TWM416775U - Stereo glasses - Google Patents

Description

M416775 V. New description: [New technical field] This creation is about stereoscopic glasses for viewing stereoscopic images or stereoscopic images, especially for stereoscopic glasses that can adjust the range of left and right eyesight. [Prior Art] In recent years, technologies for generating stereoscopic images, stereoscopic images, stereoscopic televisions, stereoscopic devices, and the like for generating three-dimensional stereoscopic video content have been actively developed and developed rapidly. Stereoscopic images have been gradually applied to a wide variety of flat prints such as magazines, advertisements, books, etc., and with the popularity of stereo cameras, the acquisition of stereoscopic images is easier. The stereoscopic picture described here includes photographs taken by a stereo camera and the like. In general, two planar images with specific parallax are taken from the same subject at two locations and integrated together to form a stereoscopic image. When viewing, the thus formed stereoscopic image is viewed by a specific stereoscopic glasses so that the left and right eyes of the viewer receive the disparity information to generate a stereoscopic visual effect, thereby perceiving the depth of field in the stereoscopic image content. In general, when the parallax is large, the two images seen by the left and right eyes are different, the depth of field is also obvious, and the stereoscopic effect is strong. When the parallax is small, there are fewer places where the two images are different, the depth of field is less obvious, and the stereoscopic effect is weak. However, the parallax cannot be too large. If it is excessive, it will cause eye fatigue or dizziness of the viewer. 0 3 M416775 The left and right eyes of the stereo glasses which use the parallax to produce the stereoscopic effect are respectively arranged with mirror groups arranged in a predetermined manner to be from the left and right planes. The light on the image is directed to the retina of the left and right eyes to produce stereoscopic vision. Therefore, if the physical relationship between the mirror groups of the adjustment stereo glasses can be adjusted by the user, and by adjusting the distance between the viewer and the image, the user can be free from the size of the stereoscopic image and can Get the best stereo viewing. However, because the stereoscopic viewing effect of the stereoscopic glasses is quite sensitive to the physical relationship between the mirror groups, for example, the position and the relative angle, generally, the conventional portable or simple stereo glasses are used to avoid complicated and cumbersome structures. The problem of high cost is to configure the physical relationship between the mirror groups to be fixed, and the user cannot adjust the range of the left and right eyes. Therefore, the user can only view the stereoscopic image whose size is limited to a small range. Therefore, stereoscopic glasses that are light and easy to carry, low in cost, and convenient for the user to adjust the line-of-sight difference to view a large-size range of stereoscopic images, and which can produce good stereoscopic effects and comfort are required. [New content] In view of the above, the present invention provides a stereoscopic eyeglass made of a lightweight flexible plate and is capable of adjusting the line of sight of the user to view stereoscopic images of different sizes. 4 M416775

According to the abstract - _, a stereoscopic eyeglass is provided for viewing an image, comprising: a body formed by a first flexible plate having an arm, an upper frame wall and a lower (four), and two walls, upper An intermediate portion adjacent to the frame wall and the lower frame wall is provided with two viewing holes in the +-strip; the mirror assembly is formed by the second flexible plate and the first-reflecting remainder and the second reaction group, and the second flexible plate Folding into a first reflecting portion and a second reflecting portion at two ends and being symmetrical with each other, the first reflecting portion having opposite first and second planes, and no second mosquito in the first plane a first intermediate plane having a first through hole, the second reflective portion having opposite third and fourth planes, and a second intermediate portion having a second through hole between the first plane and the second plane a first mirror group having first and second mirrors respectively disposed on the first plane and the second plane, the second mirror group having third surfaces respectively disposed on the third plane and the fourth plane a mirror and a fourth mirror; and a first sliding frame and a second sliding frame, respectively The tampering plate and the fourth movable plate are formed, and are respectively combined with the first reflecting portion and the second reflecting portion of the reflective component, and are capable of sliding along the upper frame wall and the lower frame wall, and the upper frame wall The lower frame wall is rotated to adjust the line of sight of the stereo glasses by moving the corresponding first mirror and the third mirror respectively. According to an embodiment of the present invention, the first sliding frame and the second sliding frame are respectively engaged with the first reflecting portion and the second reflecting portion of the mirror assembly in an engaging or adhesive manner. . According to an embodiment of the present invention, the first flexible plate, the second flexible plate, the third flexible plate, and the fourth flexible plate are made of cardboard, a plastic plate, or a resin plate. According to another aspect of the present invention, a stereoscopic eyeglass is provided for viewing a M 416775 stereoscopic image, the stereoscopic eyeglass comprising: a body formed by the first flexible plate having two arms, an upper frame wall and a lower frame wall And an intermediate portion adjacent to the two walls, the upper frame wall and the lower frame wall, and two viewing holes are provided in the intermediate portion; the sliding frame assembly is formed by folding a one-piece second flexible plate to have The left view frame and the right view frame, the left view frame and the right view frame view each include: a frame portion having a front through hole for allowing external light to enter; a front mirror portion having a front mirror To guide light entering from the front through hole; a rear through hole region adjacent to the front mirror portion, and a through hole for allowing light reflected by the front mirror to pass; and a rear mirror portion, and The rear through-hole regions are adjacent to each other and are inclined to each other, and 'providing a rear mirror for guiding light passing through the rear through-hole region toward a corresponding viewing hole provided in the body, wherein the frame portion and the front reflection The mirror portion is bonded so as to be movable integrally, when the frame portion and the front mirror portion are When moving to drive the rear area and the rear through hole moving the mirror portions, to each other to change the tilt angle between the through holes after the mirror area and the rear portion, so as to adjust the range of the stereoscopic vision glasses. The stereoscopic glasses according to the present invention have an adjustable structure, are easy to adjust, are easy to fold and unfold, are light and portable, and have low manufacturing cost, and can achieve good viewing effects and comfort. [Embodiment] In the following description, an embodiment according to the present invention will be described with reference to the drawings. The details of the embodiments of the present disclosure are disclosed in the accompanying drawings and the following description. The above and other features, objects, and advantages of the present invention will become apparent from the description and drawings. 6 (Embodiment 1) Fig. 1 is an appearance of a stereoscopic eyeglass 100 according to the present embodiment, and Fig. 2 is an exploded view corresponding to the stereoscopic eyewear 100 of Fig. 1. As shown in Fig. 2, the stereoscopic glasses 100 according to the present embodiment include a body 102, a mirror assembly 1〇3, two sliding frames i〇41 and i〇4R. According to this embodiment, the body 1〇2 is folded from a one-piece flexible plate. When folded into a desired three-dimensional shape as shown, the two folding arms 1〇2il and i〇2iR and the upper frame wall 1022 are formed by folding a predetermined folding line or a profile. The lower frame wall 1024 forms a body 102 as shown. The two arms i〇2lL and 1021R are opposite to the folding direction of the upper frame wall 1〇22 and the lower frame wall 1〇24. For example, if the former is folded backward, the latter is forward. In the intermediate portion 1〇23 adjacent to the two arm portions 1021L and 1021R, and the upper frame wall 1022 and the lower frame wall 1024, two viewing holes 1025L and 1025R for viewing are provided. According to the present invention, the mirror assembly 103 is also a combination of a one-piece flexible plate and a mirror. As shown in FIGS. 2 and 4, the one-piece flexible plate is folded such that the planar portion for arranging the first mirror 1031R and the planar portion of the second mirror 1032R oppose each other at a predetermined angular range, and A viewing hole is provided in the intermediate plane portion between the two planes. Similarly, the planar portion for the second mirror 1031L of the device and the planar portion of the fourth mirror i〇32L are also opposed to each other by a predetermined angular range, and in the intermediate plane portion between the M416775 of the two planes. With a viewing hole. In Fig. 2, the second mirror 1032L is not shown, but the mutual positional relationship of the second mirror 1032L and the corresponding first mirror 1031L can be clearly seen from Fig. 4. In other words, the mirror assembly 103 is folded by a one-piece flexible plate such that the first mirror 1031R reflects light from the outside (stereoscopic picture) to the second mirror 1032R, and then the light is guided by the second mirror 1032R. Through the viewing hole. Similarly, the third mirror 1031L and the fourth mirror 1032L form another set of mirrors, and the light from the outside (stereoscopic picture) is reflected by the third mirror i〇31L to the fourth mirror 1032L, and then Light is guided through the viewing aperture by the fourth mirror 1032L. With the respective mirror groups thus formed, light from the outside can be guided through the viewing holes to the left and right eyes of the viewer, thereby receiving good parallax information and producing a stereoscopic image effect. It should be noted that, as shown in FIG. 4, the first mirror 1031R and the third mirror 1031L can be moved as the handle portions 1034R and 1034L are pulled, and the second mirror 103R and the fourth mirror 1032L are moved. It is not moving. Therefore, the relative positional relationship between the first mirror i〇31R and the second mirror 1032R or the relative positional relationship between the third mirror 1031L and the fourth mirror 1032L can be adjusted by moving the handle portion 1034R or 1034L′. Adjust the line of sight through the viewing hole into the eyes of the viewer to achieve a good stereoscopic viewing effect. The sliding frames 104L and 104R are respectively folded by a one-piece flexible plate to form a three-dimensional frame in which viewing holes 1041L and 1041R are provided. It should be noted that the 8 sliding frames 104L and 104R are folded to be coupled with the upper frame portion 1022 and the lower frame portion 1〇24 of the body 1〇2 during assembly so as to be able to extend the frame portion 和22 and The lower frame portion 1024 slides. The structure of each component of the stereoscopic eyeglasses 10A according to the present invention has been described above, and the manner of assembly thereof will be described next. When assembled, the mirror assembly 103 is adhesively fixed to the intermediate portion 1〇23 between the upper frame portion 1022 and the lower frame portion 1〇24 such that the axis and the frame of a viewing hole in the mirror assembly 103 are fixed. The axes of the viewing holes i 〇 25L and 1025R in the body 1 〇 2 are aligned, respectively. The size of the two viewing holes in the mirror assembly 1〇3 is substantially the same as the size of the viewing holes 1025L and 1025R. Then, the sliding frame 104L is folded into a sliding engagement with the upper frame wall 1 22 and the lower frame wall 1024, so that the sliding frame 1 can slide along the upper frame wall 1 22 and the lower frame wall 1024, in other words, The frame wall 1〇22 and the lower frame wall 1〇24 serve as guide rails for the slide frame 104L so that the slide frame can be smoothly moved. The handle portion i 〇 33L of the mirror assembly 103 is combined with the slide frame 1 〇 4L, and as the slide frame 104L moves, the shank portion 1034L can move with it, and thus the second mirror 1031L is moved. Regarding the manner in which the handle portion i〇34L and the sliding frame i〇4L are combined, the handle portion 1034L can pass through the engaging hole provided in the sliding frame i〇4L and be engaged or bonded with the engaging hole so that In combination with the sliding frame 104L, the sliding frame i〇4R is combined with the body 102 and the mirror assembly 1〇3 in a similar manner. Thus, the stereo glasses M416775 100 as shown in Fig. 1 are assembled in the above manner. When the stereo glasses 100 thus formed are used, the user can adjust the line of sight of both eyes by moving the slide frame 104L or 104R' to obtain a good stereoscopic effect without causing discomfort such as dizziness. According to the present embodiment of the creation, each of the main members of the stereoscopic glasses 1 is folded by a one-piece flexible plate. For example, the material of the flexible plate may be a paper board, a resin material or a plastic or the like. In the present embodiment, cardboard is taken as an example for illustration. As described above, since the adjustment structure and the adjustment operation of the stereoscopic glasses according to the embodiment of the present invention are simple, and are made of a flexible plate such as a cardboard, a plastic plate, or a resin plate, it is easy to fold and unfold, and is lightweight. It is easy to carry and has low manufacturing cost, and can achieve good viewing and comfort. (Embodiment 2) Next, a stereoscopic eyeglass 2 according to an embodiment of the present invention will be described with reference to Figs. 5, ό and Fig. 7. As shown in FIG. 5, the stereoscopic glasses 200 include a body 202 and a sliding frame assembly 204. As in the first embodiment described above, the body 202 is formed by folding a one-piece flexible plate. When folded into a desired three-dimensional shape as shown, the two folding arms 2021L and 2021R, the upper frame wall 2022 and the lower frame wall 2024, and the card are folded to form a predetermined folding line or track. The joint 2023 thus forms the body 202 as shown. The overlap of the two arm portions 2021L and 2021R with the upper frame wall 2022 and the lower recording frame is reduced. For example, if the folding direction of the former is backward, the latter is forward. In the intermediate portion 2025 adjacent to the two arm portions 2021L and 2021R, and the upper frame wall 2022 and the lower frame wall 2024, two viewing holes such as a left viewing hole and a right viewing hole for viewing are provided. The sliding frame assembly 204 is formed to have left and right viewing frames 204R and 204L' and a respective set of corresponding mirrors are disposed within each viewing frame. In particular, the sliding frame assembly 204 is folded from a one-piece flexible panel. Next, the structure of the slide frame assembly 2〇4 will be further explained with reference to FIG. Figure 6 shows an embodiment of a one-piece flexible plate forming a sliding frame assembly 2〇4. In Fig. 6, the dotted line is represented by a dotted line. The slide frame assembly 204 shown in detail 5 is easily formed by folding the flexible plate shown in Fig. 6 along the respective virtual links. The folding process will be explained below, and it is worth noting that the order of the folding steps described in the 'for ease of understanding' in this specification is not intended to be limited to the folding. The fourth step can be in any order. First, the two side portions of the first region 2〇41L on the left side in Fig. 6 and the two end portions of the second region 2042L are folded upward by the same virtual chain line (the direction away from the drawing surface). Then, the first link between the first zone 2〇仙 and the second zone 2〇42L is crossed, and the first zone L is folded upward toward the second zone 2G42L, so that the two ends of the second zone 2042L are respectively The two sides of the area are covered with two sides. Preferably, the two ends of the second zone 2042L can be fixedly joined to the two sides of the first zone 2〇4iL by an adhesive. Then, the virtual link ' between the third zone 2043L and the fourth zone 2044L is folded toward the M416775 in such a manner that the third zone 2043L and the fourth zone 2〇4 are inclined to each other. Next, the two rectangular portions having different lengths in the two side portions of the first region 2041L are folded in half along the folding line to be joined to the fifth region 2045L, and preferably bonded by the adhesive. Thus, the third zone 2043L and the fourth zone 2044L which are inclined to each other are also included therein. Finally, the sixth zone 2〇46L and the seventh zone 2047L are folded upward by the folding line (dashed chain line) between them to be inclined to each other. The left view frame 204L shown in FIG. 7 is formed by folding as described above, and is folded into a left view frame 2〇4L as described above, and a mirror (front mirror) is provided on the surface of the fourth region 2044L, and Another mirror (back mirror) is provided on the back side of the seventh zone 2〇47L. Thus, the light from the viewing target is guided by the mirror of the fourth zone 2〇44L through the hole in the first zone through the hole provided in the sixth zone to the back surface provided in the seventh zone 2〇47L. The other mirror 're-reflects to the corresponding hole in the frame. The right side and the left side of the central area 2048 shown in FIG. 6 are substantially symmetrical with each other, so in the same manner, the folding is respectively associated with the first area 2, the second area 2042L, the third area 2043L, and the fourth a region 2044L, a fifth region 2045L, a sixth region 2046L, and a seventh region 2047R corresponding to the ninth region 2041R, the tenth region 2042R, the eleventh region 2043R, the twelfth region 2044R, the thirteenth region 2045R, the first Fourteen zones 2046R and fifteenth zones 2047R form a right viewing frame 204R. For the sake of brevity, the folding of the viewing frame 2〇4R will not be repeated. The viewing assembly 204 thus formed is joined to the body 202. The central portion 2048 of the viewing assembly 204 is fixedly joined to the intermediate portion 2025 of the body 202 by an adhesive when engaged.

Specifically, in the left view frame 2〇4L thus formed, the first region 2041L 12 M416775 and the second region 2042L constitute a frame portion, and the fourth region 2044L provided with the front mirror is fixed to the frame portion. Ground joint, therefore, when the frame portion moves, the front mirror moves together with the frame portion and the relative positional relationship does not change, and the sixth region 2〇46L with the through hole and the first mirror provided The seven zones 2047L also move together with the movement of the frame, but the positional relationship between the sixth zone 2046L and the seventh zone 2〇47L changes with the movement, in other words, the sixth zone 2046L and the seventh which are inclined to each other. The angle of inclination between the regions 2047L changes with movement, and thus the range of line of sight transmitted to the user is changed by the change of the mirror on the seventh zone 2047L. It is also possible to adjust the right viewing frame 204R in the same manner to change the viewing angle range of the viewer's right eye to obtain a good stereoscopic viewing effect. When the stereoscopic glasses 200 thus formed are used to view a stereoscopic image or a movie, the user can adjust the line of sight of both eyes by sliding the left or right viewing frame to obtain a good stereoscopic effect without causing dizziness. Discomfort such as dizziness. As described above, since the adjustment structure and the adjustment operation of the stereoscopic glasses according to the present embodiment are simple, and are made of, for example, a cardboard, a plastic plate, or a resin plate. Therefore, it is easy to fold and unfold, is light and portable, and has low manufacturing cost, and can achieve good viewing and comfort. Although the present invention has been described with reference to the illustrated embodiments. However, it is to be understood that the present teachings are not limited to the illustrated embodiments disclosed. The scope of the claims is to be interpreted in the broadest sense to cover all such modifications and equivalent structures and functions. 13 M416775 BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view showing an embodiment of a stereoscopic eyeglass according to the present invention. Figure 2 corresponds to an exploded view of the embodiment of the stereoscopic glasses of Figure 1. Fig. 3 is a front elevational view of the stereoscopic glasses corresponding to the embodiment of Fig. 1 according to the present invention. Figure 4 is a cross-sectional view corresponding to the front view of Figure 3. Fig. 5 shows an exploded view of a stereoscopic eyeglass according to another embodiment of the present creation. Figure 6 is a view 'showing an expanded view of the sliding frame assembly shown in Figure 5. Figure 7 is a view showing the folding of the sliding frame assembly shown in Figure 5. [Main component symbol description] 100 Stereo glasses 102 Main body 103 Mirror assembly 104L Sliding frame 104R Sliding frame 1021L Arm 1021R Arm 1022 Upper frame wall 1023 Middle portion 1024 Lower frame wall 1025L View hole 1025R View hole 1031R A mirror 1031L third mirror 1032R second mirror 1032L fourth mirror 1041L viewing hole 1041R viewing hole 200 stereo glasses 202 body 204 sliding frame assembly 204L left viewing frame 204R right viewing frame 2021L arm M416775

2021R Arm 2022 2023 Engagement 2024 2025 Intermediate section 2041L 2042L Second zone 2043L 2044L Fourth zone 2045L 2046L Sixth zone 2047L 2048 Eighth zone 2041R 2042R Tenth zone 2043R 2044R Twelfth zone 2045R 2046R Fourteenth zone 2047R Upper frame wall lower frame first district fourth district fifth district seventh district ninth district eleventh district thirteenth district fifteenth district

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Claims (1)

M416775 VI. Patent Application Range: 1. A stereoscopic glasses for viewing a stereoscopic image, the stereoscopic glasses comprising: a body 'formed by a first flexible plate having two arms, an upper frame wall and a lower frame wall, and And an intermediate portion of the two walls, the upper frame wall and the lower frame wall phase (4), wherein two viewing holes are disposed in the intermediate portion; a mirror assembly, wherein the second flexible plate and the first mirror group and the second mirror group axis are capable of reducing a first reflecting portion and a second reflecting portion having two end portions and symmetrical to each other, The first reflecting portion has opposite first and second planes, and a first intermediate plane between the first plane and the second plane, wherein the second reflecting portion has a relative JL a third plane and a fourth plane, and a second through hole (four) two intermediate plane between the first plane and the second plane, the first mirror group having a divisional position on the first plane and a second mirror (four) and a second mirror on the second plane, the second reflector having third and fourth mirrors respectively disposed on the third plane and the fourth plane; The line-of-sight range-sliding frame and the second sliding frame are respectively combined by the third flexible plate and the fourth flexible plate axis to the miscellaneous window, and the first reflecting portion and the second reflecting portion of the divided viewing assembly are combined And sliding the upper and lower frame walls together with the upper frame wall and the lower frame, respectively, by using the first mirror of the f and the third mirror to simplify the 16 M416775 of the stereo glasses and the second reflection The parts are joined by a snap fit. 3. The stereoscopic eyeglass of claim 1, wherein the first sliding frame and the second sliding frame are bonded to the first reflecting portion and the second reflecting portion of the mirror assembly, respectively. 4. The stereoscopic glasses of claim 1, wherein the first flexible plate, the second flexible plate, the third flexible plate, and the fourth flexible plate are cardboard, plastic plates, or Resin board. 5. A stereoscopic eyeglass for viewing a stereoscopic image, the stereoscopic suction mirror comprising: a body formed by the first flexible plate having two arms, an upper frame wall and a lower frame wall, and the two walls, An intermediate portion adjacent to the upper frame wall and the lower frame wall, wherein the intermediate portion is provided with a viewing hole, and the sliding frame assembly is formed by folding a one-piece second flexible plate to have a left viewing frame and Right view frame 'The left view frame and the right view frame view both include: a frame portion with a front through hole for allowing external light to enter; a front mirror portion with a front mirror for guiding from the front a light entering through the through hole; a rear through hole region adjacent to the front mirror portion, and a through hole for allowing light reflected by the front mirror to pass; and a rear mirror portion and the rear through hole The regions are adjacent to each other and are inclined to each other, and a rear mirror is disposed for guiding the light passing through the rear through-hole region toward the corresponding viewing hole provided in the body, wherein the frame portion and the frame are The front mirror portion is bonded so as to be integrally movable when the frame portion and the front mirror portion When moving together, the rear through-hole area and the rear mirror portion are moved, and the angle of inclination between the rear through-hole area and the 17 M416775 rear-end mirror portion is changed, thereby adjusting the line of sight of the stereoscopic glasses. 6. The stereoscopic glasses of claim 5, wherein the first flexible plate and the second flexible plate are cardboard, plastic plates, or resin plates.