface of the housing 301 is provided with a heat insulation layer.

Further, the thermal insulation layer is aerogel.

Further, the lower end of the inner side of the housing 301 is provided with an atomized water inlet 303, and the atomized water inlet 303 is connected with the air duct 201.

Further, a mask 302 is arranged at the opening of the cover 301.

Further, a hall switch is arranged on the face cover 302 of the heating module 3.

Example 3

Based on above-mentioned embodiment 1, this embodiment has mainly introduced another kind of structure of the module 3 that generates heat among the graphite alkene far infrared physiotherapy air purifier.

Referring to fig. 4, fig. 4 is a structural diagram of a heating module 3 in the graphene far infrared physiotherapy air purifier provided by the present invention, which shows that the heating module 3 includes a heating element and a housing 301; the heating component is arranged in the housing 301, and the heating module 3 comprises the heating component and the housing 301; heating element sets up inside housing 301, heating element includes graphite alkene piece, polyimide fiber cloth and toughened glass that generates heat, and heating element wholly has the radian, is polyimide fiber cloth, graphite alkene piece, toughened glass that generate heat from inside to outside in proper order.

Further, a plurality of fixing holes are formed in the periphery of the tempered glass.

Furthermore, toughened glass is provided with a plurality of wire holes for graphite alkene generates heat the piece and is connected with the power cord.

Further, the toughened glass is fixedly connected with the inner wall of the housing 301 through the aerogel;

further, the cover 301 is provided with an opening toward the outside.

Furthermore, at the position of the fixing hole, a stud penetrates through the fixing hole to fix the toughened glass on the connecting hole, and the toughened glass is screwed and fixed outside the housing by a nut.

Furthermore, an inner ring of the connecting hole is provided with an internal thread matched with the external thread of the stud.

Further, the thermal insulation layer is aerogel.

Further, a mask 302 is arranged at the opening of the cover 301.

Example 4

Based on the

above embodiment

2 or 3, the air purification process of the graphene far infrared physiotherapy air purifier of the present invention includes the following seven steps:

the first step is as follows: detecting by a sensor;

the second step is that: adding water into a water tank;

the third step: pumping water by a water pump;

the fourth step: atomizing by an ultrasonic module;

the fifth step: the fan conveys the fog;

and a sixth step: irradiating by far infrared waves;

the seventh step: and (5) filtering by using a filter screen.

Wherein the first step means, utilize inside temperature sensor, humidity transducer, PM2.5 sensor, VOC sensor, the negative oxygen ion concentration sensor of sensor module 5 to monitor the ambient air to the information that will monitor passes through operating panel and shows.

The second step is that when the water level of the water tank 7 is too low, the water level sensor of the water tank 7 in the water tank 7 can monitor the situation and give an alarm by flashing a red bulb water level alarm to remind people to add water.

The third step is that the mute water pump 203 pumps out the water in the water tank 7 through the water pipe 204 and transmits the water to the ultrasonic module 4 through the water pipe 204.

The fourth step is to atomize the water transmitted by the ultrasonic atomizer in the ultrasonic module 4 and transmit the atomized water to the atomized water outlet 401 through the small fan 202.

The fifth step is that the atomized water is transmitted through the air duct 201 by the fan 202 and enters the heating module 3 from the atomized water inlet at the bottom of the heating module 3.

The sixth step is that atomized water forms water mist outside the graphene heating sheet, electrons of water molecules are transited after the water molecules are irradiated by far infrared waves, a certain number of negative oxygen ions are generated, and the negative oxygen ions enter the air through the face mask 302 and are combined with VOC molecules in the air.

The seventh step is that the air enters the cylindrical efficient filter screen 6 through the face mask 302 on the rear door 103, and the cylindrical efficient filter screen 6 filters dust in the air and VOC molecules captured by negative oxygen ions, thereby achieving the effect of purifying the air.

Example 5

Based on above-mentioned embodiment 4, this embodiment has mainly introduced graphite alkene far infrared physiotherapy air purifier's physiotherapy effect.

The infrared lamp used by the traditional physiotherapy instrument has high radiation frequency and strong permeability, the peak value of the infrared ray is 1300nm, so that the wavelength of the infrared ray can just penetrate the corium layer of a human body, the blood circulation is promoted, the absorption capacity of muscles to the inflammation of joint tissues is enhanced, the arthritis symptom is relieved, and the healing of soft tissue injury is promoted.

The research shows that the far infrared ray with the wavelength of 8 mu m is most easily absorbed by human protein, and in the process, photon energy in the wavelength range of the far infrared ray cannot activate the electronic energy level of molecules, so that cell molecules cannot be ionized to cause harm, but the molecular energy level of organisms can be excited and then is in a higher vibration level to activate the activity of biomacromolecules such as water molecules, nucleic acid protein and the like, so that the functions of regulating the activities of organism metabolism, immunity and the like by the biomacromolecules are exerted, and the recovery and the balance of the organism function are facilitated. And the temperature of the protein does not change in the process. Through detection, the graphene heating sheet module disclosed by the invention can generate far infrared wave with a wave crest just about 8 microns.

The heating module 3 comprises a heating component and a housing 301; the heating assembly is arranged inside the housing 301 and comprises a graphene heating sheet, polyimide fiber cloth and toughened glass, the whole structure of the heating assembly has a radian, and the toughened glass, the polyimide fiber cloth, the graphene heating sheet and the toughened glass are arranged from inside to outside in sequence; an opening is formed in the outer side of the cover shell 301, and a face mask 302 is arranged at the opening; the lower end of the inner side of the housing 301 is provided with an atomized water inlet 303, and the atomized water inlet 303 is connected with the air duct 201. Through making heating element overall structure be the arc, the heating efficiency of multiplicable graphite alkene piece that generates heat has accelerated the emergence of electron transition frequency simultaneously, improves irradiation area and anion and produces efficiency, and then has promoted the physiotherapy effect effectively. Preferably, the tempered glass is two layers. Preferably, the arc of the whole structure of the heating component is 1-3 arcs.

According to the invention, the toughened glass is arranged in the graphene far infrared physiotherapy air purifier, far infrared waves generated by the graphene heating sheet irradiate atomized water molecules to generate negative oxygen ions, VOC (volatile organic compounds) molecules in the air are absorbed, and impurities in the air are filtered by the cylindrical high-efficiency filter screen 6, so that the air purification effect is achieved. Meanwhile, far infrared waves generated by the graphene heating sheet can carry out far infrared radiation physiotherapy on a human body, so that the recovery and balance of the functions of the human body are facilitated.

The above description is only a preferred embodiment of the present invention, and it is not intended to limit the scope of the present invention, and various modifications and changes may be made by those skilled in the art. Variations, modifications, substitutions, integrations and parameter changes of the embodiments may be made without departing from the principle and spirit of the invention, which may be within the spirit and principle of the invention, by conventional substitution or may realize the same function.

Claims

1. A graphene far infrared physiotherapy air purifier is characterized by comprising a shell, a framework (2), a heating module (3), an ultrasonic module (4), a sensor module (5), a cylindrical efficient filter screen (6), a water tank (7) and a power connector;

the framework (2) is vertically arranged and provided with an upright post and a transverse baffle, and the framework (2) is divided into an upper layer and a lower layer by the transverse baffle;

the heating module (3) is arranged on the upper layer of the front end of the framework (2); the sensor module (5) and the ultrasonic module (4) are arranged on the upper layer of the rear end of the framework (2);

the water tank (7) is arranged on the lower layer of the front end of the framework (2); the cylindrical high-efficiency filter screen (6) is arranged at the lower layer of the rear end of the framework;

the ultrasonic module (4) is connected with the heating module (3) and the water tank (7);

the power connector is connected with the framework (2), the heating module (3), the ultrasonic module (4), the sensor module (5), the cylinder efficient filter screen (6) and the water tank (7).

2. The graphene far infrared physiotherapy air purifier as claimed in claim 1, wherein a water tank (7) water level sensor is arranged in the water tank (7) and is connected with a water level alarm; an ultraviolet germicidal lamp is arranged in the water tank (7).

3. The graphene far infrared physiotherapy air purifier as claimed in claim 1, wherein the sensor module (5) comprises a temperature sensor, a humidity sensor, a PM2.5 sensor, a VOC sensor, and a negative oxygen ion concentration sensor.

4. The graphene far infrared physiotherapy air purifier as claimed in claim 1, wherein a fan (202), an air duct (201), a silent water pump (203) and a water pipe (204) are arranged on the framework (2).

5. The graphene far infrared physiotherapy air purifier as claimed in claim 4, wherein the water tank (7) is connected with the mute water pump (203) through a water pipe (204), the mute water pump (203) is connected with the ultrasonic module (4) through the water pipe (204), and the ultrasonic module (4) is connected with the heating module (3) through an air duct (201).

6. The graphene far infrared physiotherapy air purifier as claimed in claim 4, wherein the ultrasonic module (4) comprises an ultrasonic atomizer, a small fan and a shell, the ultrasonic atomizer is arranged at the bottom inside the shell, the small fan is arranged inside the shell, an atomized water outlet (401) is formed in the shell, the input end of the ultrasonic atomizer is connected with a water pipe (204), the output end of the ultrasonic atomizer is connected with the small fan and the atomized water outlet, and the atomized water outlet (401) is connected with an air duct (201).

7. The graphene far infrared physiotherapy air purifier as claimed in claim 4, wherein the heating module (3) comprises a heating component and a housing (301); the heating component is arranged inside the housing (301), comprises a graphene heating sheet, polyimide fiber cloth and toughened glass, and is sequentially provided with the toughened glass, the polyimide fiber cloth, the graphene heating sheet and the toughened glass from inside to outside; an opening is formed in the outer side of the cover shell (301), and a face mask (302) is arranged at the opening; the lower extreme of the inboard of housing (301) is provided with atomizing water entry (303), atomizing water entry (303) are connected with wind channel (201).

8. The graphene far infrared physiotherapy air purifier as claimed in claim 4, wherein the heating module (3) comprises a heating component and a housing (301); the heating assembly is arranged inside the housing (301), the heating assembly comprises a graphene heating sheet, polyimide fiber cloth and toughened glass, the polyimide fiber cloth, the graphene heating sheet and the toughened glass are arranged from inside to outside in sequence, and the toughened glass is fixedly connected with the inner wall of the housing (301) through aerogel; an opening is formed in the outer side of the cover shell (301), and a face mask (302) is arranged at the opening; the lower extreme of the inboard of housing (301) is provided with atomizing water entry (303), atomizing water entry (303) are connected with wind channel (201).

9. The graphene far infrared physiotherapy air purifier of claim 1, wherein the outer shell comprises a front shell (101), a rear shell (102), a rear door (103), a base (104) and an upper shell (105); the base (104) is connected with the bottom of the framework (2), and the upper shell (105) is connected with the top of the framework (2); the front shell (101) covers the front surface of the framework (2); the rear shell (102) covers the upper end of the rear surface of the framework (2); the rear door (103) covers the lower end of the rear surface of the framework (2); a mesh enclosure is arranged at the upper end of the front shell (101); the lower end of the front shell (101) is provided with a notch for installing the water tank (7); the power connector is arranged inside the rear door (103) and is connected to the outside of the shell through the rear door (103); the operation panel is arranged on the upper shell (105); the sensor module (5) is connected with the operation panel.

10. The graphene far infrared physiotherapy air purifier as claimed in claim 9, wherein the rear shell (102) and the rear door (103) are connected through a buckle, and the front shell (101), the rear shell (102) and the heating module (3) are connected together through a buckle.