FIELD OF THE INVENTION
The present invention relates generally to systems and methods of use, and more particularly, to a system and method of use of a halotherapy system and red light system that emits red light low-level wavelengths that in combination improve the positive effects sustained during the halotherapy session.
BACKGROUND OF THE INVENTION
Halotherapy or salt therapy is a form of alternative medicine that makes use of salt. Halotherapy involves grinding salt to fine particles and then dispersed into the surrounding air. This form of therapy is typically done in a closed environment, such as a room or booth, where people inside of the closed environment can easily breathe in the air mixture of oxygen, nitrogen and salt particles dispensed in the air. Salt inhalation therapy, or otherwise referred to as halotherapy, is known to benefit individuals who suffer from respiratory illnesses, such as asthma, chronic bronchitis, and allergies. Salt therapy is also known to improve lung health, kill bacteria, treat depression and anxiety and in some cases cure certain skin conditions, such as psoriasis, eczema, and acne.
In addition to health improvements, halotherapy has shown to improve the performance of athletes because it cleans the respiratory system of an athlete, naturally opening the airways, helping to improve lung function and increasing lung capacity. This means that an athlete having undergone such therapy is able to reduce lung exertion and as a result increase their performance endurance.
Aside from halotherapy, other therapeutic techniques can help athletes with their performance and physique. For instance, red light therapy is a therapeutic technique that uses red low-level wavelengths of light to treat skin issues, such as wrinkles, scars, and persistent wounds, among other conditions. In some clinical trials, red light therapy has also shown to increase testosterone levels, as well as reduce symptoms of depression, improve muscle recovery, aid weight loss, reduce inflammation and heal injuries.
Accordingly, there is an established need for a system and method of use for halotherapy treatment that could be combined with other therapeutic techniques, such as red light therapy, to enhance, improve, and increase lung function, testosterone levels, and muscle recovery, while reducing or eliminating symptoms of depression, skin ailments, and other treatable conditions.
SUMMARY OF THE INVENTION
The present invention is directed to a system and method of use for a halotherapy system that also projects red light low-level wavelengths in a closed space. The combination of halotherapy and red light therapy produces a refractory phenomenon as the light waves make contact with the salt particles dispersed in the air to cause a plethora of multi-dimensional dispersions of light waves.
Introducing a first embodiment of the invention, the present invention consists of a halotherapy and red light system, comprising an enclosed space, a machine, and a red light device. The machine may comprise a body comprising a back portion and a front portion, where the front portion includes a control panel and at least one vent. The machine is capable of dispersing salt particles into the surrounding air inside of the enclosed space. The red light device may comprise a body disposed about the ceiling of the enclosed space and include at least one LED that emits red light waves.
In a second aspect, the system may include a physical exertion machine disposed inside of the enclosed space.
In another aspect, the machine may be capable of grinding salt crystals into dispersible salt particles.
In another aspect, the machine may be attached to a designated wall space of the enclosed space.
In another aspect, the physical exertion machine may be one of a stationary cycling machine, rowing machine, walking and running machine, resistance machine, and elliptical machine.
In another aspect, the physical exertion machine may include one of a pulling, pushing, and lifting machine, and a resistance machine.
In another aspect, the red light waves emitted by the red light device are absorbable by a person.
In another aspect, the red light device may emit wavelength beams within a range of about 660 nm to about 850 nm.
In another aspect, at least one red light wave will make contact with at least one salt particle suspended in the air contained inside of the enclosed space. When the wave makes contact with the salt particle, a portion of the red light wave refracts and disperses elsewhere while another portion of the red light wave is absorbed by the salt particle.
In another aspect, the temperature of a salt particle may increase after absorbing a portion of the red light wave that makes contact with the salt particle. The increase in temperature lessens the moisture within the salt particle.
In another aspect, the enclosed space may include a booth, a room, a standing structure, a sauna type room or the like.
In another aspect, the red light waves in the enclosed space may be absorbable by a person and the salt particles are inhalable and absorbable by the person.
In another aspect, the halotherapy enclosure system may comprise an enclosure delimiting an enclosed space accessible through a pivoting door that in a closed configuration seals the enclosed space. The enclosure may include some non-transparent and some transparent surface. Inside of the enclosed space, the enclosure system may include at least one red light panel and at least one thermal heating light panel disposed on the same or separate interior enclosure surfaces. A salt aerosol dispersing device including a grinder configured to grind salt crystal into dispersible salt particles and a blower configured to uniformly disperse the salt particles into the enclosure is provided. The salt aerosol dispersing device may be disposed within the enclosure, partially within or partially outside the enclosure, or entirely outside of the enclosure. Outside the enclosure, the halotherapy system includes a controller configured to control conditions inside of the enclosed space. For example, the salination level, red light emission levels, and thermal heat levels. The halotherapy enclosure system's enclosed space is sufficiently sized to retain at least one physical exertion machine within the enclosed space of the enclosure.
These and other objects, features, and advantages of the present invention will become more readily apparent from the attached drawings and the detailed description of the preferred embodiments, which follow.
BRIEF DESCRIPTION OF THE DRAWINGS
The preferred embodiments of the invention will hereinafter be described in conjunction with the appended drawings provided to illustrate and not to limit the invention, where like designations denote like elements, and in which:
FIG. 1 presents a perspective view showing a halotherapy apparatus used with the system and method of use of the present invention;
FIG. 2 presents a side view of an enclosed space where red light wave therapy and an exercise machine are used in a halotherapy session in accordance with the system and method of use of the present invention;
FIG. 3 presents an exemplary illustration of a person inhaling the salt particles dispensed in the air during the halotherapy session;
FIG. 4 presents an exemplary illustration of a plurality of light waves refracting off of a salt particle dispensed in the air;
FIG. 5 presents an exemplary illustration of light waves colliding with salt particles dispensed in the air, reducing the amount of moisture in the salt particle;
FIG. 6 presents a side view of salt particles dispensed in the air and refracting light waves toward the person inside of the enclosed space during a halotherapy session in accordance with the system and method of use of the present invention;
FIG. 7 presents a perspective view of the halotherapy enclosure system in an exemplary embodiment;
FIG. 8 presents perspective view of the enclosed space of the halotherapy enclosure system in FIG. 7;
FIG. 9 presents an orthographic view of the thermal heating system used in the halotherapy enclosure system;
FIG. 10 presents an orthographic view of another exemplary thermal heating system used in the halotherapy enclosure system; and
FIG. 11 presents an orthographic view of the red light system used in the halotherapy enclosure system.
Like reference numerals refer to like parts throughout the several views of the drawings.
DETAILED DESCRIPTION
The following detailed description is merely exemplary in nature and is not intended to limit the described embodiments or the application and uses of the described embodiments. As used herein, the word “exemplary” or “illustrative” means “serving as an example, instance, or illustration.” Any implementation described herein as “exemplary” or “illustrative” is not necessarily to be construed as preferred or advantageous over other implementations. All of the implementations described below are exemplary implementations provided to enable persons skilled in the art to make or use the embodiments of the disclosure and are not intended to limit the scope of the disclosure, which is defined by the claims. For purposes of description herein, the terms “upper”, “lower”, “left”, “rear”, “right”, “front”, “vertical”, “horizontal”, and derivatives thereof shall relate to the invention as oriented in FIG. 1. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary or the following detailed description. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification, are simply exemplary embodiments of the inventive concepts defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise.
Referring initially to FIGS. 1 and 2, an exemplary embodiment of a halotherapy and red light system 100 is generally shown. The halotherapy and red light system 100 may comprise an enclosed space 120, a machine 102, and a red light system 115. The enclosed space 120 may include at least four upstanding sidewalls 126 supporting a ceiling 124. Supporting the upstanding sidewalls 126 may be a floor or a base 128. The enclosed space 120 may also include at least one entry door (not shown) that gives access into the enclosed space 120. In one exemplary form, the enclosed space may be part of a larger structure such as, a room in a building. In that particular embodiment, the enclosed space 120 may include for aesthetic purposes salt-covered walls, special lighting, loose salt floors, and comfortable seating such as, lounge chairs, recliners, sofa, or the like. In another exemplary embodiment, the enclosed space 120 may include sensors that read humidity, moisture and temperature levels. The enclosed space may further include special mood lighting, and have an HVAC system that provides heating and air conditioning to the enclosed space 120.
In another exemplary embodiment, the upstanding sidewalls 126, base 128, and ceiling 124 of the enclosed space may be treated with chemicals to prevent salt from migrating out of the enclosed space. For instance, the surrounding walls, floor and ceiling of the enclosed space 120 may be treated and cured with known sealants to prevent salt particles from escaping or penetrating through the wall material. In another exemplary embodiment, the surrounding walls of the enclosed space 120 may be treated and a layered with salt covered tiles that are adhered to the upstanding sidewalls 126 of the enclosed space 120 to provide an aesthetic look to the space. On the base 128 (or floor) of the enclosed space 120, loose salt may be evenly dispersed across the surface area of the base forming a thick layer of salt on the ground. In yet another embodiment, the enclosed space may be a freestanding structure, such as a booth, tent, a portable trailer, and an erectable or transportable structure. For example, a transportable structure may be transported between locations to service persons in different locals with halotherapy treatments. In that particular case, all that is necessary is that the enclosed space have ventilation. However, it is appreciated that the structure may include some or all of the aforementioned amenities.
The machine 102 of the halotherapy and red light system 100 may generally comprise a unit 104 having a back portion 112 and a front portion 114. The front portion 114 of the machine may include a control panel 106 that controls and operates the machine 102. The front portion 114 of the machine may also include at least one vent 108 (although the accompanying figures illustrate at least two). The machine 102 may include a receptacle, grinding mechanism, and a discharge mechanism. The receptacle of the machine 102 is designed to hold salt crystals therein. The receptacle (not shown) may include a funnel that directs the salt crystals into the grinding mechanism of the machine. The grinding mechanism goes through the process of manipulating the salt crystals in the receptacle by grinding the salt crystals to the size of about one to about five micrometers to produce a dry salt aerosol 110. The salt aerosol is then released with the use of the discharge mechanism of the machine into the atmosphere of the enclosed space 120 through the at least one vent 108 on the unit 104. As shown in FIGS. 3 and 6, the salt aerosol particles 110 dispersed into the air inside of the enclosed space 102 are absorbable by a person when the particles 110 land on the person's skin 202. The salt particles 110 are also inhalable by the person 200 when they breathe in air through their nose and mouth 204, which transports the salt particles into the person's respiratory system.
The machine 102, as is shown in FIG. 1, may comprise a freestanding unit that draws power from a power source, such as a domestic electrical outlet supplying 120v, or a generator (if the enclosed space is transportable). Alternatively, the machine 102 may comprise a unit 104 that is attachable to a designated wall space in the enclosed space 102. For example, the back portion 112 of the unit 104, in one exemplary embodiment, may be seated inside of a recess provided on one of the upstanding sidewalls 126 of the enclosed space 102. In this configuration, the machine 102 is not touching the base 128 of the enclosed space 120 taking up unnecessary space, thereby giving the person 200 inside the enclosed space 120 more room to move about. Although the present illustrations only show one machine 102 inside of the enclosed space 120 during a therapy session, one will appreciate that a plurality of machines may be disposed inside of the enclosed space if deemed necessary. For instance, where the enclosed space is too large for a single machine, additional machines may be added to ensure the airborne salinity level in the enclosed space is at an optimal level.
With reference to FIG. 2, the red light system 115 of the halotherapy and red light system 100 may include a plurality of red light devices 116 disposed about the ceiling 124 of the enclosed space 120. The red light devices 116 may also be evenly spaced-apart or scattered in a discernable or undiscernible pattern about the ceiling 124. Moreover, each red light device may be either recessed into the ceiling of the enclosed space or slightly protrude outwardly from the ceiling, as is shown in the FIG. 2. In an alternative embodiment, red light devices 116 may be disposed about the ceiling 124 and upstanding sidewalls 126 of the enclosed space 120 in a spaced-apart relationship (not shown). A red light device 116 may comprise a unit body 118 and at least one LED 122, with each body 118 including a set of connection cables that can connect one unit 118 to another unit 118 to allow each unit to be simultaneously controlled through a single device, such as a remote or switch. For instance, as shown in FIG. 2, all of the red light devices 116 may be simultaneously activated or deactivated through a control device to activate the unit's LED's 122. The LEDs 122 of each device 118 are capable of emitting red light beams 126. The red light beams 126, in one exemplary embodiment, may include a wavelength beam within a range of about 630 nm (i.e., red light) to about 850 nm (i.e., infrared light). One will appreciate, however, that alternative light spectrums that have beneficial effects may be used in the present invention. As will be appreciated, the number of red light devices 116 in the red light system 115 will vary depending on the size of the enclosed space 120 and thus, the number of devices 118 could range in numbers between one and about twenty or more devices.
With continued reference to FIG. 2, the halotherapy and red light system 100 may further include at least one physical exertion device 140. They physical exertion device 140 can be placed inside of the enclosed space 120 to allow a person 200 to naturally, through the use of the physical exertion device, increase their breathing and heart rate and the amount of air they inhale while the person spends time inside of the enclosed space 120. By using the physical exertion device 140, a person will naturally be inclined to take deeper breaths as the body's natural response to exercise is to bring in more oxygen to feed the respiratory system when burning fuel during exercise sessions. As a result, the person 200 inhales more salt particles 110 during a single therapy session than the person would have otherwise inhaled (if the person's heart rate remained the same). In one exemplary form, the at least one physical exertion device 140 may include fitness equipment, such as dumbbells or weight training devices, stationary bike, treadmill, elliptical machine, exercise ring, or the like. The enclosed space 120 may also provide a designated area that is large enough to allow the person to exercise by engaging in push up exercises, sit-ups, or pull-ups.
Referring now to FIGS. 3-6, in a therapy session, the machine 102 disperses salt particles 110 into the air inside of the enclosed space 120. Simultaneously, each red light device 116 of the red light system 115 will disperse red light beams 126 into the enclosed space 120. While a person undergoes a therapy session, which could last anywhere between ten minutes to about forty-five minutes or more, a person will inhale salt particles 110 infused with the surrounding air inside of the enclosed space. A person will also some of the salt particles 110 through their exposed skin 202 as salt particles will undoubtable land on the person.
A person 200 will also be subjected to the red light beams 126 that are emitted from the red light devices 116 of the red light system 115. Naturally, some of the red light beams 126 will be absorbed by the person's skin 202 when an unimpeded beam travels from the device's LED 122 to the person. Some red light beams, however, will be reach a person because of refraction. For instance, the combination of red light beams and halotherapy in the same enclosed space 120 produces a refractory phenomenon whenever a red light beam 126 makes contact with a salt particle 110. For example, when a beam of light travels between two media having different refractive indices, the beam undergoes refraction, and changes direction when it passes from the first medium to the second one. Wave theory also postulates that a small portion of each angled wave front should impact the second medium before the rest of the front reaches the interface. Meaning, a portion will start to move through the second medium while the rest of the wave is still traveling in the first medium, but will move more slowly due to the higher refractive index of the second medium. Because the wave front is now traveling at two different speeds, the wave will bend in to the second medium and thus, changing the angle of propagation. Whenever a beam is refracted or disturbed in some manner, some portion of the beam may be absorbed by the medium that caused the change of angle of propagation.
Accordingly, in FIG. 4 a plurality of red light beams 122 are shown traveling through the air in the enclosed space 120 until making contact with the surface area 130 of a single salt particle 110. When the front portion 126a of the light beam 126 makes contact with the surface area 130 of the salt particle 110, the front portion 126a of the light beam 126 bends and changes direction, while the second portion 126b of the beam tries to catch up. A portion 126c of the light beam 126 may be lost to absorption by the salt particle 110 as the light beams 126 refract. Referring quickly to FIG. 2, generally the red light devices 116 disposed about the ceiling 124 or upstanding sidewall project red light beams 126 in a singular direction (i.e., the direction the LEDs 122 are facing). Meaning, certain parts of the person 200 that are not exposed or are otherwise sheltered from the direct pathway of the red light beams 126 will not make contact with red light beams. In the present invention, however, the halotherapy and red light system is designed to create multi-dimensional dispersions of red light waves 126 inside of an enclosed space 120.
The salt particles 110 are not stationary or uniform in shape and size and thus, each salt particle 110 may rotate and change its position as it moves through the air in the enclosed space 120. FIG. 6 shows how the red light beams 126 refract from a salt particles 110 rotating in the air in the enclosed space 120. When the red light beam makes contact with the salt particle, the trajectory of the red light beam changes and reaches areas that the red light beam would not have otherwise been able to reach. For example, red light beams 126 may reach an area or a number of areas that are for the most part hidden or inaccessible to the red light devices 116 that are disposed about the ceiling and upstanding sidewalls of the enclosed space. These areas include, but are not limited to, the person's chin, torso, arms, and neck. In the present invention, however, the red light beams refract from the salt particles 110 and reach those areas. Because there are thousands of salt particles 110 randomly floating within the enclosed space 120, different patterns emerge whenever a red light beam 126 makes contact with a salt particle, creating a diverse, multi-angled refractory dispersion phenomenon of red light beams inside of the enclosed space 120.
With reference to FIG. 5, when a red light beam 126 makes contact with a salt particle, a portion of the red light beam 126 may be lost to the salt particle 110. When this occurs, the temperature T1 of the salt particle 110 begins to rise as the salt particle continues to absorb portions of red light beams 126. As the temperature T1 of the salt particle 110 rises to a higher temperature T2, the moisture 134 within the salt particle 110 begins to lessen. This in turn causes the salt particle 110 to become dryer, which enhances the therapeutic properties of the salt particle that are inhaled by the person 200. Moreover, portions of the red light beam 126 that are absorbed by the salt particle 110 may be released inside of the internal system of the person when a person inhales the salt particle 110. As such, the benefits of red light therapy may also be applied to the internal system of the person.
With reference now to FIGS. 7 through 11, another exemplary embodiment of the halotherapy and red light system (herein after referred to as the “halotherapy enclosure system”) 300 is generally shown. The halotherapy enclosure system 300 generally comprises an enclosure 302 delimiting an enclosed space 304. In some exemplary embodiments, the enclosure 302 includes at least four upstanding surfaces 306 extending from a floor 304 and supporting a ceiling 308, all of which delimit the enclose space 304. As seen in FIG. 7, access into the enclosed space 304 of the enclosure 302 can be generally done through a closeable opening 312 (e.g., a door). In one exemplary embodiment, the closeable opening is a door that is designed to pivot about a pair of hinges such that the door can be positioned in an open configuration—granting access to the enclosed space 304—or in a closed configuration—sealing the enclosed space from an exterior environment. Of course, alternative door mounting implementations may be done without departing from the scope of the invention and thus the foregoing is to be understood as exemplary and not limiting.
As illustrated, the enclosure 302 may include on or more surfaces that are transparent (e.g., see through glass) and one or more surfaces that are not transparent (e.g., solid materials or opaque glass). Disposed within the enclosed space 304 of the enclosure, the halotherapy enclosure system 300 includes on or more sensors 314 that are configured to detect humidity levels, moisture levels, salination levels, temperature levels, and light emission levels inside of the enclosed space 304 of the enclosure 302. The sensors may be scattered throughout the enclosure in one exemplary form or in the alternative grouped together in one optimized location within the enclosure. The enclosed space 302 of the enclosure 300 is also sufficiently sized to encase or otherwise retain within the enclosed space a physical exertion device 140. As discussed herein above, the physical exertion device may comprise any one of a plurality of devices or machines designed to allow a person to perform physical exercises. For example, the enclosed space 302 is large enough to retain a stationary bike to be used within the enclosure 300 to maximize the benefits of the halotherapy session.
With continued reference to FIGS. 7, 8, and 11, the halotherapy enclosure system 300 includes a red light system 316. The red light system 316 in one exemplary embodiment may comprise a panel body 318 that includes a front face 320, rear face 322, side faces 324, and top and bottom faces 326. The front face 320 of the panel body 318 includes a plurality of openings 328 that give way to a plurality of red light LEDS 330 to protrude through or emit red light through the openings. The LEDs, in one exemplary form, are connected in series and are powered by a power source. The power source may include a battery or an external power source that connects to an electrical outlet port 332, powering the halotherapy enclosure system 300 (including all of its other electrical components). Disposed inside of the panel body 318 are a plurality of fans 334 to cool down or otherwise lower the heat temperature produced by operation of the LEDs. At the side faces 324 of the panel body 318 of the red light system 316, the panel body 318 includes one or more mounting brackets 336 that are used to mount the red light system 316 to an interior upstanding surface 306 of the enclosure 302, as seen in FIGS. 7 and 8. As exemplary shown, the red light system 316 may be disposed to substantially extend longitudinally on an interior wall surface 306 of the enclosure 302. In some embodiments, the red light system 316 extends the entirety of the interior wall surface or in alternative embodiments only extends a portion of the interior wall surface. The red light system is controlled by a controller 338 but more on that later.
The halotherapy enclosure system 300 may further include one or more thermal heating light system 340. The thermal heating light system 340 in one exemplary embodiment may comprise a panel body 342 that includes a front face 344, rear face 346, side faces 348, and top and bottom faces 350. The front face 344 of the panel body 342 includes a plurality of openings 352 that give way to a plurality of thermal infrared light bulbs devices 354 configured to emit thermal energy. In one exemplary embodiment, the thermal light bulb is capable of infrared light with an available wattage of 100 W, 150 W, 175 W, 250W, 275 W, or 375 W. The light bulb devices 354, in one exemplary embodiment, are connected in series and are powered by the power source. As discussed above, the power source may include a battery or an external power source that connects to an electrical outlet port 356. At the side faces 348 of the panel body 342 of the thermal heating light system 340, the panel body 334 may include one or more mounting brackets 336, similar to the ones illustrated in FIG. 11, that are used to mount the thermal heating light system 340 to an interior upstanding surface 306 of the enclosure 302, as seen in FIGS. 7 and 8. In some exemplary embodiments, the red light system 316 and the thermal heating light system 340 may be disposed on the same interior upstanding surface within the enclosure space 304 of the enclosure 302.
In alternative embodiments, as is exemplary shown in FIGS. 7 and 8, the red light system 316 and the thermal heating light system 340 are disposed in separate upstanding surfaces within the enclosure space 304 of the enclosure 302. In one exemplary form, the thermal heating light system 340 may be disposed substantially extending longitudinally on an interior wall surface 306 of the enclosure 302. For instance, the thermal heating light system 340 may extend the entirety of the interior wall surface or in alternative embodiments only extend a portion of the interior wall surface. Moreover, the thermal heating light system 340 may be disposed on the interior wall surfaces of the enclosure that makes a corner with another interior wall surface that includes the red light system 316 so that the thermal heating system and red light system face inward (normal to one another) and toward the center of the enclosure, concentrating the heat and red light energy toward the exercise device, as seen in FIG. 8. As seen in FIGS. 9 and 10, the thermal heating system 340 may be provided in a rectangular-shaped housing configuration or in a square-shaped housing configuration 360. As is the case for the red light system, the thermal heating light system 340 is controlled by the controller 338.
With reference now to FIGS. 7 and 8, the halotherapy system 300 includes a controller 338 that is electronically connected to the electronic components of they system 300. The controller comprises a processor that includes one or more executable commands stored in memory, on or more input buttons, a timer, a wireless card, a display, and a power supply. The term microprocessor, as used herein, refers to central processing units, processors, microcontrollers, reduced instruction set circuits (RISC), application-specific integrated circuits (ASIC), logic circuits, and any other circuit or processor capable of executing the functions described herein. As used herein, the terms “software’ and “firmware” are interchangeable and include any computer program stored in memory for execution by the processor, including RAM memory, ROM memory, EPROM memory, EEPROM memory, and non-volatile RAM (NVRAM) memory. The above memory types are exemplary only and are thus not limiting as to the types of memory usable for storage a computer program. In one exemplary embodiment, the processor may be operating one or more executable commands that enables the controller to control the red light system, thermal heating light system, the sensors and the salt aerosol dispersing device 362. In some embodiments, the controller 338 is provided separately from the salt aerosol dispersing device, whereas in alternative embodiments the controller and salt aerosol dispersing device are integrated into a singular device. The controller 338 may be connected to the electrical components (e.g., the sensors, red light system, thermal heating light system, salt aerosol dispersing device) wirelessly or through electrical wires ran through out the enclosure but invisible to the naked eye. In the event the electronic components are wirelessly connected, the controller 338 and the other electrical components can communicate over a network.
Depending on the electronic component, communications software may provide support for communications using one or more of the following communications protocols or standards: the User Datagram Protocol (UDP), the Transmission Control Protocol (TCP), the Internet Protocol (IP), and the Hypertext Transport Protocol (HTTP); one or more lower-level communications standards or protocols such as, for example, the 10 and/or 40 Gigabit Ethernet standards, the Fiber Channel standards, one or more varieties of the IEEE 802 Ethernet standards, Asynchronous Transfer Mode (ATM), X.25. Integrated Services Digital Network (ISDN), token ring, frame relay, Point to Point Protocol (PPP), Fiber Distributed Data Interface (FDDI); and other protocols. Electronic components may include a network interface card, network chip, or network chipset that allows for communication over the network. The controller 338 of the halotherapy system 300 is designed and configured to allow a user to adjust the salination levels within the enclosure, schedule a workout time, and communicate with the sensors of the system to adjusts the red light, heat, and salination levels in the enclosure.
With continued reference to FIGS. 7 and 8, the halotherapy system 300 comprises a aerosol salination device 362. The aerosol salination device 362, which may be disposed outside of the enclosure (as seen in FIG. 8) or inside of the enclosed space 304, comprises a receptacle 364 that is configured to hold salt crystals therein. The receptacle 364 is connected to a conduit or hopper that feeds directly to a grinding mechanism 366 comprising a grinder that pulverizes the salt crystals into salt particles. The salt particles are then released through a discharge system 368 that comprises in one exemplary embodiment a blower configured to uniformly disperse the salt particles inside of the enclosure space 304 of the enclosure 302 of the halotherapy system 300. In one exemplary embodiment, the discharge system 368 is integrated to the aerosol salination device 362, as illustrated in FIG. 7. In an alternative form, the discharge system 368 may comprise one or more conduits 370 connected to one or more vents 372 that uniformly disperse the salt particles inside of the enclosed space 304 of the halotherapy system 300. In some embodiments, the conduits are hidden within the surfaces of the enclosure, whereas in other embodiments the conduits are visible. As discussed in greater detail above, the salt aerosol particles dispersed into the air inside of the enclosed space are absorbable by a person when the particles land on the person's skin. The salt particles are also inhalable by the person when they breathe in air through their nose and mouth, which transports the salt particles, which can be dry because of the heat provided by the thermal heating light system, into the person's respiratory system.
In summary, during a therapy session a person will inhale dry salt particles (with little to no moisture). The salt particles will reach the internal system of the person, including their nasal cavities, sinus cavities, ear canals, and other internal areas of the human body. For example, salt particles inhaled enter the person's respiratory system and dissolve in the lungs of the person, potentially killing portions of virus or bacteria lurking in the lungs. The salt particles may also come into contact with the person's skin and can absorb bacteria and other impurities responsible for many skin conditions. In an alternative embodiment, the halotherapy and red light system may include a machine comprising a halo unit hanging from the ceiling of the enclosure. One will appreciate that the invention described may also be used to therapeutically treat animals, such as dogs, cats, and horses. Overall, the present invention augments and enhances the positive effects of the red light therapy and halotherapy inside of an enclosed space.
Since many modifications, variations, and changes in detail can be made to the described preferred embodiments of the invention, it is intended that all matters in the foregoing description and shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. Furthermore, it is understood that any of the features presented in the embodiments may be integrated into any of the other embodiments unless explicitly stated otherwise. The scope of the invention should be determined by the appended claims and their legal equivalents.
Patent Application
20230414449
