WO2025020090A1 - Low-light glasses - Google Patents

Abstract

The present invention provides low-light glasses, comprising: a housing, which is of an elongated structure, wherein the housing has two accommodating recesses formed on the rear side and an operating portion provided on the front side, the operating portion has an upper inclined surface and a lower inclined surface, and the two ends of the housing are respectively provided with a temple portion; an OLED light-emitting unit, comprising two light-emitting modules that are respectively arranged at the bottoms of the two accommodating recesses, and having a slope, so that the two light-emitting modules each can generate an obliquely downward irradiation area; a control unit, comprising a key group and a controller, wherein the control unit is arranged in the housing and is electrically connected to the two light-emitting modules, and the key group is arranged on the lower inclined surface of the operating portion; and a support portion, provided between the two accommodating recesses of the housing.

Description

Low light glasses Technical Field

The invention relates to a low-light device for eyes, in particular to low-light glasses which can increase the illumination angle and improve the illumination effect.

Background Art

Nowadays, people are using more 3C products and are paying more attention to the dim light or maintenance of their eyesight. Now, a kind of LED dim light glasses is commonly seen in the market. An LED light module is set on a frame. The light changes to illuminate the glasses, creating a dim light or stimulating effect.

However, the existing LED lamp module is arranged on the outside of the frame. In addition to being unable to concentrate the light, the LED lamp emits a single color of light and the emitted light source is a single light source. During the emission process, it is easy to cause problems such as uneven and unfocused irradiation of light.

Invention Disclosure

The present invention is a pair of low-light glasses, which include: a shell, which is a long strip structure, and a rear side of which is concavely provided with two receiving grooves; a front side is provided with an operating part, and the operating part has an upper inclined surface and a lower inclined surface; two ends of the shell are respectively connected with a temple part; an OLED light-emitting unit, which is two light-emitting modules respectively arranged at the bottom of the two receiving grooves, and has an inclination so that the two light-emitting modules can produce an irradiation area obliquely downward; a control unit, which has a button group and a controller, the control unit is arranged in the shell and electrically connected to the two light-emitting modules, and the button group is arranged at the lower inclined surface position of the operating part; a support part, which is arranged between the two receiving grooves of the shell.

The micro-light glasses provided by the present invention can produce a good and concentrated illumination effect through the two light-emitting modules. The distance between the glasses and the eyes can be increased through the groove, and the inclined light-emitting modules can make their illumination areas more completely illuminate the user's eyes, thereby improving their efficiency. In addition, OLED can achieve color mixing through its own light-emitting effect, thereby improving color mixing and illumination effects.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a three-dimensional appearance diagram of a preferred embodiment of the present invention.

FIG. 2 is a rear view of the rear side of the housing of a preferred embodiment of the present invention.

FIG. 3 is a perspective exploded view of a preferred embodiment of the present invention.

FIG4 is a cross-sectional schematic diagram of the 4-4 section line in FIG2 of a preferred embodiment of the present invention.

FIG5 is a cross-sectional schematic diagram of the 5-5 section line in FIG2 of a preferred embodiment of the present invention.

FIG. 6 is a three-dimensional appearance diagram of another preferred embodiment of the present invention using different supporting parts.

Wherein, the reference numerals are:
10 Shell 11 Receptacle 12 Operation unit
121 Upper slope 122 Lower slope 13 Magnetic charging slot
14 Buckle seat 141 Buckle hole
15 Front housing 151 Card slot 16 Rear housing
161 Card Block
20 temple 21 pivot block 211 buckle slot
22 Temple 221 Buckle
30 OLED light-emitting unit 31 Left light-emitting module 32 Right light-emitting module
40 Control unit 41 Button group 42 Controller
50 support part 51 nose pad 52 buckle block
53 Support rod
60 Indicator unit 61 Indicator light
A Turning angle V Vertical line V1 Angle
B Wrap Angle

Best Mode for Carrying Out the Invention

The present invention is described in detail below with reference to the accompanying drawings and specific embodiments, but is not intended to limit the present invention.

Please refer to FIGS. 1 to 5 , which are a preferred embodiment of the micro-light glasses provided by the present invention, which include:

A housing 10 is a long strip structure, with two recesses 11 on one rear side; an operating portion 12 is provided on the front side, and the operating portion 12 has an upper inclined surface 121 and a lower inclined surface 122; a magnetic charging slot 13 is provided on the rear side of the housing 10; a buckle seat 14 is provided between the two recesses 11; two buckle holes 141 are provided on the buckle seat 14; the housing 10 is composed of a front housing 15 and a rear housing 16 The front shell 15 is assembled with the operating part 12, and the rear shell 16 is provided with the receiving groove 11, the magnetic charging groove 13 and the buckle seat 14; there is a turning angle A between the upper inclined surface 121 and the lower inclined surface 122, and the angle of the turning angle A is between 85° and 95°, and is 90° in this embodiment. The angle difference between the upper inclined surface 121 and the lower inclined surface 122 is mainly formed by turning. In addition, there is a length ratio between the upper inclined surface 121 and the lower inclined surface 122. The length of the upper inclined surface 121 is approximately between 1.6 and 2 times that of the lower inclined surface 122, and is 1.9 times in this embodiment. The longer upper inclined surface 121 can make the slope of the upper inclined surface 121 gentler, and the lower inclined surface 122 is relatively inclined. A locking block 161 is disposed at the bottom of the rear housing 16 , and a locking slot 151 is disposed opposite to the front housing 15 . When the front housing 15 and the rear housing 16 are assembled, the locking block 161 will be locked in the locking slot 151 .

The two temple portions 20 are respectively arranged at the two ends of the shell 10, and the temple portion 20 includes a pivot block 21 and a temple 22. One end of the pivot block 21 is pivoted to the side of the shell 10, and the other end of the pivot block 21 is provided with a buckle groove 211; the temple 22 is provided with a buckle 221 relative to the buckle groove 211, and the buckle 221 can be relatively elastically buckled in the buckle groove 211 to be fixed; the temple 22 is also an elastic temple, which can generate good elastic clamping force.

An OLED light-emitting unit 30 is disposed at the bottom of the two containing grooves 11, and is composed of a left light-emitting module 31 and a right light-emitting module 32, and has an inclination with a vertical line V. The left light-emitting module 31 and the right light-emitting module 32 of the OLED light-emitting unit 30 respectively have an angle V1 with the vertical line V, and the angle of the angle V1 is about 30° to 50°. In this embodiment, the angle V1 is 40°, so that the OLED light-emitting unit 30 can produce an irradiation area that is inclined downward. In addition, a wrap angle B is formed between the left light-emitting module 31 and the right light-emitting module 32, and the angle of the wrap angle B is about 120° to 160°. In this embodiment, the wrap angle B is 140°. Using OLED can produce a comprehensive and The full-color lighting effect does not require the use of multiple LEDs of different colors for light mixing like LEDs, so that the use effect of the OLED light-emitting unit 30 can be improved. Moreover, the downward tilted angle V1 of the two light-emitting modules can produce oblique lighting, which can provide a wider illumination area and a good lighting effect for different eye positions. Moreover, through the setting of the surround angle B, the left light-emitting module 31 and the right light-emitting module 32 can fit the user's face more closely; the OLED light-emitting unit 30 can produce four spectrums including but not limited to red, yellow, green and blue at the same time (or in different combinations); the spectrum wavelength emitted by the OLED light-emitting unit 30 is between 420 and 680nm and can be a continuous spectrum band.

A control unit 40 has a button group 41 and a controller 42. Placed in the shell 10 and electrically connected to these OLED light-emitting units 30 and the controller 42, the button group 41 is arranged on the lower inclined surface 122 of the operating part 12, and the button group 41 is arranged on the right side of the lower inclined surface 122 close to the right light-emitting module 32; the controller 42 can control the changes in the brightness and color of the OLED light-emitting unit 30 through the button group 41. In addition, the magnetic charging slot 13 can also supply power to the controller 42 or charge the controller 42.

A support portion 50 has two nose pads 51 and a buckle block 52; the buckle block 52 can be adjustably set on any buckle hole 141 of the buckle seat 14, so that the support portion 50 is set between the two receiving grooves 11 of the shell 10, and the two nose pads 51 can be placed on the bridge of the nose of the user, so that the two receiving grooves 11 can be relatively set at the position of the eyes of the user.

An indicating unit 60 is electrically connected to the controller 42 of the control unit 40. It is an indicator light 61, which is arranged at the rear end of the shell 10 and is located on the side of the buckle seat 14. Through the light changes of the indicator light 61, the user can know the current operating status, such as power exhaustion or in use or other operating instructions. In use, other indications such as sound or vibration can also be used to indicate the action.

When in use, the user wears the shell 10 on the face, and the two temple parts 20 can well clamp the user's face, and the support part 50 is propped up above the bridge of the user's nose. After the position is fixed, or before the position is fixed, the user can control the OLED light-emitting units 30 through the button group 41 of the control unit 40 located at the lower inclined surface 122 on the right side of the front shell 15. Because the button group 41 is set at the lower inclined surface 122, and there is a turning angle A between the upper inclined surface 121 and the lower inclined surface 122, the user can easily find the button group 41 with his fingers when wearing glasses according to the change of the inclination of the upper inclined surface 121 and the lower inclined surface 122. In the button position, the user can also conveniently feel and touch when in use. In addition, the OLED light-emitting unit 30 can produce an oblique illumination effect through the angle V1 and the surround angle B formed between the left light-emitting module 31 and the right light-emitting module 32, so that the OLED light-emitting unit 30 can be close to the user's eye position. In addition to the OLED light-emitting unit 30 using OLED to produce a good lighting effect and no need for mixed light, which can improve the illumination effect, the two OLED light-emitting units 30 maintain an inclined angle with the rear end of the shell 10, so that the user's eyes can be illuminated in a larger range, and it can also ensure that users with different eye heights can be well illuminated.

Please refer to FIG. 6 , which is a three-dimensional appearance diagram of another preferred embodiment of the present invention, and its main structure is the same as that of the previous preferred embodiment, and the similarities are not further described, wherein;

The nose pad 51 of the supporting portion 50 is replaced by a supporting rod 53 , and the user can directly insert the supporting rod 53 into the existing glasses, and can use the glasses without taking off the glasses originally worn, thereby increasing the convenience.

In summary, it is known that the invention has industrial applicability and progress, and the invention has not been seen in any publication and is also novel. It should comply with the provisions of the Patent Law. Therefore, I have filed an invention patent application in accordance with the law and sincerely request that your review committee approve the patent.

However, the above is only a feasible embodiment of the present invention and should not be used to limit the scope of implementation of the present invention; that is, all equivalent changes and modifications made according to the scope of the patent application of the present invention should still fall within the scope covered by the patent of the present invention.

Industrial Applicability

The micro-light glasses provided by the present invention can produce a good and concentrated illumination effect through the two light-emitting modules. The distance between the glasses and the eyes can be increased through the groove, and the inclined light-emitting modules can make their illumination areas more completely illuminate the user's eyes, thereby improving their efficiency. In addition, OLED can achieve color mixing through its own light-emitting effect, thereby improving color mixing and illumination effects.

Claims (14)

A low light glasses, characterized in that it at least comprises: A shell is a long strip structure, a rear side of which is concavely provided with two receiving grooves; a front side is provided with an operating portion, the operating portion has an upper inclined surface and a lower inclined surface; two ends of the shell are respectively connected with a mirror foot portion; An OLED light-emitting unit, which has two light-emitting modules respectively disposed at the bottom of the two containing grooves and has a slope, so that the OLED light-emitting unit can generate an irradiation area inclined downward; a control unit having a button group and a controller, the controller being disposed in the housing and electrically connected to the button group and the OLED light-emitting modules, the button group being disposed at a lower inclined surface of the operating portion; and A supporting portion is arranged between the two containing grooves of the shell. The micro-light glasses as described in claim 1 are characterized in that a magnetic charging slot is provided on the rear side and is electrically connected to the controller. The micro-focal glasses as described in claim 1 are characterized in that the temple portion includes a pivot block and a temple, one end of the pivot block is pivoted to the side of the shell, and the other end of the pivot block is provided with a buckle groove; the temple is provided with a buckle relative to the buckle groove, and the buckle can be elastically buckled in the buckle groove to form a fixation. The micro-focal glasses as claimed in claim 3, characterized in that the temple is an elastic temple. The micro-light glasses as described in claim 1 are characterized in that the shell is provided with a buckle seat on the rear side, the buckle seat is provided with at least two buckle holes, and the support portion is provided with a buckle block, and the buckle block can be selectively buckled on any buckle hole. The micro-light glasses as described in claim 5 are characterized in that two nose pads are provided on the supporting part. The micro-light glasses as described in claim 5 are characterized in that a connecting rod is provided on the supporting portion. The micro-light glasses as claimed in claim 1 are characterized by further comprising an indication unit, wherein the indication unit is electrically connected to the controller of the control unit. The micro-light glasses as claimed in claim 8, characterized in that the indicating unit is an indicator light. The micro-light glasses as described in claim 8 or 9 are characterized in that the indicator unit is arranged on the rear side of the shell. The micro-light glasses as claimed in claim 1 are characterized in that the two light-emitting modules respectively have an angle with a vertical line, and the angle is 30-50 degrees. The micro-light glasses as described in claim 1 are characterized in that the OLED light-emitting unit is a left light-emitting module and a right light-emitting module; there is a surround angle between the left light module and the right light-emitting module, and the surround angle is 120° to 160°. The micro-light glasses as claimed in claim 1 are characterized in that the spectral wavelength emitted by the OLED light-emitting unit is a continuous spectral band between 420 and 680 nm. The micro-light glasses as described in claim 1 are characterized in that the shell includes a front shell and a rear shell, the operating part is arranged on the front shell, and the receiving groove is arranged on the rear shell; a card block is arranged on the bottom of the rear shell, and a card slot is arranged on the bottom of the front shell; when the rear shell is combined with the front shell, the card block is arranged in the card slot.