阅读说明：本技术 一种三光路高光效立体投影装置 (Three-light-path high-luminous-efficiency stereoscopic projection device ) 是由 邓贤俊 于 2021-08-13 设计创作，主要内容包括：一种三光路高光效立体投影装置,其特征在于,包括有：由4个三角形棱镜贴合组成的偏振分光棱镜组件；位于偏振分光棱镜上下两侧的每侧各1个或2个或3个波片或者是可使偏振光的振动面旋转90度的TN液晶屏；由一个半凹透镜和一个凸透镜组成的透镜组件；位于上侧波片之后的上反射镜；位于下侧波片之后的下反射镜；分别位于上、中、下的三个偏振调制器；控制电路模块。该装置可明显降低产品的体积、重量,同时有效提升观众所看到的立体图像的亮度、清晰度并降低色差。(A three-optical path high-light-efficiency stereoscopic projection device is characterized by comprising: a polarization beam splitting prism assembly formed by jointing 4 triangular prisms; each side of the upper and lower sides of the polarization beam splitter prism is respectively provided with 1 or 2 or 3 wave plates or a TN liquid crystal screen which can rotate the vibration plane of the polarized light by 90 degrees; a lens assembly composed of a half-concave lens and a convex lens; an upper mirror located behind the upper wave plate; a lower mirror located behind the lower wave plate; three polarization modulators respectively positioned at the upper part, the middle part and the lower part; and a control circuit module. The device can obviously reduce the volume and the weight of a product, effectively improve the brightness and the definition of a stereoscopic image seen by audiences and reduce chromatic aberration.)

1. A three-optical path high-light-efficiency stereoscopic projection device is characterized by comprising: the polarization beam splitting prism assembly is formed by jointing 4 triangular prisms, decomposes an incident beam into a middle transmission beam in a P polarization state, an upper reflection beam in an S polarization state and a lower reflection beam in the S polarization state, consists of 4 prisms, comprises 1 obtuse-angle triangular prism with an obtuse angle of 156 +/-2 degrees, 1 isosceles right-angle prism and 2 identical acute-angle triangular prisms, and is a cuboid after the 4 prisms are jointed; each side of the upper side and the lower side of the polarization beam splitter prism is respectively provided with 1 or 2 or 3 wave plates or a TN liquid crystal screen which can rotate the vibration plane of the polarized light by 90 degrees and is used for adjusting the upper reflected light beam in the S polarization state and the lower reflected light beam in the S polarization state into the upper reflected light beam in the P polarization state and the lower reflected light beam in the P polarization state; the lens assembly consists of a semi-concave lens and a convex lens and is used for adjusting the size range of the transmitted light beam; an upper mirror located behind the upper wave plate for adjusting the direction of propagation of the upper reflected beam; a lower reflector behind the lower wave plate for adjusting the propagation direction of the lower reflected light beam; the three polarization modulators are respectively positioned at the upper part, the middle part and the lower part and are used for modulating the transmission light beam, the upper reflection light beam and the lower reflection light beam into left circularly polarized light and right circularly polarized light according to a frame sequence; and a control circuit module.

2. The three-optical-path high-light-efficiency stereoscopic projection device of claim 1, wherein: and 1 or 2 or 3 wave plates on each side of the upper side and the lower side of the polarization beam splitter prism are respectively 1 half wave plate.

3. The three-optical-path high-light-efficiency stereoscopic projection device of claim 1, wherein: each side of the polarization beam splitter prism positioned at the upper side and the lower side is respectively provided with 1 or 2 or 3 wave plates which are respectively 2 quarter wave plates, and the 2 quarter wave plates are attached together.

4. The three-optical-path high-light-efficiency stereoscopic projection device of claim 1, wherein: and each side of the polarization beam splitter prism, which is positioned at the upper side and the lower side of the polarization beam splitter prism, is provided with 1 or 2 or 3 wave plates which are respectively one-half wave plates.

5. The three-optical-path high-light-efficiency stereoscopic projection device of claim 1, wherein: and each side of the polarization beam splitter prism, which is positioned at the upper side and the lower side of the polarization beam splitter prism, is provided with 1 or 2 or 3 wave plates which are 3 half wave plates respectively.

6. The three-optical-path high-light-efficiency stereoscopic projection device of claim 1, wherein: the polarization modulator is a liquid crystal light valve type polarization modulator, and the retardation amount of the polarization modulator is a quarter wavelength.

7. The three-optical-path high-light-efficiency stereoscopic projection apparatus according to claim 1, 2, 3, 4 or 5, wherein: the three-optical-path high-light-efficiency stereoscopic projection device is characterized by further comprising an electric support, wherein the electric support can move the three-optical-path high-light-efficiency stereoscopic projection device to the front of a lens of a film projector when a film is played in a 3D state, and can move the three-optical-path high-light-efficiency stereoscopic projection device to the position, far away from the lens of the film projector, of the other end when the film is played in a 2D state.

8. The three-optical-path high-light-efficiency stereoscopic projection apparatus according to claim 1, 2, 3, 4 or 5, wherein: the polarization modulator also comprises an upper linear polarizer, a middle linear polarizer and a lower linear polarizer which are respectively positioned in front of the three polarization modulators and used for filtering the transmitted light beams to enable the transmitted light beams to be completely changed into linearly polarized light.

9. The three-optical-path high-light-efficiency stereoscopic projection apparatus according to claim 1, 2, 3, 4 or 5, wherein: the linear polarizer at the upper side is positioned in front of the upper reflecting mirror, the linear polarizer at the lower side is positioned in front of the lower reflecting mirror, the linear polarizer at the middle is positioned in front of the polarization modulator at the middle, and the linear polarizers at the upper side, the middle side and the lower side are all used for filtering the transmitted light beam and enabling the transmitted light beam to be completely changed into linearly polarized light.

10. The three-optical-path high-light-efficiency stereoscopic projection device of claim 1, wherein: the device also comprises a single-stage single-shear height lifting mechanism or a single-stage double-shear height lifting mechanism.

Technical Field

The invention relates to a three-dimensional image optical polarization device, in particular to a three-optical-path high-luminous-efficiency three-dimensional image optical polarization device.

Background

At present, movie theaters commonly use movie projectors, stereoscopic image optical polarizing devices, polarized 3D glasses and metal screens to watch 3D movies. However, the existing stereoscopic image optical polarization device generally has the problems that the brightness loss of light is serious, the color of the light passing through the stereoscopic image optical polarization device is easy to generate color cast, and the like, so that the film watching effect and the film watching experience of audiences are influenced. Meanwhile, the device also has the defects of large volume, heavy weight and the like.

Disclosure of Invention

The invention aims to overcome the defects and shortcomings of the prior art and provides a three-optical-path high-luminous-efficiency stereoscopic image optical polarization device comprising a polarization beam splitting prism assembly, a lens assembly, an upper reflector, a lower reflector, a polarization modulator and a wave plate, so that the viewing effect and the viewing experience of audiences are effectively improved.

The purpose of the invention is realized by the following technical scheme: 1. a three-optical path high-light-efficiency stereoscopic projection device is characterized by comprising: the polarization beam splitting prism assembly is formed by jointing 4 triangular prisms, decomposes an incident beam into a middle transmission beam in a P polarization state, an upper reflection beam in an S polarization state and a lower reflection beam in the S polarization state, consists of 4 prisms, comprises 1 obtuse-angle triangular prism with an obtuse angle of 156 +/-2 degrees, 1 isosceles right-angle prism and 2 identical acute-angle triangular prisms, and is a cuboid after the 4 prisms are jointed; each side of the upper side and the lower side of the polarization beam splitter prism is respectively provided with 1 or 2 or 3 wave plates or a TN liquid crystal screen which can rotate the vibration plane of the polarized light by 90 degrees and is used for adjusting the upper reflected light beam in the S polarization state and the lower reflected light beam in the S polarization state into the upper reflected light beam in the P polarization state and the lower reflected light beam in the P polarization state; the lens assembly consists of a semi-concave lens and a convex lens and is used for adjusting the size range of the transmitted light beam; an upper mirror located behind the upper wave plate for adjusting the direction of propagation of the upper reflected beam; a lower reflector behind the lower wave plate for adjusting the propagation direction of the lower reflected light beam; the three polarization modulators are respectively positioned at the upper part, the middle part and the lower part and are used for modulating the transmission light beam, the upper reflection light beam and the lower reflection light beam into left circularly polarized light and right circularly polarized light according to a frame sequence; and a control circuit module.

Furthermore, each side of the polarization beam splitter prism located at the upper side and the lower side is respectively 1 or 2 or 3 wave plates which are respectively 1 half wave plate.

Furthermore, each side of the polarization beam splitter prism located at the upper side and the lower side is respectively provided with 1 or 2 or 3 wave plates which are respectively 2 quarter wave plates, and the 2 quarter wave plates are attached together.

Furthermore, each side of the polarization beam splitter prism located at the upper side and the lower side is respectively provided with 1 or 2 or 3 wave plates which are respectively 2 half wave plates.

Furthermore, each side of the polarization beam splitter prism located at the upper side and the lower side is respectively provided with 1 or 2 or 3 wave plates which are respectively 3 half wave plates.

Further, the polarization modulator is a liquid crystal light valve type polarization modulator and the retardation amount thereof is a quarter wavelength.

The three-optical-path high-light-efficiency stereoscopic projection device can be moved to the front of a lens of a film projector by the electric bracket when the film is played in a 3D state, and can be moved to a position with the other end far away from the lens of the film projector when the film is played in a 2D state.

Furthermore, the device also comprises an upper linear polarizer, a middle linear polarizer and a lower linear polarizer which are respectively positioned in front of the three polarization modulators and used for filtering the transmitted light beam to enable the transmitted light beam to be completely changed into linearly polarized light.

The linear polarizer at the upper side is positioned in front of the upper reflecting mirror, the linear polarizer at the lower side is positioned in front of the lower reflecting mirror, the linear polarizer at the middle is positioned in front of the polarization modulator at the middle, and the linear polarizers at the upper side, the middle side and the lower side are all used for filtering the transmitted light beam and enabling the transmitted light beam to be completely linearly polarized.

Furthermore, the device also comprises a single-stage single-shear height lifting mechanism or a single-stage double-shear height lifting mechanism.

According to the three-optical-path high-luminous-efficiency stereoscopic projection device, the polarization beam splitting prism assembly, the lens assembly, the upper reflector, the lower reflector, the polarization modulator and the 1-3 wave plates on the upper side and the lower side are formed by bonding the 4 triangular prisms, so that the light loss and the color cast phenomenon of light can be effectively reduced, and the volume weight of equipment is obviously reduced.

Drawings

FIG. 1 is a schematic view of a three-optical-path high-light-efficiency stereoscopic projection apparatus according to a preferred embodiment of the present invention;

FIG. 2 is a schematic view of another preferred embodiment of a three-optical-path high-light-efficiency stereoscopic projection apparatus according to the present invention

Detailed Description

The invention is further described with reference to the drawings and the preferred embodiments.

FIG. 1 is a schematic diagram of a preferred embodiment of the present invention.

As shown in fig. 1, the three-optical path high light efficiency stereoscopic projection apparatus of the present embodiment includes: the polarization beam splitting prism assembly formed by jointing 1 and 4 triangular prisms comprises 1 obtuse angle triangular prism 20 with an obtuse angle of 156 +/-2 degrees, 1 isosceles right-angle prism 21 and 2 identical acute angle triangular prisms 22 and 23; 2, a lens assembly consisting of a semi-concave lens 31 and a convex lens 32; 3, an upper reflector 11; 4, a lower reflector 12; 5, polarization modulators 41, 42, 43; 6, 2 half-wave plates 33, 34 located on the upper side; 7, 2 half-wave plates 35, 36 on the lower side; 8, linear polarizers 51, 52, 53; 9, a control circuit module 60.

The polarization beam splitting prism assembly in the three-optical-path high-light-efficiency stereoscopic projection device of the embodiment is composed of 4 prisms, and includes 1 obtuse-angle triangular prism 20 with an obtuse angle of 156 ± 2 degrees, 1 isosceles right-angle prism 21, and 2 identical acute-angle triangular prisms 22 and 23. The 4 prisms are in a cuboid shape after being attached, the surfaces of two waists of the isosceles right-angle prism 21 are polarization beam splitting coating surfaces, and the longest side of the isosceles right-angle prism 21 is an emergent surface; the plane of the longest side of the obtuse triangular prism 20 is an incident plane. When light is incident from the obtuse triangular prism 20 and reaches the isosceles right-angle prism 21, the incident light beam is decomposed into a middle transmission light beam in a P polarization state, an upper reflection light beam in an S polarization state, and a lower reflection light beam in an S polarization state. The P polarization state and the S polarization state are different polarizations, incident beams are decomposed into reflected beams and transmitted beams which are different in polarization state, corresponding polarization modulators can be used for modulating the reflected beams or the transmitted beams respectively, and therefore the total loss of luminous intensity is reduced compared with a scheme of using the polarization modulators for modulating all incident light speeds. The upper mirror 11 and the lower mirror 12 are used to adjust the trajectories of the upper reflected beam and the lower reflected beam, respectively, so that the reflected beam and the transmitted beam can be projected to form exactly the same stereoscopic image. And the lens assembly consisting of a semi-concave lens 31 and a convex lens 32 is used for adjusting the size range of the middle transmitted beam, and the sizes of the projected images of the middle transmitted beam and the upper and lower reflected beams are consistent after adjustment. The upper and lower reflected light beams pass through the polarization splitting prism assembly and then pass through 2 half-wave plates (wave plates 33 and 34 on the upper side and 35 and 36 on the lower side) on each of the upper and lower sides of the polarization splitting prism assembly, which is one of the advantages of this embodiment. The 2 half-wave plates are adopted for superposition, so that the vibration plane of the S polarized light can be rotated by 90 degrees, the reflected light beam in the S polarization state is changed into the reflected light beam in the P polarization state, and the polarization states of the middle transmitted light beam, the upper reflected light beam and the lower reflected light beam are all changed into the P polarization state in a unified manner, and the two half-wave plates have the advantages of effective achromatism and the like: the common half-wave plate is a non-achromatic wave plate, and is generally only used under specific wavelength, and different wavelengths cannot be used at the same time, which is not economical in practice, and the use of the non-monochromatic light cannot be regarded as the right, but the two half-wave plates of the embodiment can make the birefringent dispersion of the device linearly change in a certain waveband by adopting the combination of two different birefringent materials, so that the retardation of the device is independent of the wavelength, thereby effectively eliminating or slowing down chromatic aberration, and an effective chromatic aberration elimination (slowing down) scheme can effectively improve the viewing effect and viewing experience of users. The intermediate transmitted, upper reflected, and lower reflected beams, all of which have been converted to the P polarization state (after reflection by the upper mirror), then pass through three linear polarizers 51, 52, 53, which are located before the polarization modulator to filter the transmitted beam to become fully linearly polarized. The intermediate transmitted beam, the upper reflected beam, and the lower reflected beam, which are completely linearly polarized and are all in the P-polarization state, are then passed through three polarization modulators 41, 42, 43, which are liquid crystal shutter type polarization modulators with a retardation of a quarter wavelength, which is typically a 90-degree twisted TN type liquid crystal device, and the polarization modulators 41, 42, 43 are used to modulate the intermediate transmitted beam, the upper reflected beam, and the lower reflected beam into left circularly polarized light and right circularly polarized light, respectively, in frame order. The projector also comprises a control circuit module 60 which is used for obtaining a synchronous signal from a GPIO interface or a 3D INTERFACE interface or an equivalent interface of the film projector and generating a relevant control signal to act on the polarization modulator, so that the polarization modulators 41, 42 and 43 can be respectively used for modulating the middle transmission light beam, the upper reflection light beam and the lower reflection light beam into left-handed circularly polarized light and right-handed circularly polarized light according to the frame sequence and forming an image on the metal screen or the equivalent screen. Further (or when necessary), parameters such as the angles of the upper reflecting mirror 11 and the lower reflecting mirror 12 are adjusted, and parameters such as the relative positions of the half concave lens 31 and the convex lens 32 in the lens component are adjusted in a matching manner, so that the intermediate transmitted light beam, the upper reflected light beam and the lower reflected light beam can form a clear image with high coincidence on the metal screen. The user can see a 3D image with high brightness, high definition and good elimination (slowing down) of chromatic aberration by matching with passive circular polarization 3D glasses worn by the user.

FIG. 2 is a schematic diagram of another preferred embodiment of the present invention.

As shown in fig. 2, the three-optical path high light efficiency stereoscopic projection apparatus of the present embodiment includes: the polarization beam splitting prism assembly formed by jointing 1 and 4 triangular prisms comprises 1 obtuse angle triangular prism 20 with an obtuse angle of 156 +/-2 degrees, 1 isosceles right-angle prism 21 and 2 identical acute angle triangular prisms 22 and 23; 2, a lens assembly consisting of a semi-concave lens 31 and a convex lens 32; 3, an upper reflector 11; 4, a lower reflector 12; 5, polarization modulators 41, 42, 43; 6, 2 half-wave plates 33, 34 located on the upper side; 7, 2 half-wave plates 35, 36 on the lower side; 8, linear polarizers 51, 52, 53; 9, a control circuit module 60.

The present embodiment is different from the previous embodiment in that: the upper, middle and lower linear polarizers of the previous embodiment are respectively positioned in front of the three polarization modulators; in the upper, middle and lower linear polarizers of the present embodiment, the upper linear polarizer is located before the upper mirror, the lower linear polarizer is located before the lower mirror, and the middle linear polarizer is located before the middle polarization modulator. This will make the structure more compact and miniaturized, be favorable to further reducing the volume and the weight of equipment.

The foregoing is a more detailed description of the invention in connection with specific preferred embodiments and it is not intended that the invention be limited to these specific details. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.