WO2016197951A1 - Phototherapeutic device - Google Patents

Abstract

Disclosed is a phototherapeutic device (100, 200, 300, 400, 600, 700, 800, 900), including a flexible base (110, 210, 470, 640, 710, 810, 910), a printed circuit board (130, 240, 420), a conductive electrode group (140, 421), a power supply unit (150, 230, 430, 620, 720, 820, 920), a light-emitting unit (160, 220, 422, 630, 730, 830, 930) and a top cover (170, 440, 610). The printed circuit board (130, 240, 420) is arranged above the flexible base (110, 210, 470, 640, 710, 810, 910), and the printed circuit board (130, 240, 420) includes a drive circuit. The conductive electrode group (140, 421) is assembled on the printed circuit board (130, 240, 420), and the conductive electrode group (140, 421) includes a positive contact (140a, 421a) and a negative contact (140b, 421b). The power supply unit (150, 230, 430, 620, 720, 820, 920) is arranged above the conductive electrode group (140, 421), and the power supply unit (150, 230, 430, 620, 720, 820, 920) includes a positive contact (150a, 430a, 620a, 730a, 820a, 920a) and a negative contact (150b, 430b, 620b, 730b, 820b, 920b). The light-emitting unit (160, 220, 422, 630, 730, 830, 930) is arranged between the printed circuit board (130, 240, 420) and the flexible base (110, 210, 470, 640, 710, 810, 910), and the light-emitting unit (160, 220, 422, 630, 730, 830, 930) is electrically connected to the power supply unit (150, 230, 430, 620, 720, 820, 920) and the drive circuit. The top cover (170, 440, 610) is arranged above the power supply unit (150, 230, 430, 620, 720, 820, 920) and covers the power supply unit (150, 230, 430, 620, 720, 820, 920), the conductive electrode group (140, 421), the printed circuit board (130, 240, 420) and the light-emitting unit (160, 220, 422, 630, 730, 830, 930). The positive contact (140a, 421a) and the negative contact (140b, 421b) of the conductive electrode group (140, 421) are in constant contact with the positive contact (150a, 430a, 620a, 730a, 820a, 920a) and the negative contact (150b, 430b, 620b, 730b, 820b, 920b) of the power supply unit (150, 230, 430, 620, 720, 820, 920), and the top cover (170, 440, 610) can press down the power supply unit (150, 230, 430, 620, 720, 820, 920) when being pressed. The phototherapeutic device is light and thin in volume and simple in structure, and can be carried about for use.

Description

Phototherapy device Technical field

The invention discloses a phototherapy device, and in particular relates to a phototherapy device which is light and thin, portable, easy to operate and can be attached to any human skin surface for emitting light therapy of different wavelengths of light to acupuncture points of a human body.

Background technique

Acupuncture is a therapy based on stimulation of acupuncture points in the human body to relieve pain. Traditional acupuncture uses instruments (such as metal needles) to be inserted into the acupoints of the body's meridian system to clear the gas or blood in the meridian system, thereby reducing blood and blood blockage and restoring the meridian system to normal.

The aforementioned acupuncture has a certain degree of danger, so the practitioner must undergo strict professional training, which is not for everyone. Furthermore, side effects such as fainting or wound infections often occur unexpectedly.

Therapies that have recently replaced the needle with light to stimulate the acupuncture point have increased rapidly. Phototherapy uses light to illuminate human skin to induce a series of biochemical reactions, which in turn achieves the effects of acupuncture and moxibustion.

However, the current phototherapy device structure is too complicated and bulky, and it is inconvenient to use and cannot be carried around. For example, there is a type of box type phototherapy device in which a user enters to receive whole body light treatment, but since it is bulky, it needs to be placed at a specific place and cannot move freely. Another relatively small phototherapy device has been developed to address the aforementioned convenience issues. However, its operation is complicated, and the size is small, and the thickness of the small-scale phototherapy device on the market cannot be truly portable and easy to use.

For this reason, there is still an urgent need to develop a small phototherapy device that is easy to use, easy to carry and safe.

Summary of the invention

In particular, it is an object of the present invention to provide a phototherapy device that can emit light to illuminate human skin in a simple manner such as pressing, rotating or folding. The phototherapy device of the invention has a compact structure, a light volume and a flexibility, and is quite suitable for being carried and used in various parts of the human body. Furthermore, the flexibility of the application can be increased by different illuminating bands, and it has a wide range of applications.

To achieve the above object, in one embodiment, a phototherapy apparatus is provided that includes a flexible base, a printed circuit board, a conductive electrode set, a power supply unit, a light emitting unit, and an upper cover. The printed circuit board is disposed above the flexible base and includes a drive circuit. The conductive electrode set is combined on a printed circuit board and includes a positive electrode contact and a negative electrode contact. The power supply unit is disposed above the conductive electrode group and includes a positive electrode contact and a negative electrode contact. The light emitting unit is disposed between the printed circuit board and the flexible base, and the light emitting unit is electrically connected to the power supply unit and the driving circuit. The upper cover is disposed above the power supply unit and covers the power supply unit, the conductive electrode group, the printed circuit board, and the light emitting unit. Wherein, the positive electrode contact and the negative electrode contact of the conductive electrode group are in constant contact with the positive electrode contact and the negative electrode contact of the power supply unit, and the upper cover is pressed to press down the power supply unit, so that the power supply unit presses the conductive electrode group to make the negative electrode contact of the conductive electrode group contact. A conductive line on the printed circuit board provides a signal to the drive circuit and drives the light unit to emit light toward the flexible base through the drive circuit.

The above phototherapy device further includes a fixing member. The fixture is located on the flexible base and is combined with the upper cover. The accommodating space is formed in the fixing member, and the power supply unit, the conductive electrode group, the printed circuit board and the illuminating unit are accommodated in the accommodating space.

In the phototherapy apparatus described above, the flexible base and the upper cover may be combined with each other by silicone infusion or by attaching the upper cover to the flexible base. The fixing member and the flexible base can also be integrally formed.

In the above phototherapy device, the upper cover can be made of a flexible material. The flexible base can extend outwardly from an extension. The shape of the extension may be linear, cross, Y-shaped, butterfly-wing or irregular. The power supply unit is a rechargeable battery, and the type thereof may be a thin film battery, a fuel battery, or a button battery.

In the above phototherapy device, the flexible base comprises a bottom surface, and the bottom surface defines a plurality of light-transmissive holes for the light emitted by the light-emitting unit to penetrate. The illuminating band of light can be from 610 nm to 650 nm. Segment, orange light band from 600 nm to 620 nm, yellow band from 580 nm to 600 nm, green band from 495 nm to 560 nm, blue band from 450 nm to 495 nm, and twilight band from 410 nm to 450 nm , 395 nm to 475 nm violet band, 650 nm to 1000 nm infrared band or greater than 1350 nm far infrared band.

In the above phototherapy device, the light emitting unit may be an inorganic light emitting diode or an organic light emitting diode. The number of light emitting units may be one or more.

In the above phototherapy device, the printed circuit board is provided with a plurality of embedded holes, the positive electrode contact and the negative electrode contact of the conductive electrode group, and the positive electrode contact and the negative electrode contact of the power supply unit are embedded in the embedded hole, so as to make the conductive electrode group and the power supply unit Fixed to the printed circuit board.

In one embodiment, the phototherapy apparatus provided by the present invention comprises a flexible base, a light emitting unit, a power supply unit, a printed circuit board, and a switch body. The light emitting unit is disposed above the flexible base; the power supply unit is disposed above the light emitting unit, and the power supply unit is electrically connected to the light emitting unit; the printed circuit board is disposed above the power supply unit, and the wireless charging system and the switch control circuit are disposed on the printed circuit board, and the wireless The charging system and the switch control circuit are electrically connected to the power supply unit individually; the switch body is disposed above the printed circuit board, and the switch body is electrically connected to the switch control circuit. The power supply unit is wirelessly charged by the wireless charging system, and the power supply unit supplies the required power to the light emitting unit and the switch control circuit, and the switch body controls the light emitting intensity and the light emitting band of the light emitting unit through the switch control circuit.

In the above phototherapy device, the light emitting unit may be an organic light emitting diode or an inorganic light emitting diode. The power supply unit can be a thin film rechargeable battery.

In the above phototherapy apparatus, the wireless charging system includes a wireless charging receiving unit and a charging circuit. The charging circuit is electrically connected to the wireless charging receiving unit and the power supply unit. The wireless charging receiving portion includes an induction coil. The induction coil is electromagnetically induced by the main coil of the external charging device to generate an inductance, and converts the electric energy to wirelessly charge the power supply unit through the charging circuit.

In the above phototherapy apparatus, the switch body includes a magnetic isolation sheet, a control circuit layer, a pad layer, and a panel layer. The magnetic isolation plate is disposed on the printed circuit board; the control circuit layer is disposed on the magnetic isolation plate, and the control circuit layer is electrically connected to the switch control circuit on the printed circuit board; the rubber layer is disposed on the control circuit layer The panel layer is disposed on the rubber layer, and the panel layer comprises a plurality of buttons. After pressing, the buttons are electrically connected to the control circuit layer and the switch control circuit, thereby switching the illumination intensity or the illumination band of the illumination unit.

In the above phototherapy apparatus, the switch control circuit includes an inductive receiving unit. The sensing receiving unit is a sound sensor, a pressure sensor, a light sensor or a gravity sensor (G-sensor).

The phototherapy device described above further includes a sealing member made of a waterproof oxygen material for coating the phototherapy device. The seal is transparent. A light-transmitting region may be formed in the sealing member for the light emitted by the light-emitting unit to penetrate. The seal can be added with a hygroscopic material.

In one embodiment, a phototherapy apparatus according to the present invention includes: a base including a bottom surface and a first chamber formed therein; the printed circuit board is mounted in the first chamber, and the printed circuit board includes a light emitting unit and Electrically connecting the conductive electrode group of the light emitting unit, wherein the light emitting unit emits light toward the bottom surface; the power supply unit is configured to electrically connect the conductive electrode group; and the upper cover has a second chamber formed therein for the power supply unit to be placed, the upper cover The second chamber is eccentrically rotated relative to the first chamber to drive the power supply unit to rotate eccentrically to switch whether the power supply unit and the conductive electrode group are turned on or not, thereby switching whether the light emitting unit emits light or not.

In the above phototherapy device, a light transmission hole may be opened in the bottom surface, so that the light emitted by the light emitting unit passes through the light transmission hole.

In the above phototherapy apparatus, the printed circuit board includes a driving circuit electrically connected to the conductive electrode group, and the light emitting unit is driven by the driving circuit to switch the light emitting mode of the light emitting unit.

In the above-described phototherapy apparatus, a fitting groove is provided in the base, and a fitting rail is provided on the lid body, and the fitting rail is rotatably fitted to the fitting groove. Barbs are formed on the fitting rails, so that the upper cover cannot be detached and separated after being fitted to the base.

In the above phototherapy device, the base further includes a plurality of open card slots, and the upper cover includes a plurality of engaging portions corresponding to the card slots. After the upper cover and the base are fitted, the card slots and the engaging portions can be adopted. The upper cover and the base are detachably separated.

In the above phototherapy device, the conductive electrode group includes a positive electrode contact and a negative electrode contact, and the power supply list The element includes a positive contact and a negative contact; the power supply unit is eccentrically rotated, so that the positive contact of the power supply unit selectively contacts the positive contact of the conductive electrode group, and the negative contact of the power supply unit constantly contacts the negative contact of the conductive electrode set. The positive electrode contact of the conductive electrode group may be columnar.

The phototherapy device further includes a flexible base, the base is fixed on the flexible base, and the flexible base extends outwardly to an extension.

In the above phototherapy device, the printed circuit board may include a plurality of light emitting units, and the second chamber is eccentrically rotated relative to the first chamber to drive the power supply unit to rotate eccentrically to switch whether the power supply unit and the conductive electrode group are turned on or not, thereby switching the current The light emitting units emit light in sequence.

In the above phototherapy device, the conductive electrode group includes a plurality of positive electrode contacts and a negative electrode contact, and the power supply unit includes a positive electrode contact and a negative electrode contact; the power supply unit rotates eccentrically, so that the positive electrode contacts of the power supply unit selectively contact the positive electrodes of the conductive electrode group in sequence At the contact point, the negative contact of the power supply unit constantly contacts the negative contact of the conductive electrode group.

In the above phototherapy device, the light-emitting units sequentially switch to emit the same or different color lights.

In one embodiment, a phototherapy apparatus according to the present invention includes: a power supply unit including a positive electrode contact and a negative electrode contact; and a light emitting unit including a positive electrode contact and a negative electrode contact. One of the positive pole contact or the negative pole contact of the light emitting unit is constantly conducting with one of the positive pole contact or the negative pole contact corresponding to the power supply unit; and the other positive contact or the negative contact of the light emitting unit is switchable by the magnetic unit The power supply unit is adsorbed or not adsorbed, and then the other positive pole contact or the negative pole contact in the power supply unit is selected to be turned on or off, thereby switching the illumination unit to emit light or not.

In one embodiment, the present invention provides a phototherapy apparatus comprising: an upper cover having an inner surface therein, and a conductive electrode disposed on a side of the upper cover; the power supply unit is disposed on the inner surface, and the left and right sides of the power supply unit respectively include The positive electrode contact and the negative contact; and the light emitting unit is disposed on the power supply unit, wherein the light emitting unit comprises a positive contact and a negative contact; wherein the negative contact of the power supply unit and the negative contact of the light emitting unit are constantly conducting, and the positive contact of the power supply unit is extended to connect the conductive electrode; The positive electrode contact of the light-emitting unit can be freely flexed to extend or not contact the conductive electrode, thereby conducting or not conducting The positive electrode contact of the electric unit and the positive electrode of the light emitting unit are used to switch the light emitting unit to emit light or not to emit light.

In the above phototherapy apparatus, the light emitting unit and the power supply unit have a sheet shape.

The phototherapy device may further include a flexible base, and the flexible base covers the upper cover to cover the light emitting unit and the power supply unit.

In one embodiment, a phototherapy apparatus provided by the present invention comprises: a flexible base; the power supply unit is disposed on the flexible base, and the positive pole contact and the negative pole joint are respectively extended on the left and right sides of the power supply unit; and the light emitting unit is disposed in the power supply unit On the left and right sides of the light emitting unit, the positive electrode contact and the negative electrode contact are respectively extended; wherein the negative electrode contact of the power supply unit is always electrically connected to the negative electrode contact of the light emitting unit, and the positive electrode contact of the light emitting unit can be flexed to be turned on or not to be turned on. The positive electrode contact is used to switch the light emitting unit to emit light or not to emit light.

In the above phototherapy apparatus, a magnetic adsorption sheet is disposed on a side of the power supply unit, and a magnetic unit is disposed on a side of the light-emitting unit, and a positive electrode contact of the light-emitting unit contacts a positive electrode contact of the power supply unit through the magnetic unit to turn on a positive electrode contact of the power supply unit and The positive contact of the light unit.

In one embodiment, the present invention provides a phototherapy apparatus comprising: a flexible base comprising a first region and a second region; the power supply unit is disposed in the first region, and the power supply unit side extends the positive contact and the negative electrode respectively The light emitting unit is disposed in the second area, and one side of the light emitting unit extends the positive electrode contact and the negative electrode contact respectively; wherein the positive electrode contact of the power supply unit and the positive electrode contact of the light emitting unit are constantly turned on, and the negative electrode contact of the power supply unit and the negative electrode of the light emitting unit The contact is not turned on when the first region and the second region are unfolded, and is turned on after the first region and the second region are relatively folded, thereby switching the light emitting unit to emit light or not.

In the phototherapy apparatus described above, a magnetic adsorption sheet is provided on one surface of the power supply unit, and a magnetic unit is provided on one surface of the light-emitting unit to closely adsorb the first region and the second region when folded. In the magnetic unit, a light-transmitting area can be opened for the light emitted by the light-emitting unit to penetrate.

In one embodiment, the present invention provides a phototherapy apparatus comprising: a flexible base comprising a first surface and a second surface on the opposite side; and a power supply unit, the power supply unit side extending the positive contact and the negative contact respectively; The light emitting unit is disposed between the power supply unit and the first surface, and one side of the light emitting unit Extending the positive contact and the negative contact respectively, the light emitted by the light emitting unit penetrates the first surface and the second surface; and the conductive portion extends from the first surface of the flexible base to be flexible; wherein the negative contact of the power supply unit The negative electrode contact of the light-emitting unit is constantly turned on, and the positive electrode contact of the power supply unit and the positive electrode contact of the light-emitting unit are turned on when the conductive portion is flexed, and are not turned on when the conductive portion is flattened, thereby switching the light-emitting unit to emit light or not.

In the phototherapy apparatus described above, a magnetic unit is provided on the second surface of the flexible base to be adsorbed when the conductive portion is flexed. A light transmitting region is opened in the magnetic unit for the light emitted by the light emitting unit to penetrate.

Compared with the prior art, the present invention has the following beneficial effects: the phototherapy device of the present invention can be used in a simple manner such as pressing, rotating or folding, so that the light emitting unit can emit light to illuminate the human skin, and has a compact structure, a thin volume, and Flexible, it is quite suitable for carrying around the body. Furthermore, the flexibility of the application can be increased by different illuminating bands, and it has a wide range of applications.

DRAWINGS

1 is an exploded perspective view showing a phototherapy apparatus according to an embodiment of the present invention;

Figure 2 is a schematic view showing the components of the phototherapy device in Figure 1;

Figure 3 is a schematic view showing the components of another part of the phototherapy apparatus of Figure 1;

Figure 4 is a schematic view showing the appearance of the phototherapy device in Figure 1;

FIG. 5A is a view showing a first use state of the phototherapy apparatus of FIG. 4; FIG.

FIG. 5B is a second use state diagram of the phototherapy device of FIG. 4; FIG.

Figure 6 is a partial structural schematic view showing another embodiment of the phototherapy apparatus of Figure 1;

Figure 7 is a perspective view showing a portion of the appearance of the phototherapy device of Figure 6;

Figure 8 is a perspective view showing a side portion of the phototherapy device of Figure 7;

Figure 9 is a schematic view showing the appearance of the phototherapy device of Figure 6;

Figure 10 is a schematic view showing the appearance of the flexible base of the phototherapy device in the form of a butterfly wing;

FIG. 11 is an exploded perspective view of a phototherapy apparatus according to an embodiment of the invention; FIG.

Figure 12 is a schematic exploded view of the switch body of Figure 11;

Figure 13 is a schematic view showing another embodiment of the phototherapy apparatus of Figure 11;

FIG. 14 is a schematic diagram showing another embodiment of wireless charging in FIG. 11; FIG.

FIG. 15A is a schematic view of a phototherapy apparatus according to an embodiment of the invention; FIG.

Figure 15B is a schematic view showing another embodiment of the phototherapy apparatus according to Figure 15A;

FIG. 16 is a schematic view showing a state in which a phototherapy apparatus according to an embodiment of the present invention is in a flexible state; FIG.

17 is a schematic view showing an application example of the phototherapy apparatus of the present invention;

18 is a schematic view showing another application example of the phototherapy apparatus of the present invention;

FIG. 19 is an exploded perspective view of a phototherapy apparatus according to an embodiment of the invention; FIG.

Figure 20 is a schematic view showing the combination of the phototherapy apparatus of Figure 19;

Figure 21 is a cross-sectional view showing the phototherapy apparatus of Figure 19;

22A is a schematic view showing the state in which the power supply unit and the conductive electrode group of the phototherapy apparatus are not turned on;

22B is a schematic view showing a state in which the power supply unit and the conductive electrode group of the phototherapy apparatus are turned on;

23A is a schematic structural view of a phototherapy apparatus according to an embodiment of the present invention;

23B is a schematic view showing the combination of the housing and the base of FIG. 23A;

Figure 24 is a view showing an embodiment of another shape of the circuit board of the present invention;

25A is a schematic diagram showing a closed state when a plurality of light emitting units are used in the present invention;

25B is a schematic view showing a first light-emitting state when a plurality of light-emitting units are used in the present invention;

25C is a schematic view showing another closed state when the present invention uses a plurality of light emitting units;

25D is a schematic diagram showing a second illumination state when the plurality of illumination units are used in the present invention;

Figure 26A is a first state diagram showing the use of wireless charging of the phototherapy device of the present invention;

26B is a second state diagram showing the use of wireless charging of the phototherapy apparatus of the present invention;

Figure 27 is a schematic view showing an application example of the phototherapy device of the present invention;

28A is a cross-sectional view showing a phototherapy apparatus according to an embodiment of the present invention;

28B is a schematic view showing an embodiment of the light emitting unit of FIG. 28A;

Figure 29A is a cross-sectional view showing a phototherapy apparatus according to an embodiment of the present invention;

Figure 29B is a cross-sectional view showing another example of the phototherapy device of Figure 29A;

Figure 30 is a cross-sectional view showing a phototherapy apparatus according to an embodiment of the present invention;

Figure 31 is a cross-sectional view showing a phototherapy apparatus in accordance with an embodiment of the present invention.

detailed description

Various embodiments of the present invention will be described below with reference to the drawings. For the sake of clarity, many practical details will be explained in the following description. However, it should be understood that these practical details are not intended to limit the invention. That is, in some embodiments of the invention, these practical details are not necessary. In addition, some of the conventional structures and elements of the prior art are illustrated in the drawings in a simplified schematic manner.

1 to FIG. 4, FIG. 1 is a structural exploded view of a phototherapy device 100 according to an embodiment of the present invention; FIG. 2 is a schematic view showing a combination of components of the phototherapy device 100 of FIG. 1 is a schematic view showing another component combination of the phototherapy device 100; FIG. 4 is a schematic view showing the appearance of the phototherapy device 100 in FIG.

The phototherapy device 100 basically includes a flexible base 110, a fixture 120, a printed circuit board 130, a conductive electrode group 140, a power supply unit 150, a light emitting unit 160, and an upper cover 170.

The fixture 120 is combined with the flexible base 110. Basically, the fixing member 120 has a hollow ring shape and defines an accommodation space 120a therein.

After the fixing member 120 is combined with the flexible base 110, the printed circuit board 130 is received in the accommodating space 120a of the fixing member 120. The printed circuit board 130 has a drive circuit (not shown).

The conductive electrode group 140 is combined on the printed circuit board 130. The conductive electrode group 140 has a positive electrode contact 140a and a negative electrode contact 140b.

After the fixing member 120 is combined with the flexible base 110, the power supply unit 150 is received in the accommodating space 120a of the fixing member 120. The power supply unit 150 also has a positive contact 150a and a negative contact 150b.

The light emitting unit 160 is combined between the flexible base 110 and the printed circuit board 130, and can be combined on the flexible base 110 or the printed circuit board 130 according to actual application conditions, and electrically connected to the power supply unit 150 and the driving circuit (figure Not shown).

The upper cover 170 is combined with the fixing member 120. After being assembled, the upper cover 170 may cover the accommodating space 120a of the fixing member 120 and form a closed structure.

The combination of the phototherapy apparatus 100 is illustrated in FIGS. 2 and 3. For example, in FIG. 2, when the phototherapy device 100 is combined, the fixing member 120 is first combined in the susceptor 110, and then the printed circuit board 130 is received in the accommodating space 120a of the fixing member 120, and then the conductive electrode group 140 is combined. On the printed circuit board 130. The fixing member 120 can be fixed to the base 110 in any manner. One way, for example, the groove 110a is formed on the base 110, and the fixing member 120 is embedded in the groove 110a.

In FIG. 3, after the combination of the susceptor 110, the fixing member 120, the printed circuit board 130, and the conductive electrode group 140 is completed, the power supply unit 150 is also accommodated in the accommodating space 120a of the fixing member 120, and then the upper cover 170 is Covered by the fixing member 120. After the upper cover 170 is combined with the fixing member 120, the accommodating space 120a of the fixing member 120 can be covered, and the fixing member 120 forms a closed structure. Thereby, the printed circuit board 130, the conductive electrode group 140, the power supply unit 150, the light-emitting unit 160, and the like housed in the accommodating space 120a are protected.

The upper cover 170 is used to control the illumination of the light-emitting unit 160 in addition to providing protection.

Please refer to FIG. 5A and FIG. 5B. FIG. 5A is a first use state diagram of the phototherapy device 100 of FIG. 4; FIG. 5B is a second use state diagram of the phototherapy device 100 of FIG. The positive electrode contact 140a and the negative electrode contact 140b of the conductive electrode group 140 are in constant contact with the positive electrode contact 150a and the negative electrode contact 150b of the power supply unit 150. The upper cover 170 can be made of a flexible and insulating material and can be pressed. After the upper cover 170 is pressed, the power supply unit 150 is pressed to press the negative electrode contact 140b of the conductive electrode group 140 to contact the conductive line (not shown) of the printed circuit board 130, thereby forming an on-circuit path and providing a signal to a driving circuit that causes the driving circuit to drive the light emitting unit 160 toward the flexible base 110 Light is emitted. The driving circuit can also control the light emitting band and the light emitting intensity of the light emitted by the light emitting unit 160.

In practical application, the power supply unit 150 may be a rechargeable battery, which may be a thin film battery, a fuel battery or a button battery.

The flexible base 110 includes a bottom surface 110b, and a plurality of light-transmissive holes 110c are formed therein for the light emitted by the light-emitting unit 160 to penetrate. The light emitted by the light emitting unit 160 can have a plurality of light emitting bands to achieve different application effects. For example, the illuminating band may be a red band of 610 nm to 650 nm, an orange band of 600 nm to 620 nm, a yellow band of 580 nm to 600 nm, a green band of 495 nm to 560 nm, and 450 nm. The blue light band of 495 nm, the xenon band of 410 nm to 450 nm, the violet band of 395 nm to 475 nm, the infrared band of 650 nm to 1000 nm or the far infrared band of more than 1350 nm. In various embodiments, the light emitting unit 160 can be an inorganic light emitting diode or an organic light emitting diode to be applied to various different conditions.

The flexible base 110 extends outwardly with an extension 111. The shape of the extension 111 can vary depending on the skin. The extension portion 111 may have a line shape, a cross shape, a Y shape, a butterfly wing shape, or an irregular shape.

In some embodiments, the structure of the phototherapy device 100 described above can be further simplified to achieve a slimmer size and a wider range of applications. Details are given in the following examples.

Please refer to FIG. 6 to FIG. 9 again. 6 is a partial schematic structural view of another embodiment of the phototherapy device 100 of FIG. 1; FIG. 7 is a perspective view showing the appearance of the phototherapy device 100 in FIG. 6; FIG. A side view of a side view of the phototherapy device 100; FIG. 9 is a schematic view showing the appearance of the phototherapy device 100 of FIG.

The fixing member 120 in the foregoing FIG. 1 is originally used for fixing components such as the printed circuit board 130 and the power supply unit 160. The arrangement of the fixture 120 is omitted in the phototherapy apparatus 100 of FIGS. 6 to 9. In one example, the flexible base 110 and the upper cover 170 of the phototherapy device 100 of FIGS. 6 to 9 can be integrally formed by silicone gel perfusion sealing or the upper cover 170 and the flexible base 110; In this case, the fixing member 120 and the flexible base 110 can also be integrally formed to form a desired structure. In 6, the printed circuit board 130 is provided with a plurality of through holes 130a, the positive electrode contact 140a and the negative electrode contact 140b of the conductive electrode group 140, and the positive electrode contact 150a and the negative electrode contact 150b of the power supply unit 150 are embedded and soldered in the through hole 130a. In order to fix the conductive electrode group 140 and the power supply unit 150 to the printed circuit board 130. Moreover, the positive electrode contact 150a and the negative electrode contact 150b of the power supply unit 150 are directly soldered to the corresponding positions of the positive electrode and the negative electrode of the conductive line (not shown) of the printed circuit board 130. After directly contacting the negative electrode 140b of the conductive electrode group 140 to contact the negative electrode of the conductive circuit (not shown) of the printed circuit board 130, a path on the circuit can be formed, and a signal can be sent to the driving circuit on the brush circuit board 130. The light emitting unit 160 is driven to emit light. Thereby, omitting the arrangement of the fixing member 120 can achieve a thinner and lighter size, and the convenience in use and the range of application are increased.

Please continue to refer to Figure 10. FIG. 10 is a schematic view showing the flexible base 110 of the phototherapy apparatus 100 in the shape of a butterfly wing in FIG. The appearance of the flexible base 110 can have a variety of implementations, thereby corresponding to different part shapes of the human body. In Fig. 10, the extension 111 of the flexible base 110 has a symmetrical butterfly wing shape. Thereby, the surface of the human skin can be more closely attached, so that the light emitted by the light-emitting unit 160 can more accurately illuminate the corresponding human skin acupuncture points.

An embodiment in which the above-described upper cover 170 of the phototherapy apparatus 100 is applied with a membrane switch will be described.

Please refer to FIG. 11 and FIG. 12 at the same time. 11 is an exploded perspective view of a light therapy device 200 according to an embodiment of the invention; and FIG. 12 is an exploded perspective view of the switch body 250 of FIG.

The phototherapy device 200 includes a flexible base 210, a light emitting unit 220, a power supply unit 230, a printed circuit board 240, and a switch body 250.

In this embodiment, the light emitting unit 220 is disposed on the flexible base 210. The light emitting unit 220 may use an inorganic light emitting diode or an organic light emitting diode.

The power supply unit 230 is disposed on the light emitting unit 220, and is electrically connected to the light emitting unit 220 and provides required power to the light emitting unit 120.

The printed circuit board 240 is disposed on the light emitting unit 220, and is provided with a wireless charging system 241 and a switch control circuit 242. The switch control circuit 242 is electrically connected to the power supply unit 230 to obtain the required power. The wireless charging system 241 is also electrically connected to the power supply unit 230 for the power supply list. Element 230 performs wireless charging. In one example, the power supply unit 230 is a thin film type rechargeable battery.

The switch body 250 is disposed on the printed circuit board 240 and electrically connected to the switch control circuit 242. The switch body 250 can control the light-emitting characteristics such as the light-emitting intensity or the light-emitting band of the light-emitting unit 220 through the switch control circuit 242.

The detailed structure of the switch body 250 described above is shown in FIG. The switch body 250 includes a magnetic isolation sheet 251, a control circuit layer 252, a pad layer 253, and a panel layer 254.

The magnetic isolation plate 251 is disposed on the printed circuit board 240, and may be made of a PET material with a high magnetic permeability material, and functions to separate the control circuit layer 252 and the printed circuit board 240. In general, the aforementioned wireless charging system 241 is also often provided with a structure similar to the magnetic isolation sheet 251, which functions to prevent electromagnetic interference. In the present invention, the same magnetic isolation sheet 251 is used as a magnetic isolation element for the control circuit layer 252 of the separation switch body 250, the printed circuit board 240, and the wireless charging system 241, whereby the phototherapy apparatus 200 of the present invention is structurally constructed. It is more highly integrated and can be used to streamline components.

The control circuit layer 252 is disposed on the magnetic isolation sheet 251. The light-emitting unit 220 is activated or controlled by electrically connecting the control circuit layer 252 to the switch control circuit 240 on the double-sided printed circuit board 240 by a pressing action.

The pad layer 253 is disposed on the control circuit layer 252.

The panel layer 242 is disposed on the pad layer 253. The panel layer 254 is provided with a plurality of buttons 254a. The control circuit layer 252 and the switch control circuit 242 can be electrically connected by pressing the buttons 254a to control the light-emitting intensity or the light-emitting band of the light-emitting unit 220. More specifically, the plurality of buttons 254a respectively correspond to different functions, and metal contacts (not shown) are disposed under the buttons 254a, electrically connected to the control circuit layer 252 through the metal contacts, and the control circuit layer 252 is further controlled by the switch. Circuit 242 is electrically connected. When the corresponding function button 254a is pressed, the control unit layer 152 and the switch control circuit 242 cooperate to control the light-emitting unit 220 to emit different light intensities or light-emitting bands.

An example of the wireless charging system 241 is shown in FIG. The wireless charging system 241 basically includes a wireless charging receiving unit 241a and a charging circuit 241b. The charging circuit 241b is electrically connected to the wireless charging connection The receiving unit 241a and the power supply unit 230. The basic wireless charging operation principle is provided, and the wireless charging receiving unit 241a is provided with an induction coil. In one example, the induction coil can be a printed induction coil for thinning requirements. At the time of charging, the main coil of the external charging device is electromagnetically induced to generate an inductance, and the electric energy is converted to wirelessly charge the power supply unit 230 through the charging circuit 241b.

Please refer to FIG. 13, which is a schematic diagram of another embodiment of the phototherapy device 200 of FIG. The switch body 250 described above controls the switch of the light-emitting unit 220 and switches the light-emitting mode by pressing. In Fig. 13, another possible example of controlling the light emitting unit 220 is illustrated. An inductive receiving unit 242a may be disposed on the switch control circuit 242, which may be a sound sensor, a pressure sensor, a light sensor, or a gravity sensor (G-sensor). Thereby, the switch of the light-emitting unit 220 and the switching of the light-emitting mode can be controlled in various non-contact manners. At this time, the switch body 250 does not need to have a multi-layer structure as in the foregoing embodiment, and only a single layer of soft film can be used, thereby making the overall phototherapy device 200 lighter and thinner, and the surface is more flat. Thereby, the phototherapy device 200 of the present invention can control the switching of the light-emitting unit 220 and switch the light-emitting mode by providing various forms such as a membrane switch or an inductive switch, thereby increasing the convenience in use.

Based on the development of current wireless charging technologies, the wireless charging system 241 of the present invention has different implementations to meet various needs. Please refer to FIG. 14. FIG. 14 is a schematic diagram showing another embodiment of the wireless charging system 241 of FIG.

In FIG. 14, the wireless charging receiving unit 241a and the charging circuit 241b are replaced with a wireless charging receiving wafer 241c and a charging wafer 241d. The wireless charging receiving wafer 241c can use, for example, a wireless charging receiving chip of the model number bq51003 of the German company; and the charging chip 241d can be used with a charging chip of the model bq500210 such as Texas Instruments. With the above two highly integrated wafers, the complicated circuit process of the original wireless charging receiving portion 241a and the charging circuit 241b can be simplified, and the phototherapy device 200 of the present invention can be more compact and easy to use.

In the phototherapy apparatus 200 described above, the base of the flexible base 210 as a whole is directly omitted, the existing switch part components are omitted, and the wireless charging system 241 and the switch control circuit 242 required for the existing switch are directly integrated into the printed circuit board. 240 on. Thereby, the switch body 250 is highly integrated, The power supply unit 230, the wireless charging system 241, and the light emitting unit 220 form a thin phototherapy device 200. In these phototherapy devices 200, all components and circuitry are completely sealed and integrated into the overall structure, and the power supply unit 230 can also be wirelessly charged without an exposed power connector. Therefore, having a good waterproof oxygen and moisture-proof effect makes the phototherapy apparatus 200 of the present invention more durable and longer in life.

In order to increase the waterproof oxygen and moisture effects, please refer to FIG. 15A and FIG. 15B together. 15A is a schematic view of a phototherapy device 300 according to an embodiment of the invention; and FIG. 15B is a schematic view showing another embodiment of the phototherapy device 300 according to FIG. 15A.

In the phototherapy apparatus 300, the phototherapy apparatus 200 is covered with a sealing member 260. The seal 260 is made of a material that is resistant to water and oxygen. Thereby, in addition to the original highly closely packed phototherapy device 200, a better water and oxygen barrier effect is achieved by the sealing member 260. In one example, as shown in FIG. 15B, a moisture absorbing material is added to the sealing member 260 and a light transmitting region 260a is opened for the light emitting unit 220 of the phototherapy device 200 to transmit light. Thereby, the moisture absorbing material further enhances the waterproof oxygen resistance to achieve a good luminescent effect.

The basic structure of the phototherapy apparatus 200, 300 is disclosed above in various embodiments. Based on the development of modern process technology, all of the components of the phototherapy devices 200, 300 can be formed thin, thereby allowing the phototherapy devices 200, 300 to be flexed into any shape to have a variety of different application types.

For example, please refer to FIG. 16. FIG. 16 is a schematic view showing the phototherapy apparatus 200 in a flexed state according to an embodiment of the present invention. In Fig. 16, the phototherapy device 200 can be flexed and bent. Thereby, a desired shape can be formed in response to various conditions at the time of wearing.

Various application embodiments of the phototherapy device 200 will be described next, and the phototherapy device 300 can be implemented in comparison. 17 is a schematic view showing an application example of the phototherapy device 200 of the present invention; and FIG. 18 is a schematic view showing another application example of the phototherapy device 200 of the present invention. Since the phototherapy device 200 can be flexed, it can be formed into a ring shape and sleeved to various parts of the human body. For example, in Fig. 17, the annular phototherapy device 200 is placed on the thumb knuckles so that it can illuminate the acupuncture point of the human hand to achieve a phototherapy effect. In Fig. 18, the sheet-like phototherapy device 200 is attached to the phase of the human foot. Corresponding to the location of the acupuncture point to achieve phototherapy effect. The phototherapy device 200 can be attached to other parts of the human body in various forms. For example, the annular phototherapy device 200 can also be sleeved to the wrist; or the sheet-shaped phototherapy device 200 can be attached to the head or made into a mask to be attached to the face so that it can illuminate the desired part. To achieve a therapeutic or whitening effect. In more likely embodiments, the phototherapy device 200 can also be stretched into a garment liner, a cap liner, a pillow cover, an insole, a sock or an eye mask liner, and is not limited to the examples disclosed above.

Please refer to FIG. 19 to FIG. 21 at the same time. FIG. 19 is a schematic exploded view of a phototherapy device 400 according to an embodiment of the present invention; FIG. 20 is a schematic cross-sectional view of the phototherapy device 400 of FIG. 19;

The phototherapy device 400 includes a base 410, a printed circuit board 420, a power supply unit 430, and an upper cover 440.

The base 410 includes a bottom surface 411 and defines a first chamber 410a therein.

The printed circuit board 420 can be mounted within the first chamber 410a. The light emitting unit 422 and the conductive electrode group 421 are disposed on the printed circuit board 420, and the driving circuit 423 is further disposed to switch the light emitting mode of the light emitting unit 422. The conductive electrode group 421 includes a positive electrode contact 421a and a negative electrode contact 421b. The light emitting unit 422, the conductive electrode group 421, and the driving circuit 423 are electrically connected to each other. The light emitting unit 422 may use an inorganic light emitting diode or an organic light emitting diode that emits light toward the bottom surface 411. The bottom surface 411 is provided with a light-transmissive hole 411a through which the light of the light-emitting unit 422 can pass, so as to guide the light to illuminate the human skin for phototherapy.

A second chamber 440a is formed on the upper cover 440, and the power supply unit 430 can be mounted and fixed to the second chamber 440a. The power supply unit includes a positive electrode contact 430a and a negative electrode contact 430b.

The upper cover 440 is rotatably received in the base 410. More specifically, the base 410 is provided with a fitting groove 413, and the upper cover 440 is provided with a fitting rail 441, and the fitting rail 441 is rotatably fitted to the fitting groove 413.

Please refer to FIG. 22A and FIG. 22B. FIG. 22A is a schematic view showing a state in which the power supply unit 430 and the conductive electrode group 421 are not turned on in the present invention. FIG. 22B is a diagram showing the power supply unit 430 and the present invention. A schematic diagram of the conductive state of the conductive electrode group 421.

After the upper cover 440 and the base 410 are combined with each other, the positive electrode contact 430a of the power supply unit 430 may or may not contact the positive electrode contact 421a of the conductive electrode group 421; and the negative electrode contact 430b of the power supply unit 430 constantly contacts the negative electrode of the conductive electrode group 421. Contact 421b. Thereby, the power supply unit 430 and the conductive electrode group 421 can be turned on or off, thereby switching the light-emitting unit 422 to emit light or turn off. More specifically, the second chamber 440a on the upper cover 440 can be eccentrically rotated with respect to the first chamber 410a of the base 410, and the power supply unit 430 is fixed to the second chamber 440a of the upper cover 440. Therefore, when the upper cover 440 is rotated, the power supply unit 430 is collectively driven to rotate eccentrically with respect to the first chamber 410a. By this eccentric rotation, the switching power supply unit 430 and the conductive electrode group 421 are turned on or off, thereby switching the light-emitting unit 422 to emit light or turn off.

In one example, the positive electrode contact 421a of the conductive electrode group 421 has a column shape, and cooperates with the shape and position of the positive electrode contact 430a and the negative electrode contact 430b of the power supply unit 430 to construct the positive electrode contact 421a and the negative electrode contact of the conductive electrode group 421 on the printed circuit board 420. When the power supply unit 430 is eccentrically rotated, the negative electrode contact 430b of the power supply unit 430 is constantly in contact with the negative electrode contact 421b of the conductive electrode group 421, but the positive electrode contact 430a of the power supply unit 430 is selectively connected to the conductive electrode group 421. The positive electrode contact 421a is in contact. Thereby, the power supply unit 430 and the conductive electrode group 421 of the printed circuit board 420 can be selectively determined to be conductive.

The power supply unit 430 can use a thin battery such as a thin film battery, a fuel cell or a button battery to achieve a small size and a portable effect.

Please refer to FIG. 23A and FIG. 23B. 23A is a schematic structural view of a phototherapy device 400 according to an embodiment of the present invention; and FIG. 23B is a schematic view showing the combination of the housing 440 and the base 410 of FIG. 23A. The aforementioned phototherapy device 400 can be used in a variety of ways. For example, as shown in FIG. 19 to FIG. 21, if the barbs 442 are formed on the mating rails 441, the upper cover 440 can be detached and separated from the base 410, and a single-use manner can be formed. The power supply unit 430 is not replaceable. Alternatively, as shown in FIG. 23A and FIG. 23B, a plurality of open card slots 414 are formed on the base 410, and a plurality of engaging portions 443 corresponding to the card slots 414 are disposed on the upper cover 440, and the engaging rails 441 of the upper cover 440 are taken. Set the barbs 442. Thereby, the engaging portion 443 can be inserted into the card slot 414 to rotate clockwise to fit the upper cover 440 and the base 414. When the power supply unit 430 is exhausted, the upper cover 440 and the base 410 can be detached and separated by the engaging portion 443 and the card slot 414 for replacement, thereby forming a multi-use manner.

Please continue to refer to Figure 24. Figure 24 is a schematic illustration of another embodiment of a printed circuit board 420 in accordance with the present invention.

The shape of the printed circuit board 420 in the present invention is not limited as long as it can be accommodated in the first chamber 410a of the base 410, and the positive electrode contact 421a and the negative electrode contact 421b of the conductive electrode group 421 are disposed on the printed circuit board 420. When the power supply unit 430 is eccentrically rotated, the negative electrode contact 430b of the power supply unit 430 is constantly in contact with the negative electrode contact 421b of the conductive electrode group 421, but the positive electrode contact 430a of the power supply unit 430 is selectively connected to the positive electrode contact 421a of the conductive electrode group 421. Contacting to switch the operation mode of the light-emitting unit 422 while maintaining the eccentric rotation of the power supply unit 430. In an example, as shown in FIG. 24, the printed circuit board 420 can be rectangular, and the positive electrode contact 421a on the printed circuit board 420 is in the shape of a curved sheet, and can still maintain the action of the switching light-emitting unit when the power supply unit 430 is eccentrically rotated. the way. The positive electrode contact 421a and the negative electrode contact 421b operate in accordance with the electrode form of the power supply unit 430. For example, when the power supply unit 430 uses a button battery, its positive electrode contact 430a is located on the side, so that its negative electrode contact 430b is in constant contact, and its positive electrode contact 430a is selectively contacted. If the power supply unit 430 is in other forms, the positive electrode contact 430a and the negative electrode contact 430b may be mutually interchanged such that the positive electrode contact 430a is in constant contact and the negative electrode contact 430b is selectively in contact.

The number of the light-emitting units 422 of the present invention is not limited, and a plurality of light-emitting units 422 can be simultaneously provided. By driving the drive circuit 423, different light-emitting modes can be obtained by sequentially switching. The plurality of light emitting units 422 may have the same color light or each have a different color light. When different colors of light are used, different kinds of effects can be obtained; when a single color light is used, different light intensities and gradations can be obtained to obtain different degrees of therapeutic effects.

Please refer to FIG. 25A to FIG. 25D together. 25A is a diagram showing the use of multiple light emitting sheets of the present invention FIG. 25B is a schematic diagram showing a first illumination state when the plurality of illumination units 422 are used in the present invention; FIG. 25C is a diagram showing the use of the plurality of illumination units 422 in the present invention. FIG. 25D is a schematic diagram showing a second lighting state when the plurality of light emitting units 422 are used in the present invention.

In FIGS. 25A to 25D, the conductive electrode group 421 on the printed circuit board 420 includes a negative electrode contact 421b and four positive electrode contacts 421a. As described above, the power supply unit 430 is driven to rotate eccentrically so that the positive electrode contact 430a is in contact with or not in contact with the positive electrode contact 421a of each conductive electrode group 421, and the negative electrode contact 430b of the power supply unit 430 is constantly in contact with the conductive electrode group 421. The negative electrode contact 421b sequentially switches the light emission or the off of the plurality of light emitting units 422. When a plurality of light-emitting units 422 of different color lights are used, in FIG. 25A, the positive electrode contact 430a of the power supply unit 430 is not in contact with any positive electrode contact 421a due to eccentric rotation, and is not turned on, forming a closed state. In FIG. 25B, the positive electrode contact 430a of the power supply unit 430 contacts one of the positive electrode contacts 421a to emit a first color light. Next, as shown in Fig. 25C, the power supply unit is again eccentrically rotated so that the positive electrode contact 430a does not contact any of the positive electrode contacts 421a, and the closed state is again formed. Next, as shown in FIG. 25D, the positive electrode contact 430a of the power supply unit 430 contacts the other positive electrode contact 421a to emit a second color light. By the foregoing, the positive electrode contact 430a of the power supply unit 430 can sequentially contact the positive electrode contacts 421a to form a circulating action of conducting or not conducting, and sequentially causing the plurality of light emitting units 422 to emit different color lights or different light intensities and color levels. The same color of light. Such multi-segment switching can also be applied to different illumination modes of the drive circuit 423 when only one illumination unit 422 is used, so that the single illumination unit 422 has different illumination modes, and thus has different variations of single color light intensity or color scale.

26A is a first state diagram showing the use of wireless charging of the phototherapy apparatus of the present invention; and FIG. 26B is a second state diagram showing the use of wireless charging by the phototherapy apparatus of the present invention. The phototherapy device 400 can also switch to charge or illuminate the light-emitting unit 422 by a rotation operation. At this time, in one example, the function of wireless charging can be achieved by adding a wireless charging chip (not shown) to the printed circuit board 420. The wireless charging chip (not shown) also has a positive contact (not shown) and a negative contact (not shown).

The positive contact pull-out circuit of the wireless charging chip (not shown) is electrically connected to the pin 424 added to the printed circuit board 420. When the light-emitting unit 422 is turned off, the pin 424 is in contact with the positive electrode contact 430a of the power supply unit 430, and the positive and negative contact points of the wireless charging chip (not shown) are respectively connected to the positive electrode contact 430a and the negative electrode contact 430b of the power supply unit 430. through. When the phototherapy device 400 is not in use, wireless charging can be performed. When the phototherapy device 400 is in use, the positive electrode contact 430a of the power supply unit 430 is disconnected from the positive electrode contact of the wireless charging chip (not shown). At this time, the battery is not charged, so that the user may be overheated due to charging while using the device. .

FIG. 27 is a schematic view showing another application example of the phototherapy apparatus 400 of the present invention.

In actual use, in an example, as shown in FIG. 27, the user can switch the illumination mode of the light-emitting unit 422 by rotating the upper cover 440. The base 410 can be disposed on the flexible base 470. The flexible base 470 extends outwardly with an extension 475 to fit a large area to the human skin, which helps the phototherapy device 400 to be fixed. The extension portion 475 may be integrally manufactured at the time of manufacturing the base 410 or the flexible base 470, or may be additionally provided, and the manner of formation thereof is not particularly limited.

Please refer to FIG. 28A and FIG. 28B together. 28A is a cross-sectional view of a phototherapy device 600 in accordance with an embodiment of the present invention. FIG. 28B is a schematic diagram showing an embodiment of the light emitting unit 630 of FIG. 28A. The phototherapy device 600 basically includes an upper cover 610, a power supply unit 620, and a light emitting unit 630, and may further include a flexible base 640. A conductive electrode 620c is disposed on a side of the upper cover 610 for arranging a positive electrode contact 620a of the power supply unit 620 and a positive electrode contact of the light emitting unit 630.

The power supply unit 620 is disposed on the inner surface 610a of the upper cover 610 and includes a positive electrode contact 620a and a negative electrode contact 620b respectively located on the left and right sides thereof.

The light emitting unit 630 is disposed on the power supply unit 620 and includes a positive electrode contact and a negative electrode contact. More specifically, in an example, please refer to FIG. 28B. The upper and lower sides of the light-emitting unit 630 respectively include a substrate 630a and a package cover 630b, and a light-emitting body 630c is interposed between the substrate 630a and the package cover 630b, and corresponding positive and negative electrodes are respectively disposed on the left and right sides of the organic light-emitting body 630c. contact. The above-described light emitting unit 630 can use, for example, a thin organic light emitting diode or inorganic hair led.

In the phototherapy device 600, the negative electrode contact 620b of the power supply unit 620 and the negative electrode contact of the light emitting unit 630 are constantly turned on, and the positive electrode contact 620a of the power supply unit 620 and the positive electrode contact of the light emitting unit 630 are not initially turned on, and thus the circuit cannot be formed. The passage on. In order to make the light emitting unit 630 emit light, the positive electrode contact 620a of the power supply unit 620 is connected to the conductive electrode 620c. The positive electrode contact of the light emitting unit 630 can be freely flexed to extend below the conductive electrode 620c. Therefore, in FIG. 31, when the positive electrode contact of the light-emitting unit 630 is flexed to contact the conductive electrode 620c, the positive electrode contact of the light-emitting unit 630 is electrically connected to the positive electrode contact 620a of the power supply unit 620 to form a path on the circuit. This causes the light emitting unit 630 to emit light.

In the actual application, the phototherapy device 600 can be covered with the flexible cover 640 and covered with the upper cover 610 to cover the light-emitting unit 630 and the power supply unit 620 to form a tightly closed device. The flexible base 640 can use a transparent solid colloid to conform to the surface of the human skin or other objects, and can be used for the light emitted by the light emitting unit 630; or a transparent hole 641 is formed in the flexible base 640 for the light emitting unit. The light emitted by 630 penetrates. Another conductive magnetic unit 660 is disposed on the positive electrode contact of the light emitting unit 630 so as to be engaged with the conductive electrode 620c when flexing.

The above-described light emitting unit 630 can use, for example, a thin bottom light emitting organic light emitting diode. Moreover, the light-emitting unit 630, the power supply unit 620, and the flexible base 640 can be in the form of a thin sheet, and then combined with the upper cover 610 to form a thin portable phototherapy device 600, which can be attached to the surface of any object to achieve a luminous effect.

Please refer to FIG. 29A and FIG. 29B. 29A is a cross-sectional view of a phototherapy device 700 in accordance with an embodiment of the present invention; and FIG. 29B is a cross-sectional view showing another example of the phototherapy device 700 of FIG. 29A. The phototherapy device 700 includes a flexible base 710, a power supply unit 720, and a light emitting unit 730.

The power supply unit 720 is disposed on the flexible base 710 and extends between the positive electrode contact 720a and the negative electrode contact 720b on the left and right sides thereof.

The light emitting unit 730 is disposed on the power supply unit 720, and extends the positive electrode contact 730a and the negative electrode contact 730b with respect to the positive electrode contact 720a and the negative electrode contact 720b on the left and right sides thereof.

In actual use, the negative electrode contact 720b of the light emitting unit 720 is always electrically connected to the negative electrode contact 730b of the power supply unit 730, and the positive electrode contact 330a of the light emitting unit 730 can be extended to be bent to turn on or not to conduct the positive contact of the power supply unit 720. 320a, whereby the light-emitting unit 330 is switched to emit light or not.

In one example, the magnetic adsorbing sheet 750 is disposed on the power supply unit 720 side, and the magnetic unit 760 is disposed on the back surface of the positive electrode contact 730a of the light emitting unit 730. Thereby, the positive electrode contact 330a of the light emitting unit 730 can adsorb the positive electrode contact 320a of the power supply unit 720 through the magnetic unit 760, and turn on the positive electrode contact 720a and the positive electrode contact 730a to cause the light emitting unit 730 to emit light. Magnetic unit 760 can be electrically conductive or non-conductive. When the magnetic unit 760 is electrically conductive, as shown in FIG. 29A, the positive electrode contact 730a of the light emitting unit 730 can be turned on when the positive electrode contact 320a of the power supply unit 720 is attracted. In another example, if the magnetic unit 760 is disposed on the front surface of the positive electrode contact 330a of the light-emitting unit 730, it is not required to have conductivity.

Please refer to Figure 30. Figure 30 is a cross-sectional view showing a phototherapy device 800 in accordance with still another embodiment of the present invention. The phototherapy device 800 includes a flexible base 810, a power supply unit 820, and a light emitting unit 830.

The flexible base 810 includes a first area 810a and a second area 810b. The power supply unit 820 is disposed in the first region 810a and extends on the one side of the positive electrode contact 820a and the negative electrode contact 820b, respectively. In one example, the power supply unit 820 can be directly attached to the film-type power supply unit 820 or directly formed on the flexible base 810.

The light emitting unit 830 is disposed on the second region 810b and extends the positive electrode contact 830a and the negative electrode contact 830b on one side thereof. In one example, the arrangement may directly attach the light emitting unit 830 or directly plate the light emitting unit 830 directly on the flexible base 810.

Similar to the foregoing embodiment, the positive electrode contact 820a of the power supply unit 820 and the positive electrode contact 830a of the light emitting unit 830 are constantly conducting, and the negative electrode contact 820b of the power supply unit 820 and the negative electrode contact 830b of the light emitting unit 830 are in the initial first region 810a and the second region. 810b does not conduct when unfolded. After the first region 810a and the second region 810b are in a folded contact, the negative electrode contact 820b is brought into contact with the negative electrode contact 830b to be turned on. At this time, the light emitting unit 830 and the power supply unit 820 form a circuit. The upper path can be illuminated.

In order to fix the first region 810a and the second region 810b of the flexible base 810 after folding, a magnetic adsorption sheet may be disposed on one surface of the power supply unit 820, and a magnetic unit 860 may be disposed on one surface of the light emitting unit 830. A region 810a and a second region 810b are relatively closely attached after being folded. In the above manner, the first region 810a and the second region 810b of the flexible base 810 can form a tightly closed phototherapy device 800 after being folded over each other. In addition, the magnetic unit 860 can open a light-transmitting area for the light emitted by the light-emitting unit 830 to penetrate.

31 is a cross-sectional view of a phototherapy device 900 in accordance with an embodiment of the present invention. The phototherapy device 900 includes a flexible base 910, a power supply unit 920, a light emitting unit 930, and a conductive portion 940.

The flexible base 910 includes a first face 910a and a second face 910b on the opposite side.

The power supply unit 920 side extends the positive electrode contact 920a and the negative electrode contact 920b, respectively.

The light emitting unit 930 is disposed between the power supply unit 920 and the first surface 910a. One side of the light emitting unit 930 extends the positive electrode contact 930a and the negative electrode contact 930b respectively, and the light emitted by the light emitting unit 930 can penetrate the first surface 910a and the second surface 910b of the flexible base 910.

The conductive portion 940 extends from the first surface 910a of the flexible base 910 and is flexible.

In actual use, the negative electrode contact 920b of the power supply unit 920 and the negative electrode contact 930b of the light-emitting unit 930 are constantly turned on, and the conduction thereof can be fastened to the positive electrode contact 920a of the power supply unit 920 and the positive electrode contact 930a of the light-emitting unit 930 through the conductive portion 940. The conductive portion 940 can be formed together when the electrodes of the light emitting unit 930 and the power supply unit 920 are manufactured. The positive electrode contact 920a of the power supply unit 920 and the positive electrode contact 930a of the light emitting unit 930 are initially non-conductive. When the conductive portion 940 is flexed, the conductive portion 940 simultaneously contacts the positive electrode contact 920a of the power supply unit 920 and the positive electrode contact 930a of the light emitting unit 930. Thereby, the positive electrode contact 920a of the power supply unit 920 and the positive electrode contact 930a of the light-emitting unit 930 are turned on, and the power supply unit 920 and the light-emitting unit 930 form a path on the circuit, so that the light-emitting unit 930 can emit light.

In order to fix the conductive portion 940 after being bent, the magnetic unit 960 is disposed on the second surface 910b of the flexible base 910 to be adsorbed when the conductive portion 940 is flexed. At the same time, if it is based on convenient use The magnetic unit 960 is entirely covered to the second surface 910b of the flexible base 910, and the light-transmitting region 960a is opened on the magnetic unit 960 to penetrate the light emitted by the light-emitting unit 930. The magnetic unit 960 can be made of a magnetic cloth to achieve lightness, softness, and comfort.

In summary, the phototherapy device disclosed by the present invention has a light and thin volume, and has flexible and simple operation modes, and is suitable for carrying anywhere. Moreover, the light-emitting unit can emit light having various different light-emitting bands, can achieve different illumination effects, and has application flexibility.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and any person skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, and thus the protection of the present invention. The scope is subject to the definition of the claims.

Claims (49)

1. A phototherapy device, characterized in that the phototherapy device comprises:

   Flexible base

   a printed circuit board disposed above the flexible base, the printed circuit board including a driving circuit;

   a conductive electrode group, which is combined on the printed circuit board, the conductive electrode group includes a positive electrode contact and a negative electrode contact;

   a power supply unit disposed above the conductive electrode group, the power supply unit including a positive contact and a negative contact;

   a light emitting unit disposed between the printed circuit board and the flexible base, wherein the light emitting unit is electrically connected to the power supply unit and the driving circuit;

   An upper cover disposed above the power supply unit and covering the power supply unit, the conductive electrode group, the printed circuit board, and the light emitting unit;

   The positive electrode contact and the negative electrode contact of the conductive electrode group are in constant contact with the positive electrode contact and the negative electrode contact of the power supply unit, and the upper cover is pressed to press the power supply unit to make The power supply unit presses the conductive electrode group such that the negative electrode contact of the conductive electrode group contacts a conductive line on the printed circuit board to provide a signal to the drive circuit and drives the drive circuit through the drive circuit The light emitting unit emits light toward the flexible base.
2. The phototherapy apparatus according to claim 1, wherein the phototherapy apparatus further comprises a fixing member, the fixing member is located on the flexible base, and the fixing member and the upper cover are combined with each other, An accommodating space is formed in the fixing member, and the power supply unit, the conductive electrode group, the printed circuit board and the light emitting unit are accommodated in the accommodating space.
3. The phototherapy apparatus according to claim 2, wherein said fixing member is integrally formed with said flexible base.
4. The phototherapy apparatus according to claim 1, wherein said flexible base and said upper cover are integrally molded by silicone infusion or by bonding said upper cover to said flexible base. .
5. The phototherapy apparatus according to claim 1, wherein said upper cover is made of a flexible material.
6. The phototherapy apparatus according to claim 1, wherein said flexible base extends outwardly by an extension portion having a shape of a line, a cross, a Y, a butterfly wing or an irregular shape.
7. The phototherapy apparatus according to claim 1, wherein said power supply unit is a rechargeable battery.
8. The phototherapy apparatus according to claim 1, wherein said power supply unit is a thin film battery, a fuel cell or a button battery.
9. The phototherapy apparatus according to claim 1, wherein the flexible base comprises a bottom surface, and the bottom surface defines a plurality of light-transmissive holes for the light emitted by the light-emitting unit to penetrate.
10. The phototherapy apparatus according to claim 1, wherein the light emission band of the light is a red light band of 610 nm to 650 nm, an orange light band of 600 nm to 620 nm, and a yellow light band of 580 nm to 600 nm. , 495 nm to 560 nm green light band, 450 nm to 495 nm blue light band, 410 nm to 450 nm light band, 395 nm to 475 nm purple band, 650 nm to 1000 nm infrared band or greater The far infrared band of 1350 nm.
11. The phototherapy apparatus according to claim 1, wherein said light emitting unit is an inorganic light emitting diode or an organic light emitting diode.
12. The phototherapy apparatus according to claim 1, wherein the number of the light emitting units is one or two or more.
13. The phototherapy apparatus according to claim 1, wherein the printed circuit board is provided with a plurality of through holes, the positive electrode contact and the negative electrode contact of the conductive electrode group, and the positive electrode of the power supply unit The contact and the negative contact are embedded in the through hole to fix the conductive electrode group and the power supply unit to the printed circuit board.
14. A phototherapy device, characterized in that the phototherapy device comprises:

    Flexible base

    a light emitting unit disposed above the flexible base;

    a power supply unit disposed above the light emitting unit, the power supply unit being electrically connected to the light emitting unit;

    a printed circuit board disposed above the power supply unit, wherein the printed circuit board is provided with a wireless charging system and a switch control circuit, wherein the wireless charging system and the switch control circuit are electrically connected to the power supply unit;

    a switch body disposed above the printed circuit board, the switch body being electrically connected to the switch control circuit;

    Wherein the power supply unit is wirelessly charged by the wireless charging system, and the power supply unit supplies required power to the light emitting unit and the switch control circuit, and the switch body controls the switch through the switch control circuit The luminous intensity and the emission band of the light-emitting unit are described.
15. The phototherapy apparatus according to claim 14, wherein said light emitting unit is an organic light emitting diode or an inorganic light emitting diode.
16. The phototherapy apparatus according to claim 14, wherein said power supply unit is a thin film rechargeable battery.
17. The phototherapy device of claim 14 wherein said wireless charging system comprises:

    Wireless charging receiver; and

    And a charging circuit electrically connected to the wireless charging receiving unit and the power supply unit.
18. The phototherapy device of claim 17 wherein said wireless charging interface The receiving portion includes an induction coil that is electromagnetically induced by the main coil of the external charging device to generate an inductance, and converts the electric energy to wirelessly charge the power supply unit through the charging circuit.
19. The phototherapy apparatus according to claim 14, wherein said switch body comprises:

    a magnetic isolation plate disposed on the printed circuit board;

    a control circuit layer disposed on the magnetic isolation sheet, the control circuit layer electrically connecting the switch control circuit on the double-sided printed circuit board;

    a pad layer disposed on the control circuit layer;

    a panel layer, which is disposed on the rubber layer, the panel layer includes a plurality of buttons, and the plurality of buttons are electrically connected to the control circuit layer and the switch control circuit after pressing, thereby switching the light emitting unit Luminous intensity or luminescence band.
20. A phototherapy apparatus according to claim 14, wherein said switch control circuit includes an inductive receiving unit.
21. The phototherapy apparatus according to claim 20, wherein the inductive receiving unit is a sound sensor, a pressure sensor, a light sensor, or a gravity sensor.
22. A phototherapy apparatus according to claim 14, wherein said phototherapy apparatus further comprises a seal made of a water-repellent oxygen material for covering said phototherapy apparatus.
23. The phototherapy device of claim 22 wherein said seal is transparent.
24. The phototherapy apparatus according to claim 22, wherein a light transmitting region is formed in the sealing member for light transmitted by the light emitting unit to penetrate.
25. The phototherapy device according to claim 22, wherein said sealing member is provided with a hygroscopic material.
26. A phototherapy device, characterized in that the phototherapy device comprises:

    a base comprising a bottom surface and forming a first chamber therein;

    a printed circuit board mounted in the first chamber, the printed circuit board comprising a light emitting sheet And a conductive electrode group electrically connected to the light emitting unit, wherein the light emitting unit emits light toward the bottom surface;

    a power supply unit for electrically connecting the conductive electrode group;

    An upper cover, wherein a second chamber is formed for the power supply unit to be placed, the upper cover can be rotatably received in the base, wherein the second chamber is eccentrically rotated relative to the first chamber And driving the power supply unit to rotate eccentrically to switch whether the power supply unit and the conductive electrode group are turned on or not, thereby switching whether the light emitting unit emits light or not.
27. The phototherapy apparatus according to claim 26, wherein a light transmission hole is formed in the bottom surface, and the light emitted by the light emitting unit passes through the light transmission hole.
28. The phototherapy apparatus according to claim 26, wherein said printed circuit board comprises a driving circuit electrically connected to said conductive electrode group, said light emitting unit being driven by said driving circuit to switch light emission of said light emitting unit mode.
29. The phototherapy apparatus according to claim 26, wherein a fitting groove is provided in the base, and a fitting rail is provided on the lid body, and the fitting rail is rotatably fitted to the fitting groove.
30. The phototherapy apparatus according to claim 29, wherein the fitting rail is formed with a barb so that the upper cover cannot be detached and separated from the base.
31. The phototherapy apparatus according to claim 29, further comprising a plurality of open card slots on the base, and the upper cover includes a plurality of engaging portions corresponding to the plurality of card slots, the upper cover After being fitted into the base, the upper cover and the base can be detached and separated by the plurality of card slots and the engaging portions.
32. The phototherapy apparatus according to claim 29, wherein the conductive electrode group comprises a positive electrode contact and a negative electrode contact, the power supply unit comprises a positive electrode contact and a negative contact; the power supply unit is eccentrically rotated to enable the power supply unit The positive electrode contact selectively contacts the positive electrode contact of the conductive electrode group, and the negative electrode contact of the power supply unit constantly contacts the negative electrode contact of the conductive electrode group.
33. The phototherapy apparatus according to claim 32, wherein said positive electrode contact of said conductive electrode group has a columnar shape.
34. The phototherapy device according to claim 29, wherein the phototherapy device further comprises a flexible base, the base is fixed on the flexible base, and the flexible base extends outwardly and extends unit.
35. The phototherapy apparatus according to claim 29, wherein said printed circuit board comprises a plurality of light emitting units, and said second chamber is eccentrically rotated with respect to said first chamber to drive said power supply unit to rotate eccentrically Switching the power supply unit to the conductive electrode group to conduct or not, and then switching the plurality of light emitting units to sequentially emit light.
36. The phototherapy apparatus according to claim 35, wherein said conductive electrode group comprises a plurality of positive electrode contacts and negative electrode contacts, said power supply unit comprises a positive electrode contact and a negative electrode contact; said power supply unit is eccentrically rotated to enable said power supply The positive electrode contacts of the unit selectively contact the plurality of positive electrode contacts of the conductive electrode group, and the negative electrode contacts of the power supply unit constantly contact the negative electrode contacts of the conductive electrode group.
37. The phototherapy apparatus according to claim 35, wherein said plurality of light emitting units sequentially switch to emit the same or different colored lights.
38. A phototherapy device, characterized in that the phototherapy device comprises:

    a power supply unit including a positive contact and a negative contact;

    a light emitting unit comprising a positive electrode contact and a negative electrode contact;

    One of the positive electrode contact or the negative electrode contact of the light-emitting unit is constantly conducting with one of the positive electrode contact or the negative electrode contact corresponding to the power supply unit; a positive electrode contact or the negative electrode contact, wherein the power supply unit can be switched or not adsorbed by the magnetic unit, thereby selectively turning on or not conducting another of the positive electrode contacts in the power supply unit or The negative electrode contact is used to switch the light emitting unit to emit light or not to emit light.
39. A phototherapy device, characterized in that the phototherapy device comprises:

    An upper cover having an inner surface and a conductive electrode disposed on a side of the upper cover;

    a power supply unit disposed on the inner surface, wherein the left and right sides of the power supply unit respectively include a positive contact and a negative contact;

    a light emitting unit disposed on the power supply unit, the light emitting unit includes a positive electrode contact and a negative electrode contact;

    The negative electrode contact of the power supply unit and the negative electrode contact of the light emitting unit are constantly conducting, and the positive electrode contact of the power supply unit extends to connect the conductive electrode; the positive contact of the light emitting unit can The freely flexing extension extends or does not contact the conductive electrode, thereby turning on or off the positive electrode contact of the power supply single source and the positive electrode contact of the light emitting unit, thereby switching the light emitting unit to emit light or not Glowing.
40. The phototherapy apparatus according to claim 39, wherein said light emitting unit and said power supply unit are in a sheet shape.
41. The phototherapy apparatus according to claim 39, wherein said phototherapy apparatus further comprises a flexible base, said flexible base being covered with said upper cover to cover said light emitting unit and said power supply unit .
42. A phototherapy device, characterized in that the phototherapy device comprises:

    Flexible base

    a power supply unit, which is disposed on the flexible base, and extends a positive contact and a negative contact on the left and right sides of the power supply unit;

    a light emitting unit, which is disposed on the power supply unit, and extends a positive electrode contact and a negative electrode contact on the left and right sides of the light emitting unit;

    The negative electrode contact of the power supply unit is always electrically connected to the negative electrode contact of the light emitting unit, and the positive electrode contact of the light emitting unit can be flexed to turn on or not to conduct the power supply unit. The positive electrode contact is used to switch the light emitting unit to emit light or not to emit light.
43. The phototherapy apparatus according to claim 42, wherein a magnetic adsorption sheet is disposed on a side of the power supply unit, and a magnetic unit is disposed on a side of the light emitting unit, the light emitting unit The positive electrode contact of the element transmits the positive electrode contact of the power supply unit and the positive electrode contact of the light emitting unit by the magnetic unit adsorbing the positive electrode contact of the power supply unit.
44. A phototherapy device, characterized in that the phototherapy device comprises:

    a flexible base comprising a first region and a second region;

    a power supply unit disposed in the first area, wherein the power supply unit side extends a positive contact and a negative contact, respectively;

    a light emitting unit is disposed in the second area, and one side of the light emitting unit extends a positive contact and a negative contact respectively;

    The positive pole contact of the power supply unit and the positive pole contact of the light emitting unit are constantly conducting, and the negative contact of the power supply unit and the negative contact of the light emitting unit are in the first area and The second region is not conductive when it is not folded, and is turned on after the first region and the second region are relatively folded, thereby switching the light emitting unit to emit light or not.
45. The phototherapy apparatus according to claim 44, wherein a magnetic adsorption sheet is provided on one surface of the power supply unit, and a magnetic unit is provided on one side of the light-emitting unit so that the first region and the second region are relatively folded. Tightly adsorbed.
46. The phototherapy apparatus according to claim 44, wherein a light transmitting region is formed in said magnetic unit for light transmitted by said light emitting unit to penetrate.
47. A phototherapy device, characterized in that the phototherapy device comprises:

    a flexible base comprising a first side and a second side on the opposite side;

    a power supply unit, wherein the power supply unit side extends a positive contact and a negative contact respectively;

    a light emitting unit is disposed between the power supply unit and the first surface, and one side of the light emitting unit extends a positive electrode contact and a negative electrode contact respectively, and the light emitted by the light emitting unit penetrates the first surface and the The second side; and

    a conductive portion extending from the first surface of the flexible base to be flexible;

    The negative electrode contact of the power supply unit and the negative electrode contact of the light emitting unit are constantly conducting, and the positive electrode contact of the power supply unit and the positive electrode contact of the light emitting unit When the conductive portion is flexed, it is turned on, and when the conductive portion is flattened, it is not turned on, thereby switching the light emitting unit to emit light or not.
48. The phototherapy apparatus according to claim 47, wherein a magnetic unit is provided on the second surface of the flexible base to be adsorbed when the conductive portion is flexed.
49. A phototherapy apparatus according to claim 48, wherein said magnetic unit is provided with a light transmitting region for light transmitted by said light emitting unit to penetrate.

Images