KR20120063361A - Polarizing glasses for watching 3 dimensional stereography image displayed and 3 dimensional stereography image display system having the same - Google Patents

Abstract

PURPOSE: Polarizing glasses for watching three-dimensional images and a three-dimensional image display system including the same are provided to respectively arrange a left-eye lens and a right-eye lens for reversing a front side and a rear side, thereby providing a normal three-dimensional image in forward and reverse operations of a liquid crystal display device. CONSTITUTION: A first polarizing plate has a first transmission axis. The first polarizing plate is formed on one outer side surface of a liquid crystal display device. A second polarizing plate is formed on the other outer side surfaces while having the first transmission axis. The first transmission axis of the second polarizing plate is perpendicular to the first transmission axis of the first polarizing plate. A patterned retarder is attached on the outer side surface of the second polarizing plate. The patterned retarder comprises phase patterns with different optical axes. Glasses(145) for watching 3D images comprise a fixing unit(147), a polarizing film, and a phase film.

Description

Polarizing glasses for 3D video viewing and 3D video realization system having the same {polarizing glasses for watching 3 dimensional stereography image displayed and 3 dimensional stereography image display system having the same}

The present invention relates to a 3D image realization system, and more particularly, to a polarized glasses for viewing 3D image and a 3D image realization system having the same.

In general, a liquid crystal display device is composed of two opposite electrodes and a liquid crystal layer formed therebetween. The liquid crystal molecules of the liquid crystal layer are driven by an electric field generated by applying a voltage to the two electrodes. Liquid crystal molecules have polarization property and optical anisotropy. Polarization property means that when liquid crystal molecules are placed in an electric field, charges in the liquid crystal molecules are attracted to both sides of the liquid crystal molecules, and the direction of molecular arrangement changes according to the electric field. Refers to changing the path or polarization state of the emitted light differently according to the incident direction or the polarization state of the incident light due to the elongated structure of the liquid crystal molecules and the aforementioned molecular arrangement direction.

Accordingly, the liquid crystal layer may exhibit a difference in transmittance due to voltages applied to the two electrodes, and display the 2D image by changing the difference for each pixel.

Meanwhile, recently, liquid crystal display devices capable of expressing 3D images have been developed in response to increasing user demand for liquid crystal display devices capable of realizing a 3D image.

In general, stereoscopic images expressing 3D are made by the principle of stereo vision through two eyes, using the parallax of two eyes, that is, binocular disparity which appears because the eyes are about 65 mm apart. A liquid crystal display device capable of displaying a stereoscopic image has been proposed.

In more detail, 3D image implementation, the left and right eyes looking at the liquid crystal display see different 2D images, and when these two images are transmitted to the brain through the retina, the brain accurately fuses each other and the original 3D image. It is to reproduce the sense of depth and the real sense of this phenomenon is commonly called stereography (stereography).

Techniques for displaying 3D stereoscopic images in a device having a 2D image display such as a liquid crystal display device include a stereoscopic image display by a special glasses, an autostereoscopic stereoscopic display, and a holographic display system.

The three-dimensional image display method by the special glasses transmits the polarized glasses method using the vibration direction or the rotation direction of the polarized light, the time-divided glasses method alternately presenting while switching the left and right images, and the light of different brightness in the left and right. It can be divided into concentration difference method.

In addition, the autostereoscopic 3D display method has a parallax barrier method that allows the user to separate and observe the image through a vertical grid-shaped aperture in front of each image corresponding to the left and right eyes, and a semi-cylindrical type. The lens may be divided into a lenticular method using a lenticular plate having a stripe arrangement of a cylindrical lens and an integral photography method using a lens plate shaped like a fly's eye.

Among them, a 3D image display device using polarized glasses is most commonly used.

1 is a view showing a 3D image implementation system using a conventional polarized glasses.

As shown in the drawing, the 3D image realization system using the conventional special glasses has a liquid crystal display device 10 displaying a large image and a lambda / 4 patterned retarder attached to an outer surface of the liquid crystal display device 10 ( 40 and spectacles 45 which selectively transmit images passing through the λ / 4 patterned retarder 40 from the liquid crystal display device 10.

First, the liquid crystal display device 10 includes an array substrate 15, a color filter substrate 20, a liquid crystal layer interposed between the two substrates 15 and 20, and the two substrates 15, 20) The first and second polarizing plates 25 and 30 attached to the outer side surfaces of the first and second polarizing plates 25 and 30 are not shown in the figure, but the outer side surfaces of the first polarizing plate 25 include a backlight unit (not shown). In this case, the first and second polarizing plates 25 and 30 are configured such that their transmission axes perpendicularly cross each other.

On the other hand, the λ / 4 patterned retarder 40 provided on the outer surface of the second polarizing plate 30 attached to the outer surface of the color filter substrate 20 is located at an odd pixel line in the horizontal direction. Corresponding to the region P, the light emitted from the pixel region P through the second polarizing plate 30 is in a right circularly polarized state, and left circularly polarized light corresponding to the pixel region P positioned in even-numbered pixel lines. The birefringent material whose phase is internally changed so as to be in a state is patterned so as to alternate with each other for each pixel region P line. The lambda / 4 patterned retarder 40 for causing light to be left circularly polarized or right circularly polarized is characterized in that it has a lambda / 4 phase difference.

In the λ / 4 patterned retarder 40 in which the phase difference of λ / 4 is generated, the optical axis is +45 degrees with respect to the transmission axis of the second polarizing plate 30 provided in the liquid crystal display device 10, respectively. -45 degrees.

Therefore, according to the configuration of the conventional 3D image realization system 1 described above, the liquid crystal display device 10 is positioned in an odd pixel line after passing through the λ / 4 patterned retarder 40. Light in the right circularly polarized state is emitted from the region, and light in the left circularly polarized state is emitted from the pixel region located in the even-numbered pixel line. In this case, in the liquid crystal display device 10, the left eye image signal incident to the left eye of the user is stored in the pixel area P positioned in the odd pixel line. For example, a 3D image may be realized by applying a right eye image signal incident to the right eye.

On the other hand, the glasses 45 for viewing the 3D image as one set with the liquid crystal display device 10 including the lambda / 4 patterned retarder 40 having the above-described configuration, the conventional glasses made of a transparent glass material It is characterized in that the polarizing film (50a, 50b) and λ / 4 phase film (not shown) attached to the.

In this case, the first λ / 4 phase film (not shown) serves to selectively convert right circularly polarized light into linearly polarized light in the left eye lens 45a corresponding to the left eye of the user when the 3D image viewing glasses 45 are worn. And a first polarizing film 50a, and a second λ / 4 phase film (not shown) and a second polarizing film which serve to selectively convert left circularly polarized light into linearly polarized light on the right eye lens 45b. 50b is attached.

Accordingly, the liquid crystal display device 10 in which a user wears 3D image glasses 45 having such a configuration, alternately line-by-line, and displays left and right eye image data and displays images having different circularly polarized states. When viewing the image through the left eye image through the left eye lens 45a, the right eye image is incident through the right eye lens 45b, so the user can view the 3D image by combining these two images. It becomes possible.

On the other hand, as described above, the liquid crystal display device 10 for displaying images suitable for left-eye and right-eye image data on a line-by-line basis is generally as shown in FIG. 2A (showing the arrangement of the liquid crystal display device in forward driving). Although it does not matter when forward driving is performed, reverse driving (rotation of the display area by 180 degrees relative to the display area during forward driving), as shown in FIG. 2B (the arrangement of the liquid crystal display device in reverse driving) is shown. Driving in the state), the lambda / 4 patterned retarder 40 is attached to match the forward driving, it is impossible to view the 3D image.

That is, referring to FIG. 3 (a diagram illustrating a 3D image realization system using a conventional polarized glasses and showing reverse driving), a liquid crystal display with a λ / 4 patterned retarder 40 attached to a forward driving is illustrated. When reverse driving is performed using the apparatus 10, the image is output by alternately starting the left eye image and the right eye image for each line in the same way as the forward driving, but? Is already attached to the liquid crystal display device 10. It is understood that the / 4 patterned retarder 40 has a phase inverted configuration, that is, a right circular polarization and a left circular polarization alternate in a forward driving, and a left circular polarization and a right circular polarization alternate in a reverse driving. Can be.

Therefore, in this configuration, the light passing through the λ / 4 patterned retarder 40 in the reverse driving is generated from the light emitted from these pixel areas P corresponding to the pixel area P located in the odd-numbered pixel lines. In the left circularly polarized state, the light from these pixel regions is in the right circularly polarized state corresponding to the pixel region P positioned in the even-numbered pixel line.

As a result, when looking at the reverse driving liquid crystal display device 10 through the 3D image viewing glasses 45, the left eye image is recognized by the right eye image of the right eye and the user sees an abnormal image. 3D image implementation is not achieved.

To solve this problem, it is necessary to separate the forward drive model and the reverse drive model and change the λ / 4 patterned retarder attachment direction for each model, which causes problems such as increased management cost and lower production cost efficiency.

Accordingly, the present invention has been made to solve the above problems, and the liquid crystal display device with the λ / 4 patterned retarder is forward driven as a 3D image viewing glasses having one type of patterned retarder array state. Another object of the present invention is to provide a 3D image viewing glasses capable of viewing a normal 3D image in response to both cases of reverse driving and a 3D image implementation system having the same.

In order to achieve the above object, a 3D image realization system according to an embodiment of the present invention, a liquid crystal display device; A first polarizing plate having a first transmission axis on one outer side of the liquid crystal display and a second polarizing plate having a first transmission axis orthogonal to the first transmission axis on the other outer side; A pattern pattern attached to an outer surface of the second polarizing plate and having a phase pattern having different optical axes corresponding to odd-numbered pixel lines and even-numbered pixel lines among the plurality of pixel areas provided in the display area; More; A left and right eye lens, a frame bordering the lens, and fixing means for fixing each lens to the frame, and selectively transmitting or blocking light having a different phase for each line from the patterned retarder to each of the lenses. And a 3D image viewing glasses with a polarizing film and a phase film attached thereto, wherein the 3D image viewing glasses rotate the fixing means so as to change the positions of the front and rear surfaces of the left and right eye lenses to which the polarizing film is attached. It can be rotated as a feature.

In this case, the phase pattern is a λ / 4 phase pattern for changing the phase by λ / 4 to linearly polarized light to the left or right polarized light, the patterned retarder is a λ / 4 patterned retarder, the phase film Is a λ / 4 phase film that converts left circularly or right circularly polarized light into linearly polarized light.

In addition, the 3D image viewing glasses, the eyeglasses are connected to the frame seated on the user's ear, and the bridge for supporting the left eye frame and the right eye frame is provided, the left and right eye lenses are fixed Each frame is provided with a rotating means for inserting the fixing means to rotate the respective lenses independently. In this case, the rotating means is preferably a bearing or a rotating hinge, the rotating means is provided with a rotary tick or the engaging portion is characterized in that the respective lenses can be maintained continuously rotated 180 degrees and 360 degrees.

In addition, the opposite ends of the fixing means is provided with an insertion groove for inserting the edge of the lens, the fastening means for fixing the insertion groove and the lens through the insertion groove and the edge of each lens is provided with It is characteristic.

Glasses for watching 3D images according to an embodiment of the present invention, the left and right eye lenses; First and second frames bordering the left and right eye lenses, respectively; A bridge connecting and supporting the first and second frames; Glasses legs connected to the first and second frames, respectively; Fixing means positioned at each end of each of the first and second frames bordering the left and right eye lenses so as to face each other so as to form one rotation axis within each frame; And a rotation means provided at the side ends of the first and second frames, respectively, and the fixing means being inserted to rotate the fixing means facing each other as the rotating shaft.

At this time, the left and right eye lens is characterized in that the polarizing film and the phase film is attached to selectively transmit or block light.

In addition, the rotating means is preferably a bearing or a rotating hinge, the rotating means is provided with a rotary tick or the engaging portion is characterized in that the respective lenses can be maintained continuously rotated 180 and 360 degrees.

In addition, the spectacles may be rotated by hinges provided in the first and second frames.

Glasses for viewing 3D images according to the present invention are configured to reverse the front and rear surfaces of the left eye lens and the right eye lens, respectively, so that the left eye and right eye lenses when the liquid crystal display equipped with the patterned retarder performs forward driving. When viewing the front side of the lens to correspond to the liquid crystal display and reverse driving, the left and right eye lenses are rotated by 180 degrees around the fixing means so that the back side of each lens faces the liquid crystal display device. By viewing in the state, the normal 3D image can be viewed in both forward driving and reverse driving of the liquid crystal display.

1 is a view showing a 3D image realization system using a conventional polarized glasses.
2A and 2B are diagrams illustrating an arrangement of a liquid crystal display device in forward driving and reverse driving in a conventional 3D image implementing system, respectively.
3 is a view illustrating a 3D image realization system using a conventional polarized glasses and showing a reverse driving time.
4 is a diagram illustrating a 3D image implementation system according to an embodiment of the present invention.
5 is a view of the glasses for watching 3D images provided in the 3D image realization system according to an embodiment of the present invention.
Figure 6 is an enlarged view of a portion where the fixing means provided in the glasses for viewing 3D images according to an embodiment of the present invention.

Hereinafter, with reference to the drawings will be described in detail the configuration of the 3D image implementation system according to the present invention.

FIG. 4 is a diagram illustrating a 3D image realization system according to an exemplary embodiment of the present invention. For convenience of description, in the patterned ritter, forward driving and reverse driving are respectively divided into left and right sides based on a center part. 5 is a view of the 3D image viewing glasses provided in the 3D image realization system according to an embodiment of the present invention, Figure 6 is a portion in which the fixing means provided in the 3D image viewing glasses according to an embodiment of the present invention is disposed Is an enlarged view.

3D image realization system 100 according to an embodiment of the present invention is a liquid crystal display device 110 for displaying an image having a first and a second polarizing plate (125, 130) on both outer surfaces largely, and the liquid crystal display device Λ / 4 patterned retarder 140 provided on the outer surface of the second polarizing plate 130 of (110), polarizing films 150a and 150b arranged to have transmission axes perpendicular to each other for the left eye and the right eye, and λ / It consists of the glasses 145 with a four-phase film attached.

First, the liquid crystal display 110 includes an array substrate 115, a color filter substrate 120, a liquid crystal layer (not shown) interposed between the two substrates 115 and 120, and the two substrates 115, 120. Although not shown in the drawings, the first and second polarizing plates 125 and 130 attached to the outer side surfaces of the first polarizing plate 125 include a backlight unit (not shown).

The array substrate 115 is connected to the gate and data lines 116 and 118 and the two lines 116 and 118 that define a plurality of pixel regions P and cross each other to correspond to each pixel region P. A thin film transistor Tr is provided, connected to the thin film transistor Tr, and provided with a pixel electrode 119.

The color filter substrate 120 includes a black matrix 121 corresponding to a boundary of each pixel region P, and a color filter layer 122 including red, green, and blue color filter patterns sequentially corresponding to each pixel region P. FIG. ) And a color filter layer 122 are disposed on the front surface of the common electrode (not shown).

At this time, a common electrode (not shown) provided on the front surface of the color filter substrate 120 according to the mode of the liquid crystal display device 110 is the pixel electrode 119 in each pixel region P of the array substrate 115. It may be formed alternately with).

On the other hand, the first and second polarizing plates (125, 130) is characterized in that the transmission axis is configured to perpendicularly cross each other.

In addition, the λ / 4 patterned retarder 140 provided on the outer surface of the second polarizing plate 130 corresponds to the pixel region P positioned in the odd pixel line in the horizontal direction during forward driving. The light emitted through the second polarizing plate 30 from P is in a right circularly polarized state, and in response to the pixel region P positioned in the even-numbered pixel line, the left circularly polarized state is reversed. Corresponding to the pixel region P positioned in the odd-numbered pixel lines in the horizontal and horizontal directions, the light emitted from the pixel region P through the second polarizing plate 30 is left circularly polarized, and the even-numbered pixel lines In order to correspond to the pixel region P, the birefringent material whose phase is changed internally so as to be in a right circularly polarized state so as to alternate with each other in each pixel region P line. It is characterized by a pattern.

In this case, in the λ / 4 patterned retarder 140 such that the phase difference of λ / 4 is generated, the optical axes thereof are respectively + relative to the transmission axis of the second polarizing plate 130 provided in the liquid crystal display device 110. It features 45 degrees and -45 degrees.

On the other hand, the 3D image viewing glasses 145 forming a set with the liquid crystal display device 110 including the lambda / 4 patterned retarder 140 having the above-described configuration is for the left eye made of a transparent glass material and Right eye lenses 145a and 145b, a frame 141 bordering each of the lenses 145a and 145b, and two frames coupled to the frame 141 and a hinge (not shown) and seated on a rotatable user's ear. It is composed of a bridge 143 that connects the spectacle legs 142 and the frame 141 bordering each of the left and right eye lenses 145a and 145b.

In this case, polarizing films 150a and 150b and λ / 4 retardation film (not shown) are attached to each of the lenses 145a and 145b, and each of the lenses 145a and 145b borders the frame 141. It is characterized in that the user is selectively configured to rotate the respective lenses 145a and 145b in the front-back direction by fixing only one axis instead of the front surface.

At this time, the left eye lens 145a and the right eye lens 145b are parallel to the bridge 143 on the basis of the bridge 143 connecting the frames 141 bordering each of the two lenses 145a and 145b. And a fixing means 147 for fixing the lenses 145a and 145b to the frame 141 on one axis with one axis in a direction.

The fixing means 147 has an insertion groove 148 into which the edges of the lenses 145a and 145b can be inserted at one end thereof, and the fixing means 147 is fixed while the edges of the lenses are inserted into the insertion grooves. By fastening by means of fastening means 149 penetrating the means 147 and the lenses 145a and 145b, the respective lenses 145a and 145b remain fixed to the frame 141 bordering them. .

At this time, the fixing means 147 having the insertion groove 148 is characterized in that the other end is fixed to the inner side end of the frame 141 to be rotatable. The fixing means 147 is fixed to the frame 141 to be rotatable can be implemented by various methods.

For example, a small bearing is provided in the frame 141 and the other end of the fixing means 147 is inserted into the bearing (not shown), or the rotating hinge (not shown) of the frame 141 is mounted. The fixing means 147 may be configured to be rotatable by inserting the other end of the fixing means 147 into the rotating hinge (not shown). In this case, the fixing means 147 is rotated by 180 degrees and 360 degrees by internal adjustment of a bearing (not shown) or a rotating hinge (not shown) provided in the frame 141 (not shown) Or it is characterized by being able to continuously maintain the state rotated 180 degrees and 360 degrees by a locking portion (not shown).

On the other hand, due to this configuration characteristic, both side ends of the left and right eye lenses 145a and 145b are fastened to the insertion grooves 148 of the fixing means 147, respectively, and surround the respective lenses 145a and 145b. The fastening means 147 is fastened so that the other end is inserted into the frame 141 so as to be positioned on the same axis in the frame 141, so that the left and right eye lenses 145a and 145b are respectively the same at both ends thereof. Since the state is fixed to the shaft is characterized in that the fixing means 147 can be rotated by the rotation axis.

In this case, the left eye lens 145a of the 3D image viewing glasses 145 having such a configuration includes a first λ / 4 phase film (not shown) and a first role of selectively converting circularly polarized light into linearly polarized light. The first polarizing film 150a is attached, and the second λ / 4 phase film (not shown) and the second polarizing film 150b serve to selectively convert circularly polarized light into linearly polarized light on the right eye lens 145b. ) Is attached.

Therefore, the user wears the 3D image viewing glasses 145 having such a configuration, and the liquid crystal display 110 for displaying images having different circularly polarized states in which left and right eye image data are applied alternately line by line. When viewing an image through the left eye image, the left eye image is incident through the left eye lens 145a, and the right eye image is incident through the right eye lens 145b. You can watch.

At this time, the 3D image viewing glasses 145 having the above-described configuration is a state in which the user wears the 3D image viewing glasses with the left and right eye lenses 145a and 145b using the fixing means 147 as the rotation axis, respectively. There is a feature that can be rotated back and forth to change the front and back of each lens (145a, 145b).

Therefore, when the liquid crystal display 110 performs forward driving, after wearing the 3D image viewing glasses 145 without rotating the left and right eye lenses 145a and 145b, the liquid crystal display device ( 110, the left eye image passes through the λ / 4 patterned retarder 140 to form a right polarized state from the pixel area P of the odd-numbered pixel lines. 145a) and the linearly polarized light causes the left eye image to enter the left eye normally, and from the pixel region P of the even-numbered pixel line, the right eye image passes the λ / 4 patterned retarder 140 and is left circularly polarized. Since the left circularly polarized light is incident to the right eye lens 145b and is linearly polarized, the right eye image is incident to the right eye, so that normal 3D images can be viewed.

In addition, when the liquid crystal display 110 performs reverse driving, the left and right eye lenses 145a and 145b are rotated by 180 degrees to view the 3D image while the front and rear surfaces of the lenses 145a and 145b are changed. After wearing the eyeglasses 145, the 3D image may be viewed by viewing the liquid crystal display 110.

That is, when the fixing means 147 is rotated to rotate the left and right eye lenses 145a and 145b so that their front and rear sides are changed, the left and right eye lenses 145a and 145b rotated 180 degrees. Their roles are reversed, and the left eye lens 145a rotated 180 degrees serves to linearly polarize the left circularly polarized light, and the right eye lens 145b rotated 180 degrees linearly polarizes the right circularly polarized light. It serves as a polarization state.

Accordingly, in this case, the left eye image is left circularly polarized from the pixel region P of the odd pixel line through the λ / 4 patterned retarder 140, and the left circularly polarized light is rotated 180 degrees. The left eye image is normally incident to the left eye by being incident to one left eye lens 145a and is linearly polarized, and the right eye image is λ / 4 patterned retarder 140 from the pixel region P of the even-numbered pixel line. As the right circularly polarized state is passed, the right circularly polarized light is incident to the right eye lens 145b rotated by 180 degrees and is linearly polarized, so that the right eye image is incident into the right eye so that a normal 3D image can be viewed.

On the other hand, the glasses 145 for viewing 3D image according to an embodiment of the present invention has been shown to be arranged so that the fixed axis of the fixing means 147 coincides with the bridge 143, one lens 145a, When the two fixing means 147 fixed in the frame 141 bordering the 145b are arranged to coincide in one frame 141, the two fixing means 147 are one in one plane. Since the rotation axis can be achieved, the position of the fixing means 147 may be variously modified.

For example, the fixing means 147 may be positioned at the vertices of the frame 141 having a rectangular shape, respectively, or the fixing means 147 in each frame 141 in a direction perpendicular to the bridge 143. ) May be arranged.

The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

141: frame 142: glasses leg
143: Bridge 145: Glasses for watching 3D video
145a: Left eye lens 145b: Right eye lens
147: fixing means 150a: first polarizing film
150b: second polarizing film

Claims (12)

A liquid crystal display device;
A first polarizing plate having a first transmission axis on one outer side of the liquid crystal display and a second polarizing plate having a first transmission axis orthogonal to the first transmission axis on the other outer side;
A pattern pattern attached to an outer surface of the second polarizing plate and having a phase pattern having different optical axes corresponding to odd-numbered pixel lines and even-numbered pixel lines among the plurality of pixel areas provided in the display area; With more;
A left and right eye lens, a frame bordering the lens, and fixing means for fixing each lens to the frame, and selectively transmitting or blocking light having a different phase for each line from the patterned retarder to each of the lenses. Glasses for viewing 3D images with polarizing film and phase film
3D image realization system, characterized in that the glasses for viewing the 3D image can rotate the fixing means as the axis of rotation so as to change the position of the front and rear of each of the left and right eye lenses to which the polarizing film is attached. .
The method of claim 1,
The phase pattern is a λ / 4 phase pattern for changing the phase by λ / 4 so that linearly polarized light is left circularly or rightly polarized,
The patterned retarder is a λ / 4 patterned retarder,
The phase film is a λ / 4 phase film, characterized in that for converting the left or right polarized light to linearly polarized light.
The method of claim 1,
The 3D image viewing glasses, the 3D image implementation system characterized in that the glasses are connected to the frame seated on the user's ear and the bridge for supporting the frame for the left eye and the right eye frame.
The method of claim 3, wherein
Each frame to which the left and right eye lenses are fixed is inserted into the fixing means is provided with a rotation means for rotating the respective lenses independently 3D imaging system.
The method of claim 4, wherein
The rotating means is a 3D image realization system, characterized in that the bearing or the rotating hinge. The method of claim 5, wherein
The rotation means is provided with a rotary tick or the engaging portion can be maintained in the state that each lens is rotated 180 degrees and 360 degrees, 3D imaging system, characterized in that.
The method according to claim 6,
Ends facing each other of the fixing means are provided with insertion grooves into which the edges of the lenses are inserted, and fastening means for fixing the insertion grooves and lenses through the insertion grooves and the edges of the respective lenses is provided. 3D image realization system.
Left and right eye lenses;
First and second frames bordering the left and right eye lenses, respectively;
A bridge connecting and supporting the first and second frames;
Glasses legs connected to the first and second frames, respectively;
Fixing means positioned at each end of each of the first and second frames bordering the left and right eye lenses so as to face each other so as to form one rotation axis within each frame;
Rotating means, which is provided at the side ends of the first and second frames, respectively, and the fixing means is inserted to rotate the fixing means facing each other with the lens provided in the fixing means as the rotating shaft.
Glasses for viewing 3D images comprising a.
The method of claim 8,
Glasses for viewing 3D images, characterized in that the left and right eye lenses are attached with a polarizing film and a phase film for selectively transmitting or blocking light.
The method of claim 8,
The rotating means is a 3D image viewing glasses, characterized in that the bearing or the rotating hinge.
11. The method of claim 10,
The rotation means is provided with a rotary tick or the engaging portion can be maintained in the state that each lens is rotated 180 degrees and 360 degrees, 3D imaging system, characterized in that.
The method of claim 8,
The glasses leg is 3D video viewing glasses, characterized in that the pivoting by the hinge provided in the first and second frames.

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