Source: https://patents.google.com/patent/RU2613607C2/en
Timestamp: 2019-10-14 10:40:33
Document Index: 419973511

Matched Legal Cases: ['application No. 61', 'art 20', 'art 20', 'art 20', 'art 20', 'art 20']

RU2613607C2 - Light therapy platform system - Google Patents
RU2613607C2
RU2613607C2 RU2014110105A RU2014110105A RU2613607C2 RU 2613607 C2 RU2613607 C2 RU 2613607C2 RU 2014110105 A RU2014110105 A RU 2014110105A RU 2014110105 A RU2014110105 A RU 2014110105A RU 2613607 C2 RU2613607 C2 RU 2613607C2
RU2014110105A
RU2014110105A (en
Джей ТЭППЕР
Лоуренс А. БЛАУСТЕЙН
Дэвид ШАТЕР
Эрик ФРЕЙТЭГ
Чарльз Питер АЛТОФФ
Алистер БРЭМЛИ
Аллен ЗАДЕ
Дэниел Джозеф ШАТЕР
Збигнев Пол ЛОРЕНК
Джонсон энд Джонсон Консьюмер Инк.
2012-09-06 Application filed by Джонсон энд Джонсон Консьюмер Инк. filed Critical Джонсон энд Джонсон Консьюмер Инк.
2015-10-20 Publication of RU2014110105A publication Critical patent/RU2014110105A/en
2017-03-17 Publication of RU2613607C2 publication Critical patent/RU2613607C2/en
SUBSTANCE: phototherapy systems comprising a therapeutic lamp platform for radiant lamps, such as LEDs disposed in an assembly comprising a first wall to which lamps are affixed, and a second wall, closer to patient, spaced from first wall wherein lamps are recessed relative thereto. Second wall comprises a reflective surface facing towards a patient and a plurality of light apertures substantially aligned with LEDs on first wall for communicating lamp radiation from lamps to a user. Lamps and associated circuitry are disposed between first and second wall so that reflective surface is relatively smooth and seamless towards patient. Walls have a malleable rigidity for flexible adjustability relative to user.
EFFECT: device is mounted to user with a frame comprising an eyeglass frame or goggles including lenses for shielding user's eyes from lamp radiation.
[0001] The priority of this application is claimed on US patent application No. 61/532140, filed September 8, 2011, the contents of which are incorporated herein by reference.
[0002] Embodiments of the present invention relate to devices and methods for providing therapeutic treatment of light-based skin to improve its healthy state, for example, for preventing skin aging or the appearance of acne, using phototherapy based on light emitting diodes (LEDs), although it is possible to use other types of light emitting sources.
[0003] It is known that some optical emission spectra of LEDs (blue or red region of the spectrum) have a therapeutic effect in treating skin for diseases such as acne, or are useful in preventing skin aging. However, there is a need to provide users / patients with a convenient phototherapy device at home, such as a wearable mask, jacket or hood, which is adaptable or flexible to fit any size and shape and which is also simple to use without discomfort for user. Currently available products on the market used by users at home are designed for the same size and / or should generally be held by hand, which generally does not satisfy the conditions for the best or necessary light scattering. An alternative to this is to visit the doctor’s office for treatment.
[0004] Known phototherapy devices, in particular masks, are inherent in problems related to the occurrence of user contact with the LEDs, as well as with the corresponding electrical circuits providing power to the LEDs. More specifically, in order to maximize the light transmission to the patient, the LEDs are arranged so that physical interaction (for example, touching) with the patient or even contact with the treated surface is allowed, which is unfavorable for the LEDs due to the accumulation of dirt and grease. In addition, any such interaction can be dangerous for patients exposed to sharp or hot edges of LEDs and associated electrical circuits. The open arrangement of electrical circuits containing numerous elements leaves a frightening and unpleasant impression when treatment takes several minutes, while a mask located relatively close to the face often causes an uncomfortable feeling of confined space over time.
[0005] Hand-free therapy is always perceived better than having to hold the device in a particular position for extended periods of time. Numerous modules have been developed to place masks or helmet-shaped devices on various straps, ribbons, dressings and cords, which can lead to a close pressing of the support and support module to the hair or scalp of the patient. There is always a need to minimize the size of such fastening modules so that, on the one hand, this device is firmly attached to the patient, and on the other hand, the fastening structure should have a minimal effect on patient comfort during the actual treatment. Relatively light weight, as well as convenient and minimized retention during use during therapy, are important for user acceptance.
[0006] Since users have various shapes and sizes, the devices must be adapted to fit in size or area so that the therapy can be carried out efficiently and / or selectively enhanced for the desired treatment sites.
[0007] In conclusion, especially in therapeutic devices that treat facial areas, it is necessary to provide eye protection in order to avoid damage or irritation of the patient's eyes with light. Known devices generally use removable pads that should be placed on the area around the eyes to block the transmission of therapeutic light to the visual system itself. There is a need for a better method that can easily be adapted to transmit therapeutic light to areas near the eyes, in particular in the prevention of aging, and which also protect the patient.
[0008] It is desirable to provide an alternative means to take advantage of phototherapy in a manner that maximizes the effectiveness of the treatment when exposed and which at the same time maintains ease and ease of use. To this end, various embodiments are disclosed within the scope of the present invention, which are flexible and lightweight, and are also adaptable, including various applications with energy varying according to the conditions or needs of the user.
[0009] These embodiments comprise phototherapy systems and devices comprising a therapeutic base for emitting lamps, for example, LEDs placed in a module containing a first wall to which the lamps are attached and a second wall located closer to the patient and at a distance from the first walls, said lamps being recessed relative to said wall. The second wall has a reflective surface facing the patient, and light-transmitting holes, essentially located on one straight line with LEDs located on the first wall, for transmitting lamp radiation from the lamps to the user. Lamps and corresponding electrical circuits are located between the first and second walls, while the reflective surface in the direction of the patient is relatively smooth and seamless. The number of lamps, as well as the electrical circuits for them, is reduced to a minimum, while other materials of the module are purposefully selected to provide a module with a relatively low weight, which as a result improves the user's comfortable state during a therapy session. These walls are flexible to allow flexible fit to the user's head. More specifically, the walls have a concave shape relative to the face of the user, adjustable relative to the starting position to expand it relative to the size of the user's head for a tight installation and reliable interaction with the user during use. This device is placed on the user with the help of the bearing part, made in the form of a spectacle frame or goggles, which contains lenses to protect the user's eyes from lamp radiation. The possibility of fitting in these embodiments is further improved due to the fact that the walls are rotatable relative to the supporting part, and these supporting parts may contain retractable temporal arches for the possibility of selective adjustment to the size of the user's head. Thus, this device is held on the patient in the form of a worn mask, so that the hands remain free, or a similar device. The power source transmits energy to the lamps and contains an external battery pack, while it may contain a control processor to calculate the number of uses of the device for the user and to indicate the need to replace the device after a given number of uses.
[0010] These embodiments comprise an adjustable / flexible base for providing light-based therapy that easily adapts to the receiving surfaces of the user regardless of size or condition, and phototherapy can be applied without limiting the type of light and without limiting the ultimate goal of treatment, i.e. . beauty, treatment and / or wound healing. Such sources may be different in type of supply of radiated energy. Pulsed light (intense pulsed light, IMS), focused light (lasers) and other ways of using light energy are included in these embodiments. Other methods of light emission may include continuous, pulsed, focused, diffuse radiation, radiation with several wavelengths, radiation with a single wavelength, radiation with wavelengths of light in the visible and / or invisible range.
[0011] This embodiment describes forms such as a shaped / adjustable mask, goggles, a mask for the skin around the eyes, a protective shell or hood, and a face mask (referred to collectively as “mask”) with light emitted from the LEDs lamps or LED strips, which are made with the possibility of fitting to changes in the size of the face or areas intended for therapeutic effects. To change the light intensity, frequency or direction there are control systems.
[0012] The base can be attached to the head by various means: eyeglass frames, straps, drawstrings, straps, Velcro tools, rotary discs or latches and buttons. The mask, when attached, can be fitted vertically to cover from the chin to the forehead. It can also be outwardly adjusted to cover from one side to the other side. In addition, after bending / moving the base to cover the face, the distance from the base to the skin can be adjusted so as to obtain the necessary light intensity relative to the surface of the user's skin. Thus, phototherapy can be maximized up to three physical measurements.
[0013] This fitting opportunity can be realized through intelligent processing systems and sensor systems to improve flexibility / fit in the form of controlled output energy, adjustable wavelengths, priority zones, timers, and so on. Sensors of sensor systems provide the opportunity to evaluate the data on the execution of the skin of the face and body of the patient using sensors of color, wrinkles, age spots, acne, density of damage, and so on, as well as for planning processing using intelligent means, using more or less energy on priority areas. The proposed embodiments may be intelligent in terms of skin type, age, general severity of problems and, accordingly, may be able to perform appropriate individual processing.
[0014] In yet another embodiment, the lamps are integrated into a flexible web of moldable material and formed integrally into strips within the web of material.
[0015] Additionally, control systems can measure or count the number of uses of the device, as well as report usage statistics and indicate a replacement period.
[0016] Thus, a fully flexible and customizable LED device is disclosed herein that provides improved usability and improved light scattering.
[0017] FIG. 1 is a perspective view of one embodiment of a therapeutic lamp base containing a wearable mask;
[0018] FIG. 2 is another perspective view of the apparatus shown in FIG. one;
[0019] FIG. 3 is an exploded perspective view of the device of FIG. one;
[0020] FIG. 4 is an exploded perspective view of the device of FIG. 2;
[0021] FIG. 5 is an exploded perspective view of a control device B;
[0022] FIG. 6 is a cross-sectional view of a two-wall structure of the embodiment shown in FIG. 1, in which the inner wall contains light-transmitting holes located on a straight line with LEDs to transmit therapeutic light to the user;
[0023] FIG. 7 is a second sectional view along a vertical center line;
[0024] FIG. 8 is a perspective view of a partial sectional view showing the arrangement of LED lamps disposed in recesses relative to openings of the inner wall;
[0025] FIG. 9 depicts a perspective view of another embodiment in which the power source and control circuits are integral with the mask assembly;
[0026] FIG. 10 is an exploded view of the device of FIG. 9;
[0027] FIG. 11 is an exploded view of another embodiment in which mask walls are spaced apart by a protrusion;
[0028] FIG. 12 shows an embodiment of a package containing the device shown in FIG. one;
[0029] FIG. 13 depicts the “test me” element of the packaging shown in FIG. 11, with which the user can see the trial operation of the device; and
[0030] FIG. 14 depicts a block diagram of a device operation control.
[0031] Embodiments of the invention relate to a phototherapy system comprising methods and devices, preferably comprising a wearable device used with free hands, with an external battery pack providing power to the therapy lamps in the device. The proposed devices have numerous advantages, including a light base, and the specified base and lamps in it can be properly positioned relative to the user during operation without human intervention. That is, the structural components of the device not only support the specified base on the user, but also work as a guide for the appropriate placement of lamps relative to the processed areas of the user. The design of the device eliminates the possibility of user contact with sharp or hot surfaces, since the lamps are placed in a recess relative to the internal reflective surface, which is closest to the treated surface of the patient. Inside the structure of the walls are also enclosed components of the electrical circuit for transmitting electricity to the lamps. The healing light passing through the openings in the wall enters the user, while the lamps and electrical circuits are effectively enclosed inside the structure with spaced walls. The smooth, seamless surface presented in this way to the user and appropriately removed to carry out the necessary therapeutic treatments also provides improved ventilation, so that the user is presented with an aesthetic and attractive surface of the device, which minimizes the discomfort of the user. Other advantages relate to the possibility of fitting the device in the form of a flexible mask, which is formed when installed on the user to fit on the treated surface of the user, for example, the size of the head. Intelligent components not only evaluate the usability of the device, but also can calculate the time of lamp degradation with the ability to tell the user the time to properly replace the lamp. The entire module is purposefully designed with relatively low weight and minimizing components for ease of use and user comfort.
[0032] More specifically, in accordance with FIG. 1-4, the proposed embodiments comprise a base A for lamps and a remote battery pack B. Base A has a wall structure 10 surrounding therapeutic lamps, for example, red and blue LEDs 12, and electrical circuits 14 that supply energy to the lamps through cable 80 and connector 83 from the battery unit B. Other forms of radiation energy may also include fluorescent light sources, lasers, or infrared light sources. The wall structure 10 is mounted on a carrier part 20 connected by snap-on swivel joints 22, which makes it possible to adjust the position of the structure by turning it slightly relative to the carrier part 20. The carrier part 20 also includes protective lenses 24 and a nose bridge 26. Temporal arches 28 can be fixed or extendable, as well as rotatable relative to the bearing part 20, so that the base A can be mounted on the user with holding without using hands due to support on the bridge of the nose with the help of the arch 26 and on the ears with the help of the temporal arches 28.
[0033] FIG. 3, 4, 6, 7, and 8, it can be seen that the wall structure 10 has an outer wall 50 and an inner wall 52. The outer wall is located as far away as possible from the user's surface to be treated, while the inner wall 52 is located close to it. The walls have a concave shape both horizontally and vertically, while they are made of ductile plastic, so that the structure 10 can bend and slightly deform during operation. The specified concavity has a multidimensional parabolic curvature for capturing and reflecting radiation back to the treated areas. It is assumed that this concavity is slightly less than the curvature of the user's head, so that when using the mask should be bent outward, thereby ensuring a tight but comfortable tightening on the user, which ensures that module A is held in position during use. The specified concavity also provides the location of the therapeutic lamps or LEDs 12 in the necessary positions relative to the user. Lamps 12 and electrical circuits 14 are located in the gap 54 between the walls, so that the lamps and electrical circuits are located between the walls to improve safety and convenience. As you can see, the gap decreases from the middle of the device towards the end sections 58, 60, however, where the walls converge together, the module 10 is tightly closed around the end perimeter. Such a tight closure is ensured in general by means of an ultrasonic welding device. Alternatively, local welding points (not shown) can be used to jointly assemble the walls with spaced apart weld points. Thus, the inner and outer masks have different concavity radii, however, they are a one-piece design, as far as the user is concerned. The outer wall 50 generally acts as a support for the lamps 12 and the electrical circuits 14. In FIG. 4 it can be seen that the lamps are placed on the wall 50 in a predetermined manner for irradiating the treated areas that are most susceptible to phototherapy. It is supposed to use a minimum number of 12 lamps, but this amount is sufficient for effective therapy. Alternatively, these lamps can be attached to the inner wall 52. Regardless of which wall supports the lamps, the lamps should be properly positioned on a straight line with the holes 70 and directed to the treated areas.
[0034] Instead of accidentally placing the LEDs, the number of LEDs in this invention in particular is minimized, and they are located relative to the treated areas and the parabolic reflectivity of the wall so as to provide the necessary therapy. More specifically, it can be seen that the individual lamps 12 and their corresponding openings 70 on the inner wall are arranged so as to process the most common areas benefiting from said therapy. These embodiments illustrate a placement configuration effective for treating acne. Naturally, it is assumed that other placement schemes fall under the scope of legal protection of embodiments of this invention. In this case, three LED strips are shown, which generally contain two blue glow bands located above and below the middle red glow band, since these frequencies are most effective for treating acne. Only blue light, only red light, or any other mixed combination of LEDs, or other type of radiation energy can be used in this invention. The configuration shown thus provides an enhanced therapeutic effect on the jaw line, chin, cheeks and forehead, but not on the eyelids. Light sources may include, for example, LEDs, fluorescent light sources, lasers, or infrared radiation devices. Such sources may have a different form of transmission of radiated energy. Light pulses (SI), focused light (lasers), and other methods of converting light energy are included in these embodiments. Other methods of emitting light may include continuous, pulsating, focused, diffuse radiation, radiation with different wavelengths, a specific wavelength, radiation with waves in the visible and / or invisible light range.
[0035] The inner wall 52 has a smooth, seamless reflective surface facing the area to be treated, and also has holes 70 mutually spaced on one straight line relative to the lamps so that the lamps can emit therapeutic light through the holes 70. Accordingly, the LEDs 12 are located in the recess relative to the inner wall 52 to prevent contact with the work surface and to hinder any contact of the user with the lamps themselves. Such a module provides, as a result, a controlled transfer of radiation therapy when a predetermined cone of therapeutic light is applied to the treated area. These holes are placed relative to the desired treated areas, as well as a parabolic wall configuration for uniform distribution of light on the treated area. The combination of an adjustable light cone defined by the locations of the lamps themselves on the base, the internal reflective surface on the inner wall 52 and the adjustable positioning of the module relative to the treated area due to the location of the base relative to the contact areas of the nose and ears, is a module that provides an accurately predicted light distribution configuration (specified light cones based on light source) thereby minimizing the number of lamps 12 that are required imo use for efficient processing.
[0036] In accordance with FIG. 2, 3, and 4, one embodiment comprises a carrier portion essentially representing a spectacle frame as a corresponding support structure for the base 10. It is possible to use interchangeable lenses 24 to adjust the degree of protection provided by the lenses or their respective shape. Although not shown in this document, retractable temporal arches 28 can be extended to better fit the size of the user's head. Molded ear clips can also be made as part of the temporal arches. Alternatively, said arms may include a head strap. Swivel joints 22 provide the ability to rotate the structure with the walls relative to the bearing parts, so that the user can adjust the light intensity relative to the treated area by moving the gaskets closer or further. As noted above, the base 10 is flexible with a concave parabolic curvature, but still with the flexibility. When the carrier portion 10 is mounted on the user, it is positioned so as to increase parabolic curvature of the base to ensure consistency with the size of the user. The control contact points of the rim of the user's glasses may contain a portion of the upper point of the fronto-nasal suture, nose bridge and ears of the user. Alternatively, the supporting part may comprise a construction of goggles and a head strap resting on a portion of the upper point of the fronto-nasal suture.
[0037] In the battery unit B (FIG. 5), supply batteries 81 and a control processing device 82 are electrically connected to the lamps via a wire 80. Although wiring between the connectors 83 and the LED strips 12 is not shown for clarity, at least, it is located between the walls 50, 52. The battery pack contains a two-position switch 84 and a user interface 86. The processing processing unit 82 may include various control systems indicating to the user that the device is used. Such a system may be a counter. The user interface may include a display for various useful information coming to the user from the regulatory systems of the control device, for example, counting the number of use and a message that the device has been used enough times to such an extent that the LEDs themselves are in a deteriorated state and for therapy replacement is recommended.
[0038] The “test me” package, see FIG. 11 and 12, provides a potential user the opportunity to view the indicative use in a packaged form. The proposed embodiments further comprise a packaging unit 210 comprising a device in which a switch S1 (not shown) for operating the lamp module has multi-positional functionality, including normal operation mode, shutdown mode, and “test me” mode. The “test me” mode is available while the lamp module is in the package to show the lamp operation to the user. The package contains a transparent or translucent coating 212 on top of device A. To limit the display time of the lamps in the “test me” mode, for example, to two seconds, a circuit is completed that interrupts the “test me” mode. The time of the normal mode of operation of the lamps, measured by the meter, is isolated from the “test me” mode, so the use of the “test me” mode does not affect the calculation of the dosed use of the device for actual therapy. It is assumed that the time of using the “test me” mode is insignificant relative to the time of dosed use.
[0039] The proposed devices have numerous advantages for the user, offering a worn device used so that the hands remain free, and containing an external battery pack. The specified device is made with the possibility of proper positioning in a relatively automatic manner with minimal human involvement by using user-related control contact points, while, in particular, during use, the device is used so that the hands remain free. There are no sharp or hot surfaces that the user can touch. The user faces a smooth, seamless surface that is appropriately located at a distance from the treatment area to provide improved ventilation and minimal discomfort during processing.
[0040] FIG. 13 is a block diagram of an embodiment of device control. The device shown as operational in FIG. 10, contains two switches S1, S2, at least one of which must be in the closed state to ensure the supply of energy from the power source to the therapy lamps. When the device is in the retail package, the S2 switch, which is a safety switch, is in the open state so that only the “test me” mode is available. After being removed from the package, switch S2 can be closed, while the device can operate in normal operation. Accordingly, after the initial step 100 and in the state in which S2 is open (step 102), for example, when the device is still inside the package, this system remains in standby mode in which a graphical user interface (for example, a liquid crystal display (LCD)) , is in the off state at step 104. If the switch S2 in step 106 remains in the closed state, but the switch S1 in step 108 is in the pressed state (for example, FIG. 12), then at step 110 the device can enter the “test me” mode "In the cat rum LEDs are lit for two seconds and then turned off. This demonstration of the “test me” mode while the device is in the package provides the user with information about the actual work and can help in making a purchase decision or better understand the way the device works. If the device is removed from the package and S2 is in the closed state, the device enters the normal operation mode in step 114, in which the graphical user interface has a liquid crystal display that displays the number of remaining cycles in accordance with the value on the counter. Note that no trial work in the “test me” mode does not affect the value of 134 counters.
[0041] In one embodiment, said device counts backward from 55 to 1, since 55 uses are found to be sufficient to noticeably degrade the efficiency of the LEDs from the maximum operating mode of the LEDs when used as emitting therapeutic lamps. Accordingly, when a user reads device readings, it is immediately known about the number of remaining cycles from the number of uses from 55 to 0 for the permissible and recommended operation of the device. If the display shows a value above 0 and the user is interested in a therapy session, then he needs to turn on the device by pressing the switch S1 in step 120, while the LEDs increase the glow at step 122 for about 1.5 s, and then emit light at step 124 continuously until either the user in step 126 does not want to turn off the device by pressing the switch S1 again, so that in step 128 the LEDs can reduce the glow, or until the session time in step 130 expires, for example, for the remaining until the completion of a radiation time of approximately 10 minutes. After completing the corresponding working time of the therapy session, the LEDs reduce the glow at step 132, while the graphical user interface display decreases the counter by 1 at step 134.
[0042] FIG. 9 and 10 show another embodiment, in which the control device B is excluded, while the energy source and the processing control device are fully installed in the device 90. In this case, the base 20 and the walls 50, 52 remain essentially the same as in the device shown in FIG. 1. However, the energy source, for example, the batteries 92 are placed as part of the temporal temple for glasses, and the electricity from the batteries 92 is fed through wires passing to the LEDs through the hinge points of the carrier part 20 into the gap 54 for final connection to the LEDs. A control device 94 comprising a liquid crystal display 96 is also located behind the reflective wall 52 relative to the user, while the wall 52 may have a relatively small recess (not shown) for the screen 96.
[0043] The embodiment shown in FIG. 9 and 10 is even more compact compared to the embodiment shown in FIG. 1, and thus more free from the use of hands, since it somehow eliminates the need for controlling controller B during operation.
[0044] FIG. 11 shows another embodiment in which the outer wall 50 ’and the inner wall 52’ are not spaced apart by constructing with different curvatures. More specifically, the walls 50 ’, 52’ have the same curvature, however, the inner wall 52 has an indent 300 depending on the perimeter of the wall to form a protrusion extending from the surface of the wall 52 ’to the outer wall 50’ to effectively form a separator between the two walls. In one embodiment, a protrusion 300 with a width of about 8 mm extends continuously along the entire perimeter of the wall 52 ’and has a thickness of about 5 mm to provide the necessary clearance between the inner and outer walls. In this embodiment, the protrusion 300 is part of the inner wall 52 ’, while, as in the previous embodiment, both walls are made of plastic by vacuum molding, PET (polyethylene terephthalate) or PVC (polyvinyl chloride). The module shown in FIG. 11 can be joined by ultrasonic welding, glued or joined by a double-sided adhesive. Alternatively, instead of continuous welding, intermediate welding points (not shown) may be made. As you can see, in this embodiment, there is a different number of LEDs 12 'located opposite the frontal part of the module relative to the user, so that the number of holes 70' and LEDs 12 'is reduced in comparison with the previous embodiment from 18 to 15. Both are effective for performing the necessary treatment, although other components of the module shown in FIG. 11 are substantially the same with the components in the embodiment shown in the previous drawings.
[0045] Another embodiment other than the options shown in FIG. 1 and other drawings, includes the arrangement of a transparent flexible polymer strip (not shown) containing LED lights between the outer wall 50 and the inner wall 52. Such a structure may comprise a polymer film coated with a transparent thin layer of carbon nanotubes with a specific arrangement, which serves to wiring connecting LED lamps. The specified polymer material protects the LEDs from contact with the user. Such protective polymeric materials are available under the trademark Lumisys.
[0046] Another embodiment includes such a transparent flexible polymer strip, on the top of which a reflective film is deposited, containing recesses located opposite the LEDs and allowing the transmission of emitted light through the reflecting region by the method shown in FIG. 4, between the inner wall 52 with the LEDs 12 through the holes 70. This design may also include a flexible outer wall 50 on the other side of the flexible polymer strip to give flexibility to the module with a film reflective coating.
[0047] Another embodiment includes sensors (not shown), such as temperature or radiated energy sensors, located relative to the inner wall 52 for monitoring the radiated energy acting on the user during treatment. If for any reason it is considered that such an effect is inappropriate, then the detection of this discrepancy by the sensors will recognize the control device B and the therapy may be suspended.
[0048] It should be understood that embodiments of the present invention and other features, functions, or alternatives can be combined to provide many other different systems or applications. Specialist in the field of technology can subsequently perform various unforeseen or unforeseen in this document options, modifications, changes or improvements, while it is assumed that they are also subject to the following claims.
1. Device for phototherapy containing
a base for therapeutic lamps, comprising a mask made with concave parabolic curvature and having flexibility, and emitting lamps providing radiated energy with different wavelengths and arranged to transmit radiation energy to the treated area of the user, and also containing an outer wall and an inner wall having a reflective surface facing the patient and holes transmitting radiated radiation energy to the treated area, the inner wall being made on with the possibility of a uniform distribution of the radiated energy on the treated area, and
the bearing part for holding the mask on the user, including lenses for protecting the eyes, and when the device is placed on the user, the parabolic curvature of the mask increases to ensure consistency with the size of the user.
2. The device according to claim 1, in which the lamps are located between the outer and inner walls.
3. The device according to claim 2, in which the lamps are attached to the outer wall.
4. The device according to claim 1, in which the reflective surface of the inner wall is relatively smooth and seamless.
5. The device according to claim 1, in which the supporting part is arranged to place the mask at a distance from the treated area in the required position to obtain the necessary therapeutic treatment.
6. The device according to claim 5, in which the carrier part has contact points for the user, intended for proper positioning of the device.
7. The device according to claim 1, in which the lamps are located in recesses relative to the reflective surface of the inner wall.
8. The device according to claim 1, in which the radiated energy with different wavelengths includes a red glow, a blue glow or infrared light.
9. The device according to claim 1, in which the bearing part contains a spectacle frame.
10. The device according to claim 1, in which the supporting part contains goggles.
11. A device for phototherapy containing
a put-on base for therapeutic lamps, containing emitting lamps that provide radiated energy with different wavelengths, and an inner wall having a reflective surface facing the patient, and openings for radiated energy located on one straight line with the lamps with the possibility of transmitting radiation energy to the treated area user, and the inner wall is made with the possibility of uniform distribution of radiated energy over the treated area, and
bearing part for holding the base on the user.
12. The device according to p. 11, which further comprises an outer wall located at a distance from the inner wall, and the emitting lamps are located between the outer and inner walls.
13. The device according to p. 11, in which the radiated energy with different wavelengths includes a red glow, blue glow or infrared light.
14. The device according to claim 11, in which the reflective surface of the inner wall is smooth and seamless.
15. The device according to p. 14, in which the inner wall is made with parabolic curvature for uniform distribution of radiated energy over the treated area of the user.
16. The device according to p. 11, in which the bearing part contains a spectacle frame.
17. The device according to claim 16, wherein said eyeglass frame contains lenses for protecting the eyes.
RU2014110105A 2011-09-08 2012-09-06 Light therapy platform system RU2613607C2 (en)
RU2014110105A RU2014110105A (en) 2015-10-20
RU2613607C2 true RU2613607C2 (en) 2017-03-17
ES (2) ES2725605T3 (en)
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2016-06-20 HZ9A Changing address for correspondence with an applicant