CN109991742A - A kind of virtual reality device optical module - Google Patents

Abstract

The application provides a kind of virtual reality device optical module, including the outer lens barrel nested together and inner lens cone, and is separately fixed at the outer optical mirror slip and interior optical mirror slip of the end of outer lens barrel and inner lens cone.Wherein, it is plane that outer optical mirror slip and interior optical mirror slip, which are sides, and the other side is cambered surface, and section is the lens structure of D-shaped.It is coated with the multilayer polarization membrane structure for reducing ambient light interference on the outerplanar side of outer optical mirror slip, is coated with anti-reflection film on the outer arc surface side of outer optical mirror slip.Optical module provided by the present application, membrane structure is polarized by the way that multilayer is arranged in the side of outer optical mirror slip plane, it absorbs, light in reflection or refraction external environment, ambient light is reduced on outer optical mirror slip, or enter in optical module the speck for having an impact viewing effect by outer optical mirror slip, improve the image quality of optical module, to solve the problems, such as that the eyeglass in conventional optical components is easy to be influenced by external environment.

Description

A kind of virtual reality device optical module

Technical field

This application involves wear display equipment technical field more particularly to a kind of virtual reality device optical module.

Background technique

Display equipment is worn, refers to and is worn on user's head, the equipment that optical signalling can be sent to user's eyes, including Virtual reality (Virtual Reality, VR) equipment, augmented reality equipment, game station etc..Wherein, virtual reality device because It can be for wearer brings strong feeling of immersion and is widely current.Virtual reality device, such as VR glasses, built-in independent screen, VR resource can be presented to the right and left eyes of wearer, form virtual reality imagery.Due to the screen and pendant of virtual reality device The distance of wearer's glasses is close, therefore in many virtual reality devices, built-in as disclosed in Patent No. US20170017078B Optical module provided in technical solution, to adjust VR image.

The eyeglass made of glass or resin material is equipped in the optical module of virtual reality device, eyeglass material itself Light transmittance only has 91%, and some light can be gone out in the two sides of eyeglass by surface reflection, and user wears virtual reality device When, screen brightness with higher during demonstrating picture is held between the lens of optical module due to the reflex of eyeglass It is also easy to produce the shadow of picture and reflective, influences viewing effect when user wears.In order to improve the above problem, usually in eyeglass table Plated film, the light transmittance of Lai Zengjia eyeglass is arranged in face.

In the prior art, coating process is usually and adsorbs the Coating Materials of transparent plastics material by way of plating In lens surface, lens surface is made to form very thin film layer, improvement leads to the problem of shadow and reflective.Due to virtual reality device The excessively high easy ability eyeglass of screen intensity on generate reflective and shadow, and excessively high brightness can generate dazzling sense when wearing, Therefore existing virtual reality device screen intensity all will not be too high.But the low shadow being also easy to by environment light of the brightness of screen It rings, the picture for observing wearer is unintelligible, in addition, since the eyeglass of optical module is easy and external environment during wearing In object contact so that being damaged to coating structure.

Summary of the invention

This application provides a kind of virtual reality device optical module, with solve the eyeglass in conventional optical components be easy by The problem of being influenced to external environment.

Virtual reality device optical module provided by the present application, comprising: outer lens barrel, outer optical mirror slip, inner lens cone and interior Optical mirror slip, wherein；

The outer lens barrel and the inner lens cone are to nest together columnar structured, and the outer optical mirror slip is fixed on institute The outboard end of outer lens barrel is stated, the interior optical mirror slip is fixed on the inner lens cone close to the end of virtual reality device screen position It sets；

The outer optical mirror slip and the interior optical mirror slip are that side is plane, and the other side is cambered surface, and section is D-shaped Lens structure；The multilayer polarization membrane structure for reducing ambient light interference is coated on the outerplanar side of the outer optical mirror slip, Anti-reflection film is coated on the outer arc surface side of the outer optical mirror slip.

Optionally, trilamellar membrane structure, the triple-layer coating structure, remote are coated on the outerplanar side of the outer optical mirror slip On direction from the outerplanar side, plated film sequence is successively are as follows: 1/4 polarizing coating, reflection type polarization film and absorption polarizing coating.

Optionally, the outer lens barrel is equipped with the external fixation of step structure far from the end of the screen, described outer solid Determine the outerplanar side edge that platform is bonded the outer optical mirror slip；

The inner lens cone is equipped with interior fixed station close to the end of the screen, and the interior fixed station is bonded the interior optical frames The inner plane side edge of piece.

Optionally, protection glass is covered on the outerplanar side of the outer optical mirror slip, the protection glass is that area is big In or equal to the outer optical mirror slip planar optics structure, the protection glass is for protecting, in the outer optical mirror slip The multilayer polarization membrane structure being arranged on the outerplanar side.

Optionally, the thickness H of the protection glass is less than or equal to, and the external fixation and the outer lens barrel are close to described The distance between the end face of outer optical mirror slip D.

Optionally, the protection glass is coated with anti-reflection film far from the side of the outer optical mirror slip.

Optionally, the dura mater and anti-pollution film for protecting anti-reflection film are also coated on the protection glass.

Optionally, the inner plane side of the interior optical mirror slip is coated with anti-reflection film, the inner arc surface side plating of the interior optical mirror slip There is the anti-part permeable membrane in part, for the anti-part permeable membrane in part along axis, the direction far from the screen is reflection；The part Anti- part permeable membrane is transmitted along axis close to the direction of the screen.

Optionally, the optical module further includes the planar optics for being covered on the screen surface, and the planar optics is remote From anti-reflection film and antireflective coating is coated on a side plane of the screen, the planar optics is used to reduce the reflection of the screen Rate.

The application also provides a kind of virtual reality device, including front housing, rear shell and above-mentioned optical module, in which:

The front housing is identical as the edge contour of the rear shell, and the front housing connect to be formed for storing with the rear shell State the cavity of optical module and electronic device；

It is set in the rear shell there are two mirror hole, the diameter in the mirror hole is greater than or equal to optical module China and foreign countries lens barrel Outer diameter, the mirror hole is for being fixedly mounted the optical module.

From the above technical scheme, the application provides a kind of virtual reality device optical module, comprising: outer lens barrel, outer Optical mirror slip, inner lens cone and interior optical mirror slip, wherein outer lens barrel and inner lens cone be nest together it is columnar structured, outside Optical mirror slip and interior optical mirror slip are separately fixed at the end of outer lens barrel and inner lens cone, put jointly to the picture that screen is shown Greatly.Outer optical mirror slip and interior optical mirror slip are that side is plane, and the other side is cambered surface, and section is the lens structure of D-shaped.Outside The multilayer polarization membrane structure for reducing ambient light interference, the extrados of outer optical mirror slip are coated on the outerplanar side of optical mirror slip Anti-reflection film is coated on side.

Optical module provided by the present application polarizes membrane structure by the way that multilayer is arranged in the side of outer optical mirror slip plane, inhales It receives, the light in reflection or refraction external environment reduces ambient light and enters on outer optical mirror slip, or through outer optical mirror slip The speck that viewing effect is had an impact in optical module improves the image quality of optical module, to solve in conventional optical components Eyeglass be easy the problem of being influenced by external environment.

Detailed description of the invention

In order to illustrate more clearly of the technical solution of the application, letter will be made to attached drawing needed in the embodiment below Singly introduce, it should be apparent that, for those of ordinary skills, without creative efforts, also Other drawings may be obtained according to these drawings without any creative labor.

Fig. 1 is a kind of structural schematic diagram of virtual reality device optical module；

Fig. 2 is a kind of assembling figure of virtual reality device optical module；

Fig. 3 is the structural schematic diagram of part A in the embodiment of the present application；

Fig. 4 is the structural schematic diagram of part B in the embodiment of the present application；

Fig. 5 is the structural schematic diagram of Local C in the embodiment of the present application；

Fig. 6 is optical module diplopia image-forming principle schematic diagram in the embodiment of the present application；

Fig. 7 is a kind of structural schematic diagram of virtual reality device.

Specific embodiment

Embodiment will be illustrated in detail below, the example is illustrated in the accompanying drawings.In the following description when referring to the accompanying drawings, Unless otherwise indicated, the same numbers in different drawings indicate the same or similar elements.Implement described in following embodiment Mode does not represent all embodiments consistent with the application.It is only and be described in detail in claims, the application The example of the consistent system and method for some aspects.

The optical module of virtual reality device is mounted between screen and wearer's face, the light being made of multiple lens Learn adjustment mechanism.Optical module is mainly used for the picture that will be shown on screen, is presented on wearer at the moment by the refraction of lens, The picture in screen still can be clearly watched when keeping the facial dimension screen of wearer close.And optical module can be with Image-forming range of the screen-picture in human eye is adjusted, to adapt to the wearer of different eyesight status.It should be noted that this place The image-forming range said refers to screen relative to the equivalent image-forming range between human eye, and during actual wear, virtual reality is set The actual range between screen and wearer's eye in standby is fixed and invariable, and adjustment one of the optical module to image-forming range As be so that the focal length of entire optical module be made to change, and then to be adjusted by adjusting the position of eyeglass movable in optical module The size and clarity of picture observed by whole wearer, are equivalent to and are adjusted to image-forming range.

It is a kind of structural schematic diagram of virtual reality device optical module referring to Fig. 1.It can from structure shown in fig. 1 Out, optical module provided by the present application includes: outer lens barrel 1, outer optical mirror slip 2, inner lens cone 3 and interior optical mirror slip 4.Its China and foreign countries Lens barrel 1 and inner lens cone 3 are to nest together columnar structured, and outer optical mirror slip 2, the two group are fixed on outer optical mirror slip 2 At static lens barrel, interior optical mirror slip 4 is fixed on inner lens cone 3, the two composition activity eyeglass is between inner lens cone 3 and outer lens barrel 1 Clearance fit, with guaranteeing inner lens cone 3 and under the premise of coaxial outer lens barrel 1, realization inner lens cone 3 is relative to outer lens barrel 1 in axis The movement in direction and rotation in circumferencial direction.The outboard end of outer lens barrel 1 refers to, end position of the outer lens barrel 1 far from screen 6 It sets, i.e., in the section Example of the application, as shown in Figure 1, one end far from screen 6 is equipped with ladder-like on 1 inner wall of outer lens barrel Structure, for fixed outer optical mirror slip 2, the other end of outer lens barrel 1 is connect with the bracket of screen 6, and in inner lens cone 3 close to screen 6 end position is again provided with step structure, is used to optical mirror slip 4 in fixed.

Further, outer optical mirror slip 2 and interior optical mirror slip 4 can directly be bonded in epi mirror by adhesives such as glue The side of the step structure of cylinder 1 and inner lens cone 3 can also install one additional after outer optical mirror slip 2 is put into outer lens barrel 1 Positioning ring compresses outer optical mirror slip 2 by the effect of positioning ring, to fix its position.For using adhesive to be fixed Eyeglass and lens barrel, fixation have good dust-proof effect；And eyeglass and mirror for using positioning ring to be fixed Cylinder will not cause adhesive to pollute eyeglass, and eyeglass can be very easily then while guaranteeing that position is fixed It is taken out in lens barrel, being detachably connected between eyeglass and lens barrel is realized, in order to clean and replace eyeglass.

The optical module of above-mentioned virtual reality device, in actual operation, virtual reality imagery pass through internal processor Processing, the image of right and left eyes is respectively displayed among two screens of the left and right side built in virtual reality device.In order to make The wearer of virtual reality device does not generate dazzling feeling when watching VR image while providing stronger feeling of immersion, above-mentioned void Quasi- real world devices can reduce the brightness of a part of picture, the viewing sense of wearer is improved with this during picture is demonstrated By.But the reduction of picture brightness but also optical module imaging effect, the interference by external light source is easy, for example, passing through Light shield device edge projects the light into viewing areas, it is easy on the surface of outer optical mirror slip 2, hot spot or diplopia are formed, These hot spots and diplopia occur directly in wearer at the moment, often seriously affect the picture imaging effect of virtual reality device Fruit.In order to improve influence of the external light source to virtual reality device optical module imaging effect, virtual reality provided by the present application Equipment optical module has following characteristics.

As shown in Fig. 2, virtual reality device optical module provided by the present application, comprising: outer lens barrel 1, outer optical mirror slip 2, Inner lens cone 3 and interior optical mirror slip 4, wherein outer lens barrel 1 is to nest together columnar structured, outer optical frames with inner lens cone 3 Piece 2 is fixed on the outboard end of outer lens barrel 1, and interior optical mirror slip 4 is fixed on inner lens cone 3 close to the end of virtual reality device screen 6 Portion position.In order to mitigate influence of the external light source to optical module imaging effect, as shown in Figure 3, Figure 4, skill provided by the present application It further include following structure feature on the basis of above structure in art scheme, that is, outer optical mirror slip 2 and interior optical mirror slip 4 are equal It is side is plane, the other side is cambered surface, and section is the lens structure of D-shaped；It is coated on the outerplanar side 21 of outer optical mirror slip 2 Multilayer for reducing ambient light interference polarizes membrane structure, is coated with anti-reflection film on the outer arc surface side 22 of outer optical mirror slip.

In the present embodiment, outer optical mirror slip 2 and interior optical mirror slip 4 are the eyeglass that section is D-shaped, in actual use, D The plane side of shape eyeglass can make two optical mirror slips only need to set on outer lens barrel 1 and inner lens cone 3 in order to the fixation of eyeglass Setting simple step structure can be completed the fixation of eyeglass, and the other side of interior optical mirror slip 4 is that cambered surface can not only be used to Change the image-forming range of picture, issuing eyeglass by screen When light irradiates, the light of mirror-reflection will not direct irradiation on screen 6, so as to avoid the reflective in screen 6 of cambered surface side On have an impact the hot spot of viewing effect.

The cambered surface side effect having the same of the cambered surface side of outer optical mirror slip 2 and interior optical mirror slip 4, but due to outer optical frames Piece 2 is more nearly external light source, therefore is easier to be influenced by the environment light source in multiple directions on outer optical mirror slip 2.And And since screen 6 emits beam the collective effect with incident ray in external environment, in the cambered surface side of outer optical mirror slip 2 peace Surface side may all assemble light, have an impact the diplopia and hot spot of imaging effect, therefore in technical solution provided by the present application, The multilayer polarization membrane structure for reducing ambient light interference, and outer optical frames are coated on the outerplanar side 21 of outer optical mirror slip 2 Anti-reflection film is coated on the outer arc surface side 22 of piece.

For outer optical mirror slip 2, cambered surface side is coated with anti-reflection film, and anti-reflection film can be used in increasing the transmissivity of eyeglass, can With when ambient light generates the aggregation of light in cambered surface side, most of light forms the cambered surface side for being transmitted through outer optical mirror slip 2, keeps away Exempt to form hot spot or diplopia in cambered surface side.In addition, eyeglass can be more due to being coated with anti-reflection film in the cambered surface side of outer optical mirror slip 2 Picture shown by good presentation screen 6.The multilayer polarization membrane structure of its planar side setting can pass through the polarization of each tunic Light in external environment is deviated and is absorbed by effect, is reduced light in external environment and is penetrated outer optical mirror slip 2 into light It learns in component, so that the light alleviated in external environment has an impact picture.

Further, as shown in figure 3, in the section Example of the application, what the planar side 21 of outer optical mirror slip 2 was arranged Multilayer polarizes membrane structure, mainly includes triple-layer coating, i.e., on the direction far from the outerplanar side 21, plated film sequence is successively Are as follows: 1/4 polarizing coating, reflection type polarization film and absorption polarizing coating.In actual use, the light irradiation in external environment When on to outer optical mirror slip 2, absorption polarizing coating is first passed through, absorption polarizing coating absorbs environment light, reduces environment light It is irradiated to the planar side 21 of outer optical mirror slip 2, and then reduces environment light and forms stronger hot spot on outer optical mirror slip 2, is influenced The viewing of VR image.

Component environment light is after through absorption polarizing coating, then is transmitted on reflection type polarization film, by reflective A part of the effect of polarizing coating, ambient is reflected into again on absorption polarizing coating, and absorption polarizing coating is passed through It absorbs, so that a large amount of light to be absorbed without to the eye that can project wearer.

By the effect of above-mentioned two layers of plated film, still there may be the ambient light not being reflected or absorbed partially, this portions After light splitter is by absorption polarizing coating and reflection type polarization film, into 1/4 polarizing coating, changed by the effect of 1/4 polarizing coating The direction of illumination of ambient light makes a part of out of plumb in the environment light penetrated act on the planar side 21 of outer optical mirror slip 2 On, so that the light reflected by the planar side 21 of outer optical mirror slip 2 will not directly be reflected back the eye of wearer, mitigate reflex The hot spot of formation influences the viewing of VR image.

It should be noted that since most of virtual reality devices all have the light shield device for stopping external environment light, The face that general light shield device passes through contact wearer, it is sufficient to outside by most of environment light blocking, therefore, be mentioned in the application To environment light refer to, due to the face contour difference of different wearers, and transmitted from light shield device and facial contact gap Into the environment light in viewing region, and, the light that virtual reality device screen issues, in the face for being irradiated to wearer, and in face The light of portion's diffraction.Obviously, in the application, the intensity of environment light is weaker, also just because of environment light is weaker, is polarized by above-mentioned multilayer The effect of film will not just have an impact the hot spot of viewing on outer optical mirror slip 2.

In addition, since the multilayer polarization membrane structure on outer optical mirror slip 2 is while mitigating environment shadow sound, also further Brightness of image of the on-screen displays before wearer is reduced, when the picture brightness of display is inherently lower, multilayer is inclined Vibrating diaphragm may will affect the image quality of VR image, therefore, in technical solution provided by the present application, can be avoided external environmental light Under the premise of influence, the coating layers of polarizing coating should be reduced to the greatest extent.For example, for different virtual reality devices, light shield device It is different to the facial adaptability of different wearers, it is also different by light shield device and the facial gap extraneous luminous intensity entered, It is very weak into the ambient light intensity in viewing range when the leakproofness of light shield device is preferable when virtual reality device is larger, for Optical module used in this virtual reality device can reduce coating layers in the planar side 21 of outer optical mirror slip 2, such as only One layer of plated film of absorption polarizing coating is set.

When virtual reality device is more frivolous, light shield device is weaker for the adaptability of different wearers, by connecing The ambient light intensity that touching gap enters viewing areas is stronger, for optical module used in this virtual reality device, not only Have other than above-mentioned three layers of polarization membrane structure, and the leakproofness of light shield device and the display brightness of screen 6 can be regarded, into one The coating layers that step increases polarizing coating are e.g. further added by one layer of absorption polarization between 1/4 polarizing coating and reflection type polarization film Film, to reduce the influence of environment light.

From the above technical scheme, virtual reality device optical module provided by the present application, in actual use, scope The interior optical mirror slip 4 installed and outer optical mirror slip 2 are coaxially disposed on cylinder 3 and outer lens barrel 1, the picture for jointly showing screen 6 at Eye as arriving wearer.In optical module provided by the present application, anti-reflection film is set to subtract in the cambered surface side 22 of outer optical mirror slip 2 Few ambient forms hot spot in the aggregation of cambered surface side 22, and multilayer polarizing coating knot is arranged in the planar side 21 of outer optical mirror slip 2 Structure, by absorbing, reflection and part are reflected, and are further reduced the view that environment light is irradiated into wearer by outer optical mirror slip 2 In wild range, mitigates environment light and the viewing effect of VR image is had an impact.

In the section Example of the application, as shown in figure 3, outer lens barrel 1 is equipped with step structure far from the end of screen 6 External fixation 11, external fixation 11 is bonded 21 edge of outerplanar side of outer optical mirror slip 2；Inner lens cone 3 is close to the end of screen 6 Equipped with interior fixed station 31, interior fixed station 31 is bonded 41 edge of inner plane side of interior optical mirror slip 4.External fixation 11 can not only be used In fixed outer optical mirror slip 2, and can be by the planar side of outer optical mirror slip 2 and outer lens barrel 1 close to the end face of wearer's eye Between be spaced a distance, so that mitigating outer optical mirror slip 2 is influenced by external environment in use and is scratched.Due to Coating Materials on each eyeglass is generally the lower plastic material of hardness, therefore is easy to scratch occur in use, and this stroke Trace can have an impact the shadow of viewing when being penetrated by ambient lighting, substantially reduce the image quality of optical module.

Further, as shown in figure 3, in order to avoid the multilayer polarizing coating on outer optical mirror slip 2 is scratched damage, in this Shen In a kind of technical solution that please be provide, it is covered on the outerplanar side 21 of outer optical mirror slip 2 for protecting multilayer to polarize membrane structure Protection glass 5, protection glass 5 be area be greater than or equal to outer optical mirror slip 2 planar optics structure.In the present embodiment, prevent Protecting lens 5 can choose the flat glass of high transparency or resin material is made, protection glass 5 can by outer optical mirror slip 2 with External environment is isolated, to be avoided in use using the wearability of glass or resin, the multilayer polarization of outer optical mirror slip 2 Occurs scratch in membrane structure.

In the present embodiment, protected completely to enable the multilayer polarization membrane structure of the external optical mirror slip 2 of protection glass 5 to realize Shield, the area of protection glass 5 be greater than or equal to outer optical mirror slip 2 21 area of planar side, i.e. protection glass 5 will be completely covered In the planar side of outer optical mirror slip 2.To facilitate installation, protection glass 5 should be to have same shape with outer optical mirror slip 2 Circular flat eyeglass, in the assembling process of virtual reality device, can in advance after plated film outer optical mirror slip 2 planar side 21 The higher protection glass 5 of a light transmittance is bonded, then two eyeglasses are commonly mounted in outer lens barrel 1；Or it first will protection Eyeglass 5 is mounted in outer lens barrel 1, then installs outer optical mirror slip 2, and two eyeglasses are pressed on one by cricoid fixing piece It rises.

It should be noted that there is centainly convex relative to rear shell 9 since the application provides outer lens barrel 1 after assembling It rises, and during the installation process, the mirror hole 91 for needing to be arranged in rear shell 9, when setting protection glass 5 on outer optical mirror slip 2 When, need to reserve certain installation space for protection glass 5, therefore the area of protection glass 5 should not be too large.In the present embodiment In, if the area of protection glass 5 is excessive, outer lens barrel 1 can be made in the position for installing protection glass 5, the wall thickness of lens barrel It is relatively thin, so that influencing the stability in use of protection glass 5.It, can also be into addition, if the area of protection glass 5 is excessive One step increases the internal diameter of outer lens barrel 1, and optical module is made integrally to be not easy to install, and more increase that environment light enters optical module can It can property.In summary effect, in the present embodiment, preferential selection make the area phase of protection glass 5 with the outer optical mirror slip 2 Deng, and the shape of mirror surface is identical.

Further, as shown in figure 3, the thickness H of protection glass 5 is less than or equal to, external fixation 11 and outer lens barrel 1 are close The distance between the end face of outer optical mirror slip 2 D.In technical solution provided by the present application, it joined on the outer optical mirror slip 2 of protection Multilayer polarizes the protection glass 5 of membrane structure, but also increases ambient while increase protection glass 5 and be radiated at protection glass On 5 and then a possibility that reflective is generated, it is right in the present embodiment in order to avoid protection glass 5 has an impact the reflective of viewing effect In the thickness H of protection glass 5, if H be greater than external fixation 11 and outer lens barrel 1 between the end face of outer optical mirror slip 2 away from From D, the thickness of protection glass 5 can be made blocked up, can not only occupy the installation space of outer optical mirror slip 2, make outer optical mirror slip 2 more Close to interior optical mirror slip 4, imaging and focusing range are influenced, and can be since the refraction action of 5 pairs of light of protection glass is in protective glasses Diplopia is formed on piece 5.Therefore in the present embodiment, the thickness of protection glass 5 should be reduced to the greatest extent under the premise of guaranteeing wear-resistant strength Degree.

In the present embodiment, in order to avoid protection glass 5 generates reflective, side of the protection glass 5 far from outer optical mirror slip 2 It is additionally provided with anti-reflection film, anti-reflection film can be further improved the light transmittance of protection glass 5, reduce protection glass 5 close to wearer For the albedo of ambient light on eye outer surface, helmet is reduced when wearing because of the hot spot of reflective formation.Into one Step ground, in order to protect the anti-reflection film on protection glass 5, can be coated with anti-reflection film in the outer surface of protection glass 5 in the present embodiment Afterwards, dura mater and anti-pollution film are further added by.Wherein, dura mater can avoid anti-reflection film quilt in use under the premise of guaranteeing light transmittance It scratches；Anti-pollution film, which can reduce protection glass 5, to be stained with and invites dust or greasy dirt, improves the light transmittance of protection glass 5, and convenient for wiping Eyeglass.

In a kind of technical solution, as shown in figure 4, the inner plane side 41 of interior optical mirror slip 4 is coated with anti-reflection film, interior optical frames The inner arc surface side 42 of piece 4 is coated with the anti-part permeable membrane in part, and the anti-part permeable membrane in part is along axis, to the side far from screen 6 To for reflection；The anti-part permeable membrane in part is transmitted along axis to the direction close to screen 6.In skill provided by the present application In art scheme, due to sharing two eyeglasses of coaxial arrangement in entire optical module, wherein interior optical mirror slip 4 is closer to void The screen 6 of quasi- real world devices, when screen 6 demonstrates picture, the light that screen 6 is issued will be radiated at the inner arc of interior optical mirror slip 4 On surface side 42, by the refraction action of inner arc surface side 42, the image demonstrated on screen 6 is amplified.And in order to improve from light The quality for watching display picture in component is learned, in the present embodiment, the anti-part permeable membrane in part, portion are coated on interior optical mirror slip 4 Point anti-part permeable membrane is reflection on the direction far from screen 6, so that the light that screen 6 issues be reflected, do not make its into Enter wearer within sweep of the eye；And be transmission on the direction close to screen 6, i.e., wearer can be along moving closer to screen The content shown on screen is clearly watched on 6 direction.In technical solution provided by the present application, on interior optical mirror slip 4 The increased anti-part permeable membrane in part can filter out the relatively strong dazzling light of the sending of screen 6, and reduce display to a certain extent The granular sensation of picture promotes the image quality shown on screen 6, can be obtained higher quality without high-resolution screen Picture.

In the present embodiment, as shown in fig. 6, optical module during the work time, the road that normal optical path such as light I is propagated Diameter, but due to the reflex of interior optical mirror slip 4, lead to the reflection light for occurring light II and light III in optical module.Its In, light II is reflected to form by the inner arc surface side 42 of interior optical mirror slip 4, this some light by interior optical mirror slip 4 due to being reflected Focal power is insufficient, will not directly be imaged in optical module, therefore light II is smaller on image quality influence minor impact；And light On screen 6 because of its direct vertical irradiation, imaging also can be entered wearer by screen reflection within sweep of the eye to line III, because This light III can be affected to image quality at a fuzzy picture.

In the present embodiment, if defining screen exit light energy is 1:

Emanated energy=1 of light III × 4 transmissivity of interior optical mirror slip × 4 transmissivities of interior optical mirror slip × screen 6 reflects Rate × 4 transmissivity of interior optical mirror slip；

I emanated energy=1 of light × 4 transmissivity of interior optical mirror slip × 4 reflectivity of interior optical mirror slip；

For optical module provided by the present application, light III does not influence viewing effect, to meet: I emanated energy of light/light III emanated energy >=256 of line, i.e. less than 1 gray scale, therefore, in the present embodiment:

If being coated with 50% transmission on interior optical mirror slip 4, when the anti-part permeable membrane in part of 50% reflection,

III emanated energy=1 × 0.5 × 0.5 × 0.04 of light × 0.5=0.005；

I emanated energy=1 × 0.5 of light × 0.5=0.25；

At this point, therefore I emanated energy of light/light, III emanated energy=50 < 256 are coated with 50% on interior optical mirror slip 4 Transmission, when the anti-part permeable membrane in part of 50% reflection, light III can have an impact the output picture of optical module.

And if it is 75% that interior optical mirror slip 4, which is coated with reflectivity, when the anti-part permeable membrane in part that transmissivity is 25%,

III emanated energy=1 × 0.25 × 0.25 × 0.04 of light × 0.25=0.000625；

I emanated energy=1 × 0.25 of light × 0.75=0.1875；

At this point, I emanated energy of light/light, III emanated energy=300 > 256, therefore, the plating on above-mentioned interior optical mirror slip 4 Film scheme can be to avoid generating fuzzy picture on the screen.In addition, passing through light accordingly since the reflectivity of screen plated film is higher It is darker to learn the screen-picture that component is observed, i.e., effectively output energy is smaller, not only reduces image quality, and but also light Component imaging effect is learned to be easy to be influenced by external environment light source.

Further, in order to while guaranteeing image quality, reduce influence of the light III to imaging effect, in this implementation In example, the coated reflection rate on the inner arc surface side 42 of interior optical mirror slip 4 should be greater than or be equal to 73.25%, it may be assumed that

III emanated energy=1 × 0.2675 × 0.2675 × 0.04 of light × 0.2675=0.00076565；

I emanated energy=1 × 0.2675 of light × 0.7325=0.19594；

Therefore, I emanated energy of light/light, III emanated energy=256, just as the critical value of reflectivity.

In a kind of technical solution, as shown in figure 5, optical module 10 further includes the planar optics for being covered on 6 surface of screen 7, planar optics 7 is far from anti-reflection film and antireflective coating is coated on a side plane of screen 6, planar optics 7 is for reducing screen 6 Reflectivity.In the present embodiment, the reflectivity of screen 6 can be reduced by increasing planar optics 7, and then avoid light III in screen Upper generation vague image, such as when screen 6 is after installing planar optics 7 of plated film additional, the reflectivity of screen 6 drops to from 4% 0.4%, then:

III emanated energy=1 × 0.5 × 0.5 × 0.004 of light × 0.5=0.0005；

I emanated energy=1 × 0.5 of light × 0.5=0.25；

At this point, I emanated energy of light/light, III emanated energy=500 > 256, to avoid light III wearer's Vague image is generated within sweep of the eye, influences viewing experience.

In addition, some light is 41 reflection of inner plane side by interior optical mirror slip 4 due in reflected light line III At, therefore, in the present embodiment, in order to reduce the reflected intensity of light III, also set on the inner plane side 41 of interior optical mirror slip 4 There is anti-reflection film, by the way that anti-reflection film is arranged, the picture for not only being presented optical module is more clear, and can also reduce inner plane side 41 reflecting power avoids generating diplopia.

Based on the optical module of above-mentioned virtual reality device, the application also provides a kind of virtual reality device, including front housing 8, rear shell 9 and above-mentioned optical module 10, wherein:

Front housing 8 is identical as the edge contour of rear shell 9, and front housing 8 connect formation with rear shell 9 for storing optical module 10 and electricity The cavity of sub- device.In virtual reality device provided by the present application, electronic device refers to virtual reality imagery resource conversion At the device of vision signal, mainly include screen, display driving part, controller, aspect sensor, signal transmission component and Sensor worn etc. is assisted, by the cooperating between all parts, virtual reality device is made to demonstrate corresponding VR resource.

It being set in rear shell 9 there are two mirror hole 91, the diameter in mirror hole 91 is greater than or equal to the outer diameter of optical module China and foreign countries lens barrel 1, Mirror hole 91 is for being fixedly mounted optical module 10.Two mirror holes 91 are symmetrical arranged relative to the middle position of virtual reality device, The distance between two mirror holes 91 should meet between the eyes of wearer in the zone of reasonableness of distance.Since optical module needs are whole A to run through rear shell 9, in order to make rear shell 9 not interfere with the installation of optical adjustment system, the diameter in mirror hole 91 should be greater than or be equal to light Learn the diameter of the outer lens barrel 1 of adjustment system.But it due to biggish 91 diameter of mirror hole, will increase between mirror hole 91 and outer lens barrel 1 Gap enters dust in cavity by gap, influences the heat dissipation of electronic device, therefore the diameter in mirror hole 91 should not be too large.It is excellent Choosing, the diameter in mirror hole 91 is equal to the diameter of outer lens barrel 1.

From the above technical scheme, the application provides a kind of virtual reality device optical module, comprising: outer lens barrel 1, outer Optical mirror slip 2, inner lens cone 3 and interior optical mirror slip 4, wherein outer lens barrel 1 is the cylinder-shaped knot nested together with inner lens cone 3 Structure, outer optical mirror slip 2 and interior optical mirror slip 4 are separately fixed at the end of outer lens barrel 1 and inner lens cone 3, show jointly to screen 6 Picture amplifies.Outer optical mirror slip 2 and interior optical mirror slip 4 are that side is plane, and the other side is cambered surface, and section is D-shaped Lens structure.The multilayer polarization membrane structure for reducing ambient light interference is coated on the outerplanar side 21 of outer optical mirror slip 2, outside Anti-reflection film is coated on the outer arc surface side 22 of optical mirror slip.

Optical module provided by the present application polarizes membrane structure by the way that multilayer is arranged in the side of outer 2 plane of optical mirror slip, inhales Receive, reflection or refraction external environment in light, reduce ambient light on outer optical mirror slip 2, or by outer optical mirror slip 2 into The speck for entering to have an impact viewing effect in optical module improves the image quality of optical module, to solve conventional optical components In eyeglass be easy the problem of being influenced by external environment.

In above embodiments, the optical module is not only limited to virtual reality device, applies also for any wear and sets It is standby, and the helmet is specifically including but not limited to virtual reality device, augmented reality equipment, game station, mobile computing Equipment and other wearable computers etc..

Similar portion cross-reference between embodiment provided by the present application, specific embodiment provided above is only It is several examples under the total design of the application, does not constitute the restriction of the application protection scope.For those skilled in the art For member, any other embodiment expanded without creative efforts according to application scheme all belongs to In the protection scope of the application.

Claims (10)

1. a kind of virtual reality device optical module characterized by comprising outer lens barrel (1), outer optical mirror slip (2), inner lens cone (3) and interior optical mirror slip (4), wherein；

The outer lens barrel (1) and the inner lens cone (3) are to nest together columnar structured, and the outer optical mirror slip (2) is solid It is scheduled on the outboard end of the outer lens barrel (1), the interior optical mirror slip (4) is fixed on the inner lens cone (3) close to virtual reality The end position of device screen (6)；

The outer optical mirror slip (2) and the interior optical mirror slip (4) are that side is plane, and the other side is cambered surface, and section is D The lens structure of shape；The multilayer being coated on the outerplanar side (21) of the outer optical mirror slip (2) for reducing ambient light interference is inclined Diaphragm structure is coated with anti-reflection film on the outer arc surface side (22) of the outer optical mirror slip.

2. optical module according to claim 1, which is characterized in that the outerplanar side (21) of the outer optical mirror slip (2) On be coated with trilamellar membrane structure, the triple-layer coating structure, on the direction far from the outerplanar side (21), plated film sequence is successively Are as follows: 1/4 polarizing coating, reflection type polarization film and absorption polarizing coating.

3. optical module according to claim 1, which is characterized in that end of the outer lens barrel (1) far from the screen (6) Portion is equipped with the external fixation (11) of step structure, and the external fixation (11) is bonded the outerplanar of the outer optical mirror slip (2) Side (21) edge；

The inner lens cone (3) is equipped with interior fixed station (31) close to the end of the screen (6), and the interior fixed station (31) is bonded institute State inner plane side (41) edge of interior optical mirror slip (4).

4. optical module according to claim 3, which is characterized in that the outerplanar side (21) of the outer optical mirror slip (2) On be covered with protection glass (5), the protection glass (5) be area be greater than or equal to the outer optical mirror slip (2) plane mirror Chip architecture, the protection glass (5) are arranged on the outerplanar side (21) of the outer optical mirror slip (2) for protecting Multilayer polarizes membrane structure.

5. optical module according to claim 4, which is characterized in that the thickness H of the protection glass (5) is less than or waits In the external fixation (11) and the outer lens barrel (1) are close to the distance between the end face of the outer optical mirror slip (2) D.

6. optical module according to claim 4, which is characterized in that the protection glass (5) is far from the outer optical frames The side of piece (2) is coated with anti-reflection film.

7. optical module according to claim 6, which is characterized in that be also coated on the protection glass (5) for protecting The dura mater and anti-pollution film of anti-reflection film.

8. optical module according to claim 1, which is characterized in that the inner plane side (41) of the interior optical mirror slip (4) It is coated with anti-reflection film, the inner arc surface side (42) of the interior optical mirror slip (4) is coated with the anti-part permeable membrane in part, and the anti-part in the part is thoroughly For film along axis, the direction far from the screen (6) is reflection；The anti-part permeable membrane in part is along axis, the close screen The direction of curtain (6) is transmission.

9. optical module according to claim 1, which is characterized in that the optical module (10) further include be covered on it is described The planar optics (7) on screen (6) surface, the planar optics (7) far from the screen (6) a side plane on be coated with anti-reflection film And antireflective coating, the planar optics (7) are used to reduce the reflectivity of the screen (6).

10. a kind of virtual reality device, which is characterized in that including front housing (8), rear shell (9) and claim 1-9 any one The optical module (10), wherein:

The front housing (8) is identical as the edge contour of the rear shell (9), and the front housing (8) connect formation with the rear shell (9) and uses In the cavity for storing optical module (10) and electronic device；

It is set on the rear shell (9) there are two mirror hole (91), the diameter of the mirror hole (91) is greater than or equal in the optical module The outer diameter of outer lens barrel (1), the mirror hole (91) is for being fixedly mounted the optical module (10).