CN111812848A - Near-to-eye display structure - Google Patents

Abstract

The invention discloses a near-to-eye display structure, which comprises an angle selection diaphragm, a screen, a first semi-transparent semi-reflective diaphragm and a second semi-transparent semi-reflective diaphragm, wherein the first semi-transparent semi-reflective diaphragm is arranged on one side, facing towards eyes, of the angle selection diaphragm, the second semi-transparent semi-reflective diaphragm is arranged on one side, far away from eyes, of the angle selection diaphragm, the first semi-transparent semi-reflective diaphragm, the angle selection diaphragm and the screen are arranged above the first semi-transparent semi-reflective diaphragm in an inclined mode and face towards the angle selection diaphragm to form a light traveling space in an enclosing mode, one side, far away from eyes, of the second semi-transparent semi-reflective diaphragm is an outwards convex curved surface, and a distance adjusting structure for adjusting the distance through opposite or reverse movement is arranged. Due to the structural arrangement, the perspective efficiency is improved; and the definition adjustment of the image seen by human eyes is realized through the position adjustment of the outermost reflector.

Description

Near-to-eye display structure

Technical Field

The invention belongs to the technical field of optical display, and particularly relates to a near-to-eye display structure.

Background

One of core technologies in the field of Augmented Reality (AR) is a transmissive optical display system, which can superimpose a computer-generated image on the real vision of a user, so that a virtual image and a real image are seamlessly fused. The combination of the digital world and the real world brings a completely new experience to the user. AR technology is now widely used in gaming, retail, education, industry, and medical fields.

At present, the augmented reality technology usually adopts a transmission type optical display mode, and comprises schemes such as a holographic grating, a reflection waveguide, a common reflection prism, a free-form surface prism and the like. In the existing optical display structure, the high-brightness screen is generally an opaque screen, and the setting position of the opaque screen generally affects the perspective effect. And, when the focal length needs to be adjusted, it is usually realized by adjusting the position of the screen. If the screen position needs to be adjusted in a rotating mode, the image can also rotate, and meanwhile the problem that the screen wiring is electrified needs to be considered. In addition, when AR glasses need be equipped with near-sighted adjusting function, need install extra near-sighted adjusting device additional, lead to overall structure increase, increase cost has reduced and has worn the experience.

Disclosure of Invention

The invention aims to solve the technical problems in the prior art. Therefore, the invention provides a near-eye display structure, which aims to avoid the influence of a screen on the perspective effect and can be convenient for realizing the definition of images viewed by human eyes.

In order to achieve the purpose, the invention adopts the technical scheme that:

the utility model provides a nearly eye shows structure, includes the angle selection diaphragm, show the structure and still include the screen, locate the angle selection diaphragm towards the first semi-transparent semi-reflection diaphragm that people's eye one side and slope set up and locate the angle selection diaphragm and keep away from the semi-transparent semi-reflection diaphragm of second of people's eye one side, first semi-transparent semi-reflection diaphragm and angle selection diaphragm and locate first semi-transparent semi-reflection diaphragm inclined top and close formation light walking space towards the screen enclosure of angle selection diaphragm, the semi-transparent semi-reflection diaphragm of second keeps away from a side of people's eye for outside convex curved surface, be equipped with through in opposite directions or reverse motion with the interval control structure of spacing between angle selection diaphragm and the semi-transparent semi-reflection diaphragm of second.

The distance adjusting structure is a rotary distance adjusting structure for adjusting the distance by adjusting the second semi-permeable semi-reflecting membrane through forward and reverse rotation.

The rotary distance adjusting structure is a thread matching structure arranged at the sleeving end of the second semi-permeable semi-reflecting diaphragm and the angle selection diaphragm.

The thread matching structure comprises an internal thread section arranged on one side of the second semi-permeable and semi-reflective membrane facing the angle selection membrane and an external thread section arranged on one side of the angle selection membrane facing the second semi-permeable and semi-reflective membrane and matched with the internal thread section.

The thread fit structure comprises an external thread section and an internal thread section, wherein the external thread section is arranged on one side of the second semi-transparent and semi-reflective membrane facing the angle selection membrane, and the internal thread section is arranged on one side of the angle selection membrane facing the second semi-transparent and semi-reflective membrane and matched with the external thread section.

The angle selection film comprises an angle selection lens and an angle selection film arranged on one side surface of the angle selection lens close to human eyes, the angle selection film is in a reflection state for incident light between zero and forty-five degrees, and is in a projection state for light at other angles.

The first semi-transparent semi-reflective membrane comprises a transparent lens and a semi-transparent semi-reflective membrane plated on the surface of the transparent lens.

The second semi-transparent semi-reflective film is a convex lens with central symmetry, one side surface of the convex lens far away from the human eyes is a curved surface with central symmetry, and the surface of the curved surface is plated with the semi-transparent semi-reflective film.

The angle selection diaphragm, the first semi-transparent semi-reflective diaphragm and the second semi-transparent semi-reflective diaphragm are arranged in a manner of sharing an optical axis with human eyes.

The display structure further comprises a concave lens arranged on the outer side of the curved surface.

The screen is an OLED or LED display screen.

The light reflection and transmission process adopting the display structure comprises the following steps: the light that the screen sent selects the diaphragm to the angle, and the light of angle selection diaphragm to this incident angle is reflective state for the light reflection of incident is to first semi-transparent semi-reflective diaphragm, and 50% light is reflected back to the angle selection diaphragm by first semi-transparent semi-reflective diaphragm, and the light angle at this moment can transmit the angle selection diaphragm, later shoots at second semi-transparent semi-reflective diaphragm, and the light that the second semi-transparent semi-reflective diaphragm reflected sees through angle selection diaphragm, first semi-transparent semi-reflective diaphragm in proper order and gets into the people's eye formation of image.

The invention has the beneficial effects that: the screen is arranged obliquely above the diaphragm, so that a perspective area is not shielded, and the screen is not required to be of a transparent structure, and the perspective efficiency is improved due to the arrangement of the structure; and the definition adjustment of the image seen by human eyes is realized through the position adjustment of the outermost reflector. Through setting to rotatory interval regulation structure, when rotation regulation, the image can not follow the rotation, need not to consider the problem that the screen was walked the line and is gone up the electricity. The near-to-eye display structure can realize the near-sightedness adjusting function of the AR glasses, is simple and convenient to use, does not need to be additionally provided with an additional near-sightedness adjusting device, and is small in size and low in cost. Compared with the switching of the myopia lenses, the continuous adjustment of 0-7D can be realized, and the matching degree with the eyesight is better.

Drawings

In order to more clearly illustrate the embodiments of the present disclosure or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only one or more embodiments of the present disclosure, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram of the structure of the present invention after adjusting the spacing;

FIG. 3 is a partially enlarged view of the threaded connection between the second semi-permeable and semi-reflective membrane and the angle selective membrane;

FIG. 4 is a schematic view of the configuration of the present invention in which concave lenses are provided on the outermost sides;

fig. 5 is a schematic structural diagram of the second compensating mirror of the present invention.

Labeled as:

1. an angle selection diaphragm; 2. a screen; 3. the human eye; 4. a first semi-transparent semi-reflective membrane; 5. a second semi-transparent semi-reflective membrane; 6. a concave lens; 7. and a second compensation mirror.

Detailed Description

The following detailed description of the embodiments of the present invention will be given with reference to the accompanying drawings for a purpose of helping those skilled in the art to more fully, accurately and deeply understand the concept and technical solution of the present invention and to facilitate its implementation. It should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. In the following embodiments, the terms "first" and "second" do not denote an absolute structural and/or functional distinction or a sequential order of execution, but are merely used for convenience of description.

As shown in fig. 1 to 3, a nearly eye shows structure, including angle selection diaphragm 1, show the structure and still include the screen 2, locate angle selection diaphragm 1 towards people's eye 3 one side and the first semi-transparent semi-reflective diaphragm 4 that the slope set up and locate angle selection diaphragm 1 and keep away from the second semi-transparent semi-reflective diaphragm 5 of people's eye 3 one side, first semi-transparent semi-reflective diaphragm 4 and angle selection diaphragm 1 and locate first semi-transparent semi-reflective diaphragm oblique top and towards the screen 2 of angle selection diaphragm enclose and close and form light walking space, the second semi-transparent semi-reflective diaphragm 5 keeps away from a side of people's eye for outside convex curved surface, be equipped with between angle selection diaphragm 1 and the second semi-transparent semi-reflective diaphragm 5 through in opposite directions or reverse motion with the interval adjustment structure of adjustment interval. In the near-eye display structure, the screen can adopt an OLED (organic light emitting diode) or LED (light emitting diode) display screen; the screen is arranged above the diaphragm in an inclined mode, a perspective area is not shielded, the screen is not required to be of a transparent structure, the structure is arranged, and the perspective efficiency is improved. The angle selection membrane is used for totally reflecting light of a screen image to the first semi-transparent semi-reflective membrane (the first reflection is total internal reflection of the lens), and receiving light transmitted in the positive and negative directions of the first semi-transparent semi-reflective membrane and the second semi-transparent semi-reflective membrane, wherein the light reflected by the first semi-transparent semi-reflective membrane is received and projected to the second semi-transparent semi-reflective membrane, and the light reflected by the second semi-transparent semi-reflective membrane is received and transmitted to the first semi-transparent semi-reflective membrane; the first semi-transparent semi-reflective membrane is used for reflecting the light part reflected by the angle selection membrane back to the angle selection membrane and transmitting the light reflected by the second semi-transparent semi-reflective membrane passing through the angle selection membrane; the second semi-transparent semi-reflective film is used for reflecting the light rays transmitted by the angle selection film. The light reflection and transmission process adopting the display structure comprises the following steps: the light that the screen sent selects the diaphragm to the angle, and the light of angle selection diaphragm to this incident angle is reflective state for the light reflection of incident is to first semi-transparent semi-reflective diaphragm, and 50% light is reflected back to the angle selection diaphragm by first semi-transparent semi-reflective diaphragm, and the light angle at this moment can transmit the angle selection diaphragm, later shoots at second semi-transparent semi-reflective diaphragm, and the light that the second semi-transparent semi-reflective diaphragm reflected sees through angle selection diaphragm, first semi-transparent semi-reflective diaphragm in proper order and gets into the people's eye formation of image.

The spacing adjusting mechanism can adopt a transverse stretching adjusting or rotating adjusting mode, and the transverse stretching adjusting needs to additionally increase the structure and increase the structure cost. Preferably, the distance adjusting structure is a rotary distance adjusting structure for adjusting the distance by adjusting the second semi-permeable and semi-reflective membrane through forward and reverse rotation. The rotary distance adjusting structure can adopt the existing adjusting modes such as button-cutting rotation, thread rotation and the like. Preferably, as shown in fig. 3, the rotary distance adjusting structure is a screw thread matching structure arranged at the sleeving end of the second semi-permeable and semi-reflective membrane and the angle selection membrane. This screw-thread fit structure accessible both structures set up the form and realize, one kind is that the screw-thread fit structure is including locating the second semi-permeable semi-reflective membrane 5 towards the internal thread section of angle selection membrane 1 one side and locating the angle selection membrane 1 towards the second semi-permeable semi-reflective membrane 5 one side and internal thread section complex external thread section. The other structure form is as follows: this screw-thread fit structure is including locating the outer screw thread section of the semi-permeable semi-reflective diaphragm of second towards angle selection diaphragm one side and locating the interior screw thread section of angle selection diaphragm towards semi-permeable semi-reflective diaphragm one side of second and outer screw thread section complex. When the distance needs to be finely adjusted, the second semi-transparent semi-reflective membrane is manually rotated forwards and backwards to enable the second semi-transparent semi-reflective membrane to move towards the human eye direction or away from the human eye direction along the optical axis, the distance between the second semi-transparent semi-reflective membrane and the angle selection membrane is adjusted, and then the definition of an image entering the human eye can be adjusted. This kind need not rotatory regulation screen when rotation regulation, and the image can not follow the rotation, need not to consider the problem that the screen was walked the line and is gone up electricity.

The angle selection film 1 comprises an angle selection lens and an angle selection film arranged on one side surface of the angle selection lens close to human eyes, wherein the angle selection film is in a reflection state for incident light between zero and forty-five degrees and in a projection state for light at other angles. The selection of the incident and transmission angles facilitates better matching of the arrangement of the near-eye display structure, so as to achieve relatively better human eye imaging effect. And processing the angle selection film on the side surface of the angle selection lens close to the human eye. The incident and transmission angles of the angle selection film are set at the above-mentioned angles.

The first semi-transparent semi-reflective membrane 2 comprises a transparent lens and a semi-transparent semi-reflective membrane plated on the surface of the transparent lens. Adopt transparent lens, the better transmission of light of being convenient for combines to plate in the semi-transparent semi-reflecting film on transparent lens surface, and the selectivity of the light of being convenient for sees through and reflects.

The second semi-transparent semi-reflective film 5 is a convex lens with central symmetry, one side surface of the convex lens far away from human eyes is a curved surface with central symmetry, and the surface of the curved surface is plated with the semi-transparent semi-reflective film. The convex lens is a movable lens, the arrangement of a central symmetrical structure is adopted, the reflection of light rays is facilitated, and meanwhile, the reflection angle is relatively more balanced, so that the image quality is improved, and the definition of reflection imaging is improved. The type of the curved surface may be a spherical surface, an aspherical surface, or a free-form surface.

In order to further improve the reasonable structural arrangement of human eye imaging, the angle selection diaphragm 1, the first semi-transparent semi-reflective diaphragm 2, the second semi-transparent semi-reflective diaphragm 5 and the human eye 3 are arranged in a coaxial mode. Because light reflects through the first semi-transparent semi-reflective membrane, and then forms a coaxial light path with the lens, in order to further increase the definition of human eye imaging, the compensation piece is preferably added, the compensation piece is used as a first compensation mirror, and compensates the light energy generated by the ambient light at the second semi-transparent semi-reflective membrane, and the compensation piece is glued and fixed with the second semi-transparent semi-reflective membrane, and when the second semi-transparent semi-reflective membrane moves, the compensation piece moves along with the second semi-transparent semi-reflective membrane.

In addition, as a further modification, as shown in fig. 4, the display structure further includes a concave lens 6 provided outside the curved surface. The concave lens can be connected at the corresponding position outside the curved surface through gluing; further increasing the desirability of imaging the display structure.

As shown in fig. 5, the lens is a solid structure, the display structure further includes a second compensation mirror 7 disposed on the outer side of the first semi-transparent and semi-reflective membrane 2, so as to compensate all light paths (including display and viewing), and the second compensation mirror 7 is fixedly connected to the first semi-transparent and semi-reflective membrane 2.

As another preferred embodiment, the second compensation mirror and the first transflective film may be disposed in a prism. When the optical lens is specifically arranged, the first semi-transparent semi-reflective film is positioned in a space formed by the second compensation lens and the inner wall surface of the side, far away from human eyes, of the prism. The structure arrangement can well form compensation for all light paths, and optimizes the structural layout.

The adjusting method adopting the near-eye display structure comprises the following steps: according to the visual field adjusting requirement of a user, the second semi-transparent semi-reflective membrane is manually rotated, when the relatively large diopter needs to be adjusted, the second semi-transparent semi-reflective membrane is positively rotated, so that the second semi-transparent semi-reflective membrane gradually approaches towards the direction of human eyes, and when the proper position is adjusted, the positive rotation of the second semi-transparent semi-reflective membrane is stopped; when the relatively small diopter needs to be adjusted, the second semi-transparent semi-reflective membrane is reversed, so that the second class head semi-reflective membrane is gradually far away from the direction departing from the human eyes, and when the proper position is adjusted, the second semi-transparent semi-reflective membrane is stopped to be reversed.

For the myopia users, because the focal power of the whole display structure is mainly provided by the second semi-transparent semi-reflective membrane, the diopter of the light path can be changed by adjusting the position of the second semi-transparent semi-reflective membrane (close to or far away from the eyes of the user), and the myopia adjustment is realized. The farther away from the eye, the smaller the diopter, the closer to the eye the greater the diopter. The distance between the second semi-transparent semi-reflective film and the human eyes can be adjusted to better adapt to the change of the myopia condition of the myopia user, and finally the myopia user can see the image clearly.

The display structure realizes the myopia adjusting function of the AR glasses through the lens of the light path, is simple and convenient to use, does not need to be additionally provided with an additional myopia adjusting device, and is small in size and low in cost. Compared with the switching of the myopia lenses, the continuous adjustment of 0-7D can be realized, and the matching degree with the eyesight is better.

Furthermore, the display structure can be used for hyperopic patients, and can be covered (adjusted towards the direction close to human eyes) by adjusting the range of front and back adjustment.

The invention is described above with reference to the accompanying drawings. Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to intimate that the scope of the disclosure, including the claims, is limited to these examples; within the idea of the present disclosure, also technical features in the above embodiments or in different embodiments may be combined, steps may be implemented in any order, and there are many other variations of the different aspects of the embodiments of the present description as described above, which are not provided in detail for the sake of brevity. It is to be understood that the specific implementations of the invention are not limited in this respect. Various insubstantial improvements are made by adopting the method conception and the technical scheme of the invention; the present invention is not limited to the above embodiments, and can be modified in various ways.

The embodiments of the present description are intended to embrace all such alternatives, modifications and variances that fall within the broad scope of the appended claims. Therefore, any omissions, modifications, equivalents, improvements, and the like that may be made within the spirit and principles of the embodiments described herein are intended to be included within the scope of the disclosure.

Claims (10)

1. The utility model provides a nearly eye shows structure, includes the angle selection diaphragm, its characterized in that, show the structure and still include the screen, locate the angle selection diaphragm towards the first semi-transparent semi-reflection diaphragm that people's eye one side and slope set up and locate the angle selection diaphragm and keep away from the semi-transparent semi-reflection diaphragm of second of people's eye one side, first semi-transparent semi-reflection diaphragm and angle selection diaphragm and locate first semi-transparent semi-reflection diaphragm oblique top and close formation light walking space towards the screen enclosure of angle selection diaphragm, the semi-transparent semi-reflection diaphragm of second keeps away from a side of people's eye for outside convex curved surface, be equipped with through in opposite directions or reverse motion with the interval control structure of spacing between angle selection diaphragm and the semi-transparent semi-reflection diaphragm of second.

2. The near-to-eye display structure of claim 1, wherein the distance adjusting structure is a rotary distance adjusting structure for adjusting the distance by adjusting the second transflective film through forward and backward rotation.

3. The near-to-eye display structure of claim 2, wherein the rotary distance adjustment structure is a screw thread matching structure disposed at the coupling end of the second transflective membrane and the angle selection membrane.

4. The near-eye display structure of claim 3, wherein the thread-engaging structure comprises an internal thread section disposed on a side of the second transflective membrane facing the angle-selecting membrane and an external thread section disposed on a side of the angle-selecting membrane facing the second transflective membrane and engaged with the internal thread section.

5. The near-to-eye display structure of claim 3 wherein the thread-engaging structure comprises an external thread section disposed on a side of the second transflective membrane facing the angle-selective membrane and an internal thread section disposed on a side of the angle-selective membrane facing the second transflective membrane and engaging with the external thread section.

6. The near-eye display structure of claim 1 wherein the angle-selective membrane comprises an angle-selective lens and an angle-selective film disposed on a side of the angle-selective lens adjacent to the eye, the angle-selective film being reflective for light incident at between zero and forty-five degrees and transmissive for light at other angles.

7. The near-to-eye display structure of claim 1 wherein the first transflective film comprises a transparent lens and a transflective film coated on a surface of the transparent lens.

8. The near-eye display structure of claim 1, wherein the second transflective film is a convex lens with central symmetry, a side of the convex lens away from the human eye is a curved surface with central symmetry, and the surface of the curved surface is plated with the transflective film.

9. The near-to-eye display structure of claim 1, wherein the angle selective membrane, the first transflective membrane and the second transflective membrane are disposed coaxially with the human eye.

10. The near-to-eye display structure of claim 1 further comprising a concave lens disposed outside the curved surface.

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