ITTO960881A1 - STEREOSCOPIC SLIDES PROJECTOR AND FRAME FOR STEREOSCOPIC SLIDES. - Google Patents

Description

Description of the Industrial Invention entitled: "Stereoscopic slide projector and mount for stereoscopic slides",

DESCRIPTION

The present invention relates to a stereoscopic slide projector and a stereoscopic slide mount and, in particular, a stereoscopic slide projector which can use a roll of film and a mount for stereoscopic slides having means for positioning the film.

A conventional stereoscopic slide projector has a structure in which a stereoscopic slide mount is inserted so that an image can be seen by two eyes. A roll of developed film is cut at each frame, mounted in the stereoscopic slide mount, and then displayed. In this case it is advantageous to have a stereoscopic slide projector which allows the roll of film wound lengthwise to be viewed without it having to be cut.

Even though the roll of film is still cut at each frame and placed in the stereoscopic slide mount, it is considered beneficial for improving the efficiency in the editing work if the roll of film can be positioned at the correct amount of masking. of the image while remaining in the roll condition. This is because it is necessary to mask the non-duplicated parts that are at the left edge of the left image and at the right edge of the right image due to the difference in the displayed fields of the right and left photographic lenses when the slide captured using a general purpose stereo camera, which does not have a lens shift mechanism, is mounted in the stereoscopic slide frame. Since the area to be masked increases in width or decreases depending on the distance from the object, it is necessary to select the stereoscopic slide mount that has a window of suitable width from a plurality of stereoscopic slide mount types having windows different widths or otherwise adjust the distance between the left and right films. Previously this assembly work was done manually. The degree of result of the work which depends on intuition and experience is remarkable and an error in the selection of the frame or the mounting position of the film occurs easily.

It is therefore necessary to remedy the technical problem exposed by providing a stereoscopic slide projector that allows you to observe a steroscopic image in the presence of a roll of film, a stereoscopic slide projector that allows you to identify the amount of image masking at the moment assembly in the presence of a roll of film and a stereoscopic slide projector in which positioning at the time of assembly is facilitated. The object of the present invention is therefore to solve the aforementioned technical problem.

To achieve the aforementioned objective, the present invention provides a stereoscopic slide projector comprising two right and left optical systems each provided with an objective, a ground glass and an eyepiece and means for advancing the film having a pair of front windows. and rearward arranged along the path of advancement of a film, in which the images of a roll of film loaded in the film advance means located in said pair of windows are projected individually on the right and left frosted glasses so that images stereoscopic images can be appreciated by two eyes.

The present invention further provides a stereoscopic slide projector further comprising a mechanism for adjusting the magnification of the projected image, a mechanism for adjusting the distance of the frosted glasses, and an interconnection mechanism for the mechanism for adjusting the magnification of the projected image. with the frosted glass distance adjustment mechanism, in which the inner edges of the left and right frosted glasses are brought to coincide with the inner edges of the images projected onto the frosted glasses by the interconnection mechanism, regardless of the magnification ratio of the projection.

The present invention further provides a stereoscopic slide projector further comprising perforation units mounted above or below a pair of windows of the film advancing means, in which a notch can be formed in a predetermined position of an upper or lower edge of the loaded film. in the film advancing means and a mount for stereoscopic slides comprising a base frame and a cover frame aligned with two rectangular windows, in which a positioning unit is formed on the surface of the base frame on which the film is placed bringing the images of two films to coincide with the windows by engaging with the film notches formed by the perforation units.

Figure 1 is a plan view of the stereoscopic slide projector according to claim 1;

Figure 2 is a perspective view of the manual film advancing means;

Figures 3 (a) and 3 (b) are explanatory views of the adjustment of the distance between the optical axes of the objectives;

Figure 4 is a front view of a roll of 135 film photographed in which an example of a string of frames from a stereoscopic camera is shown;

Figure 5 is a front view of a projected portion of a reference notch on the ground glass;

Figure 6 is a perspective view of the motorized film advancing means;

Figure 7 is a plan view of the stereoscopic slide projector according to claim 2;

Figure 8 is a front view of frosted glass for detecting the amount of masking;

Figure 9 is an exploded perspective view of a drilling unit;

Figures 10 (a) and 10 (b) are front views of a film in which notches are formed by the punch unit;

Figure 11 illustrates a stereoscopic slide projector according to claim 14, where Figure 11 (a) is a top down rear view of a cover frame, Figure 11 (b) is a front view of a base frame, Figure 11 (c) is a sectional view of Figure 11 (a), and Figure 11 (d) is a sectional view of Figure 11 (b);

Figures 12 (a), 12 (b), 12 (c) and 12 (d) are top-down rear views of a cover frame of a stereoscopic slide mount of Figure 15;

Figure 13 is a plan view of the stereoscopic slide projector according to claim 12; And

Figure 14 is an explanatory view of an interconnection mechanism of a punch unit of a stereoscopic slide projector according to claim 12 with a ground glass.

Preferred embodiments of the present invention will now be described in detail. Figure 1 illustrates a stereoscopic slide projector 1 in which film advancing means 3 for advancing a lengthwise wound roll of film F are mounted at the rear on a table 2, a pair of left and right lens holders 4R and 4L are provided at the intermediate rear and front portions of table 2, and objectives 5R and 5L are mounted on the right and left lens holders 4R and 4L. Nuts are provided at the right and left lens holders 4R and 4L. An advance screw 6 mounted at the table 2 is coupled to the nuts of the lens holders 4R and 4L by means of ball screw mechanisms. Left-hand and right-hand threads are symmetrically obtained from the intermediate portion to the left and to the right. A lens distance adjustment knob 7 mounted at the end of the feed screw 6 is rotated to separate or bring the left and right lens holders 4R and 4L in a direction perpendicular to the optical axis, thereby adjusting the distance between the optical axes of the 5R and 5L objectives.

A pair of right and left 8R and 8L frosted glass are mounted in front of table 2 and 9R and 9L frosted glass with a completely opaque surface are mounted on the supports of 8R and 8L frosted glass. Eyepiece holders 10R and 10L opposite the frosted glasses 9R and 9L are fixed in front of table 2 and eyepieces 11R and 11L are mounted on the eyepiece holders 10R and 10L. The lenses of the 11R and 11L eyepieces are moved back and forth by rotating a cylinder to thereby adjust the dioptric power to match the eyes of the observer. It is preferable to set the distance between the centers of the ground glass 9R and 9L and the eyepieces 11R and 11L at the distance of about 63.5 mm corresponding to the standard human distance between the two eyes.

A semicircular reflecting plate 12 is fixed to the rear end of the table 2, a lighting bulb 13 is mounted in an internal space formed by the reflecting plate 12 and the film advancing means 3 to constitute a diffused light source, thereby illuminating uniformly the rear surface of the film advancing means 3.

Figure 2 illustrates the film advancing means 3, in which an openable retaining cover 15 is pivotally secured to a film guide table 14 having guide slots equal in width to that of the film. Windows 16R and 16L of size and pitch corresponding to that of the format of a string of images of the stereo camera are provided to the right and to the left of the film guide table 14 and of the retaining cover 15.

The advancing means of the film 3 of Figure 2 correspond to those of the stereoscopic camera of the format of the string of images in which an image of another set is inserted between a pair of right and left images. Furthermore there are stereoscopic cameras having different pitches between the images in which left and right images are arranged adjacent or two other sets of images are arranged in two frames between a pair of right and left images and the film advancing means can be replaced with the film advancing means having a pitch between the windows for each of the stereoscopy cameras.

When the film advancing means 3 are replaced, the lens distance adjustment knob 7 is operated to adjust the distance between the lenses 5R and 5L so that the centers of the lenses 5R and 5L are arranged in a straight line to connect the centers of the left and right frosted glass 9R and 9L to the centers of the windows 16R and 16L of the advancing means 3, as illustrated in Figures 3 (a) and 3 (b), thereby focusing a set of images on the left and right frosted glass 9R and 9L.

Identification means such as an electrical contact or having a type identification hole are provided at the film advancing means and an electrical, magnetic or optical sensor is provided in the body of the stereoscopic slide projector to provide a means identification mechanism. and a motor is provided in a lens distance adjustment mechanism 5R and 5L and the distance between lenses 5R and 5L can be automatically adjusted in response to the type of the film advance means, by means of a control unit .

The film advancing means 3 illustrated in Figure 2 is used for a 135 film. A sprocket 17 which engages with the perforations of the 135 film is mounted on the film guide table 14 and a roll of film F can be advanced by rotating a feed knob 18 fixed to the end of the sprocket shaft 17.

Although omitted in the drawings, a reel from which the film is unwound and a reel to which the film is wound are mounted at both ends of the film guide table 14 to achieve an unwind and rewind mechanism similar to that of a generic camera, a roll of film is drawn onto the take-up reel by the unwind reel and can be rewound onto the unwind reel after viewing. An advance mechanism or a winding reel guiding mechanism obtained by means of a latch roller is used as an alternative to the advance mechanism obtained by means of the toothed wheel 17 to thereby advance the film which has no perforations, such as for example a 120 roll of film.

Figure 4 illustrates an example image string format of a stereoscopy camera. The images are arranged from the beginning of the 135 film roll in the order IR, 2R, IL, 2L, 3R, 4R, 3L, 4L, ..., and representations flipped from top to bottom and left to right are displayed on the pictures. The flipped representations from top to bottom and from left to right on the film roll F are inverted by the 5R and 5L lenses of the stereoscopic slide projector 1, are focused in the form of straight representations on the frosted glass 9R and 9L, and the straight stereoscopic representation can be appreciated through the right and left eyepieces 11R and 11L.

With reference to Figure 4, the applicant of the present invention has proposed a stereoscopic camera in which perforation marks CM and frame numbers nR and nL constituting indices of the perforation marks between the images of a film F are exposed at the moment of capture. image. Referring again to Figure 2, the perforation mark projection window 19 and a frame number projection window 20 are provided on the film guide table 14 and the retaining cover 15, and a projection portion of the perforation marks 21 and a projection portion of the number of the frame 22 are provided on the ground glass 9R thus allowing the accurate alignment of the images of the film F with the windows 16R and 16L and allowing the visual recognition of the frame number.

Referring to Figure 5, an index line IR E F similar to the perforation mark CM is printed on the projection portion of the perforation mark 21 of the frosted glass 9R and the relative position relationship between the index line I * ir and the area of the The image of the ground glass 9R corresponds to the position relationship between the photographed image on the roll of film F and the perforation mark CM. Therefore, if the perforation mark CM projected on the projection portion of the perforation mark 21 is brought to coincide with the index line LR EF, the position of the windows 16R and 16L coincide with the images of the film F.; In addition, means for l The advancement of the film can be automated using the CM perforation mark. Referring to Figure 6, an optical sensor 34 is provided in the projection window of the perforation mark 33 of the holding cover 32 of the motorized film advancing means 31, and a feed control unit (not shown) is provided for the control of a winding motor 35 in accordance with the perforation mark recognition signal of the optical sensor 34. The start of the film roll F is secured to a winding reel 36 and the holding cover 32 is superimposed on a film guide table 37. When a feed execution signal is sent to the feed control unit by activation means such as a feed button, the take-up motor 35 is activated to rotate to wind the roll of film F. When the CM perforation mark on the first image is recognized by the optical sensor 34, the winding is stopped and the images gini of the first set are arranged in correspondence with windows 38R and 38L. ; Frame advance or frame rewind is performed by the advance controller in response to the activation of the forward button, it is stopped at the position where the corresponding punch mark is detected by the optical sensor 34 and the stereoscopic images can be displayed continuously by simply activating the button. ; In the roll of film photographed by the stereoscopic camera of the format of the string of images shown in Figure 4, after the set of IR and IL has been displayed, when the film is advanced one frame, the set of 2R and 2L it is contained in the windows and it is therefore necessary to advance three frames to observe the 3R and 3L. This requires manual operation to alternately advance one frame and three frames. In order to eliminate this need for a manual operation, the use of means for the automatic control of the motorized winding mechanism based on the format of the string of images of the stereo camera is effective. Although omitted in the drawings, as automatic control means are provided for winding, means are also provided for reading data from an edge liner of the film roll of magnetic material for recording position and position information. frame number, obtained by means of a magnetic head at the film guide table. In this case the magnetic head is provided at the film guide table, the position and frame number information is recorded by a data recorder / reproducer, or the magnetic head and data recorder are provided in the camera. for stereoscopy for recording information on the film at the time of image capture. If information is recorded by the film advancing means, a roll of film is first mounted on the film advancing means, the film is advanced manually or by a motor to align the images with the windows, and the recorder / player is activated at the position to record information on the respective images. ; If magnetic information recording is used, various information can be recorded in addition to the position and frame number information. For example, skip instructions are recorded on the failed image to allow the unnecessary image to be automatically discarded on the roll of film when advancing to the next image. The aforementioned stereoscopic slide projector 1 exhibits fixed ratios of the fields of view on the left and right images. In a stereoscopic camera having a mechanism for adjusting the distance between the optical axes of photographic lenses, as suggested by the applicant of the present invention, optimal stereoscopic effects are obtained in all film images in which parallax is corrected in response to distance. of photography. However, as described above, in film from a stereoscopic camera in which no mechanism for adjusting the distance between the optical axes is provided, the stereoscopic effect can be unnatural depending on the photographing distance of an object. In order to eliminate this problem, with reference to Figure 1, masking closures of the images 39R and 39L are provided to shield the external parts of the left and right frosted glass 9R and 9L or closures are provided to shield the inside of the right and left windows. left of the film advancing means 3, and the outer areas of the straight images are correctly masked in response to the photography condition to achieve an optimal stereoscopic effect. The image masking closures 39R and 39L can be adjusted manually or by means of a motor by providing an adjustment mechanism for interconnecting said closures symmetrically by means of feed screws. The masking quantities of the respective images are determined by test verification, the masking quantities are stored in the film F as magnetically recorded information as described above, and the locking drive motor is automatically controlled by the control unit, and therefore manual operations can be eliminated. A stereoscopic slide projector 41 illustrated in Figure 7 has manual or motorized means for advancing the film 31 described above, mounted at the rear with respect to a guide table for the slides 42, and a base of the objectives 43, mounted at the front with respect to the means advancing means of the film 31, so that the advancing means of the film 31 and the base of the objectives 43 are displaceable in the direction of the optical axis. Objective holders 44R and 44L are mounted on the base of the objectives 43, mechanisms for adjusting the distance between the objectives are provided by means of ball screws as described above at the objective holders 44R and 44L to adjust the distance between the axes optics of the 45R and 45L lenses. ; Frosted glass holders 46R and 461 · are mounted in front of the slide guide table 42 and the frosted glasses 47R and 47L of the frosted glass holders 46R and 46L can be replaced. Similarly to the stereoscopic slide projector 1 of Figure 1, supports for the eyepieces 10R and 10L opposite the ground glass 47R and 47L are fixed frontally to the end of the guide table of the slides 42, and the dioptric power can be adjusted by rotating the cylinder of the eyepiece lenses R and L of eyepiece holders 10R and 10L. A diffuse light source of a semicircular plate 12 and a bulb 13 is provided at the rear end of the slide guide table 42.; The frosted glass holders 46R and 46L are mounted, similarly to the lens holders 44R and 44L on a ball screw mechanism, feed screws 48 of the ball screw mechanism are right-hand threaded on the right and left-hand side. The right and left frosted glass supports 46R and 461 are separated or brought closer in a direction perpendicular to the optical axis by turning the ground glass distance adjustment knob 49 mounted at the end of the feed screw 48 and the distance can be adjusted within a predetermined range in the direction of approach relative to each other from the reference pitch to the pitch of the ground glass 47R and 47L. Two cam plates 50 and 51 for individually moving the film advancing means 31 and the base of the objectives 43 are mounted in an intermediate position of the advance screw 48. Tappet rods 52 and 53 are interposed between the advancing means of the film 31 and the cam plate 50 and between the base of the objectives 43 and the cam plate 51 and the means for advancing the film 31 and the base of the objectives 43 are caused to press with the cam plates 50 and 51 through the stems of tappet 52 and 53 due to the traction force exerted by coil springs 54 and 55. Therefore, the film advancing means 31 and the base of the objectives 43 are interconnected to the rotations of the cam plates 50 and 51 by turning the knob for adjusting the distance between the frosted glasses 49 and moved back and forth in an interval between the main position of a 1: 1 magnification and the last position of enlarged projection. The two cam stones 50 and 51 are formed in such a way that the images projected on the frosted glasses 47R and 47L maintain the displacement ratio so as to always maintain the state of focus within the range of displacement of the means of advancement of the film 31 and of the base of the objectives 43, thus allowing any enlargement of the projected image. ; When the film advancing means 31 and the base of the lenses 43 are moved in a magnification direction of the projected image, the lens holders 46R and 46L are interconnected to approach each other at the determined distance and images straight on the left and right frosted windows 47R and 47L are masked on the outside by the image frames of the frosted glass 47R and 47L. ; At this point, assuming that the actual image widths of the stereoscopic slides and the image widths of the 47R and 47L frosted glass are 30 mm, the projected image width when the slide images are for example enlarged and projected becomes 30 x 30/29 = 31,034 (min) and the difference of the projected image width from the 30 mm of the image widths of the 47R and 47L frosted glass is 31,034 - 30 = 1,034 (mm). That is, if the 47R and 47L frosted glasses are arranged at the initial positions shown in Figure 7, the enlarged projection image extends 1.034 / 2 = 0.517 (mm) to the right and left side of the 47R and 47L frosted glass. ; The pitch of the feed screw 48 is the shift pitch of the right and left frosted glass holders 46R and 46L of 0.517mm in the case of, for example, a projection magnification ratio of 30/29. The inner edges of the image areas of the 47R and 471 "frosted glass coincide with the inner edge of the projected slide image regardless of the projection magnification ratio, the external area of the projected image protrudes outside the frosted glass to be masked and the masked area is continuously varied in response to the projection magnification ratio. Therefore, when the roll of film photographed with the stereoscopic camera which does not have a mechanism for adjusting the distance between the optical axes is displayed, the magnification ratio of the projection is adjusted in response to the condition of the photograph and the external area of the the image is properly masked to be displayed with an optimal stereoscopic effect. ; Stereoscopic slide projector 41 can be used as a masking amount control unit when film is mounted in a stereoscopic slide mount by replacing the fully opaque surface 47R and 47L frosted glass with frosted glass for amount recognition 56 having a collimation pattern CP having a main body of vertical lines as illustrated in Figure 8. 49, the amount of masking becomes optimal when the front and rear positions of a subject in the close range are substantially equal to the collimation pattern CP of the left and right ground glass 56R and 56L or in the observed condition i The depth of the CP collimation pattern, and accurate stereoscopic images can be reproduced by mounting the film in the stereoscopic slide mount having a window width that satisfies the conditions. ; As shown in Figure 7, the same number as the mount number is displayed at the rotation position of the stereoscopic slide mount or the framing jig (a plurality of types of stereoscopic slide mounts or a trimming jig having a foot positioning of the film and different window widths) proposed by the applicant of the present invention corresponding to the image shielding ratio on a scale 57 of the frosted glass distance adjustment knob 49. Therefore, if the scale number 57 is observed when the subject in the close range field is arranged in the front or rear position substantially equal to the collimation pattern CP of the ground glass for recognizing the amount of masking. 56R and 56L or when the CP collimation pattern deep observation condition occurs, the correct number of the stereoscopic slide mount or the trimming template can be recognized, and the editing can be easily and accurately completed. The work of mounting film that does not have perforation, such as a 120 film, can be facilitated in a similar manner to the 135 film case by providing punch units 61R and 61L in the film advancing means 31 as illustrated in Figure 7 With reference to Figure 9, a punching machine 62 of the perforation unit 61 is coupled to the film guide table 37 of the film advancing means 31 and a punch holder 63 and a film holding arm 64 are attached, free to rotate vertically, to the punch 62. Spiral thrust springs 65 and 66 are mounted at the punch 62 and the film holding arm 64 as well as the punch holder 63, and the punch holder 63 and the film holding arm 64 are oscillating with respect to the punching machine 62. A cam 67 is arranged above the punch holder 63 and the punch holder 63 and the holding arm d the film 64 are moved downwardly by rotating an actuation lever 68 attached to a cam shaft. When the cam 67 presses the upper surface of the punch holder 63, the punch holder 63 and the film holding arm 64 are integrally displaced downwards and the film is held between the film holding arm 64 and the punch 62, to be fixed. Then, when the actuation lever 68 is further rotated, the punch holder 63 compresses the spiral thrust spring 66 downwards and the punch 69 which is mounted at the end of the punch holder 63 is coupled with the punching machine 62 to pierce the edge. of film F thus forming a notch. ; When the stereoscopic slide is cut at each frame, it is not easy to distinguish a left film from a right film. However, the perforations of the right and left punch unit 6IR and 6IL and the shapes of the punch presses are different, and the shapes of the NR and NL notches of the right side FR and the left side FL film are different, as shown in Figure 10 and therefore, the right side FR film can be distinguished from the left side FL film. Figure 11 illustrates a stereoscopic slide mount for a 120 film having a cover frame 71 in Figure 11 (a) and a base frame 72 in Figure 11 (b). Form protrusions 74R and 74L mating with the film notches are provided at the upper edge of a hollow film positioning portion 73 formed on the base frame 72 and the protrusions 74R and 74L are arranged on the axis of the right and left windows . A film holding portion 75 of the protruding surface coupled with the film positioning portion 73 of the base frame 72 is formed on the cover frame 71 engaged with the base frame 72 and the film holding portion 75 has a symmetrical shape comprising cavities 76R and 76L corresponding to the projections 74R and 74L of the base frame 72.; The stereoscopic slide mount is preferably configured so that, similarly to the stereoscopic slide mount or the squaring mask proposed by the applicant of the present invention as described in previously, the pitch Pi of the left and right windows 77R and 77L of the base frame 72 is approximately 63.5 mm similar to the distance between human eyes. The ratio of the length to the width of the windows 77R and 77L is the same as the image size of the slide film F or slightly larger, so that the entire image of the film F can be seen. When a set of slide film F cut at each frame is placed on the film positioning portion 73 and the NR and NL notches are mated with the protrusions 74R and 74L, the centers of the windows 77R and 77L coincide with the centers of the images of the slide film F.; With reference to Figure 12, the cover frames 71 coupled with the base frames 72 of a plurality of types are arranged in which the distance of the right and left windows 78R and 78L and the widths of the windows are equal (# 0) to the distance C1 of the windows and the width W of the window of the base frame 72 and the widths W of the windows are gradually scaled (# 0, # 1, # 2, ...) *

When the cover frame 71 of the number obtained from the masking amount recognition work using the stereoscopic slide projector 41 is joined to the base frame 72, the stereoscopic slide having the correct amount of image masking can be formed in response to the condition of photography.

A stereoscopic slide projector 81 illustrated in Figure 13 has no mechanisms for adjusting the magnification of the projection and has a mechanism for adjusting the distance of the lenses 45R and 45L and a mechanism for adjusting the distance of the frosted glasses similar to that of the projector of stereoscopic slides 41 of Figure 7. Perforation units 61R and 61L are mounted movably along the film guide table 37 of the means for advancing the film 31.

Levers 82R and 82L are secured so that they can rotate horizontally to the right and left lens holders 44R and 44L, and the rotation fulcrums of the levers 82R and 82L are arranged at equal positions to the optical centers of the lenses 45R and 45L. As shown in Figure 14, one end of the levers 82R and 82L engages with the frosted glass holders 46R and 46L and the other end engages with the punch units 6 1R and 61L. When the frosted glass gap adjustment knob 49 is rotated to move the frosted glass holders 46R and 46L in the approach direction, the spacing of the 61R and 61L perforation units increases symmetrically, and the positions of the notches NR and NL formed on the film F are offset outward with respect to the centers of the inverted image from top to bottom and from left to right, i.e. inside the straight image. Therefore, when the film formed with the notches in this way is cut at each frame and mounted in the stereoscopic slide mount, the closer the distance to the subject of the film, and the greater the pitch of the images, the outer area of the straight image is masked by the stereoscopic slide mount, the parallax of the subject at close range is correct, and a stereoscopic slide having a correct amount of masking can be formed in response to the condition of the photograph.

If the NR and NL notches are formed on the film F by the stereoscopic slide projector 81, since the pitch of the film images is increased more than the image pitch of the stereoscopic slide mount which must be mounted frequently, the need arises to form a slightly smaller width of the stereoscopic slide mount so that the peripheral edge of the image within the image is not exposed in the mount window. However, it is not necessary to register the number of the suitable cover frame 71 by recognizing the amount of masking and prepare cover frames 71 of various and different window widths from the stereoscopic slide projector 41 in which the positions of the notches are fixed, but the film can be mounted uniformly in the stereoscopic slide mount having a predetermined window width, and thus the mounting work is advantageously facilitated.

The stereoscopic slide projector of the present invention as described above can display the lengthwise wound roll of film as it is. Therefore, the manual operation required to replace the stereoscopic slide mounts one by one is eliminated and the film can be viewed continuously.

Even when the film is mounted in the stereoscopic slide mount, the proper amount of masking can be determined before each frame is cut and, therefore, the efficiency of the editing process can be greatly increased.

When the notch is formed at the film that has no perforations, such as a 120 film, by the stereoscopic slide projector having a perforation unit, so that the film can be mounted on the stereoscopic slide mount of the present invention, the film is carefully positioned to allow sufficient stereoscopic visual effect to be obtained, and thus the complexity and inaccuracy of editing conventional stereoscopic slides is eliminated.

The magnification adjustment mechanism and the distance adjustment mechanism of the frosted glass can be realized, instead of manually operated as illustrated, by means of guide units which use a servomotor and by providing an electric, magnetic or optical position sensor in correspondence with the movable units to control their position by means of a control unit. The realization of the units can be modified in various ways while remaining within the inventive principle of the present invention, finally it should be noted that the present invention includes these modified embodiments.

Claims (15)

CLAIMS 1. Stereoscopic slide projector comprising two left and right optical systems each provided with an objective, ground glass and eyepiece, and film advancing means having a pair of front and rear windows arranged along the direction of advance of the film, wherein the images of a roll of film loaded into the film advancing means located in said pair of windows are individually projected onto the left and right frosted glass so that stereoscopic images can be seen by two eyes. 2. Stereoscopic slide projector comprising two left and right optical systems each provided with an objective, ground glass and eyepiece, and means for advancing a film having a pair of front and rear windows along the direction of travel of the film, in which the images of a roll of film loaded into the film advancing means located in said pair of windows are individually projected onto the left and right frosted glasses and further comprising a mechanism for adjusting the magnification of the projected image , a frosted glass distance adjustment mechanism, and an interconnection mechanism of the projected image magnification adjustment mechanism with the frosted glass gap adjustment mechanism, in which the inner edges of the left and right frosted glass are brought to coincide with the inner edges of the proi images etched on the frosted glass by the interconnect mechanism regardless of the magnification ratio of the projection. Stereoscopic slide projector according to claim 1, further comprising an image masking telescopic closure from the outside of the left and right frosted glasses in the image area, wherein the masking amounts of the outside image areas of the right and left are variable. (IN A stereoscopic slide projector according to claim 1, further comprising a ground glass distance adjustment mechanism, wherein the masking amounts of the outer areas of the right and left frosted glass are variable. Stereoscopic slide projector according to claim 1 or 2, further comprising a mechanism for adjusting the distance between the optical axes of the right and left lens pair. 6. Stereoscopic slide projector according to claim 1 or 2, wherein the film advancing means are so constituted so that they can be replaced. A stereoscopic slide projector according to claim 1 or 2, wherein the ground glasses are formed so that they can be replaced. Stereoscopic slide projector according to claim 1 or 2, wherein a motorized mechanism for advancing the film is mounted on the film advancing means. The stereoscopic slide projector according to claim 1 or 2, wherein a motorized mechanism for advancing the film is mounted on the film advancing means, wherein a magnetic head is provided on the film advancing means, and wherein a control unit is provided for recording on a film coated with magnetic material the information on the position of the image and on the frame number through a data recorder / reproducer and the magnetic head and for controlling the motorized mechanism for the advancement of the film based on the recorded information. 10. A stereoscopic slide projector according to claim 2, 3 or 4, wherein a motorized mechanism for advancing the film is mounted on the film advancing means, wherein a magnetic head is provided on the film advancing means, and in which a control unit is provided for recording on a film coated with magnetic material the information on the position of the image and on the frame number through a data recorder / reproducer and the magnetic head and for controlling the motorized mechanism for film advance, an image masking closing mechanism or frosted glass distance adjustment mechanism, or a projection magnification adjustment mechanism and frosted glass distance adjustment mechanism on the basis of the recorded information. The stereoscopic slide projector according to claim 1 or 2 further comprising punch units mounted above or below a pair of windows of the film advancing means, in which notches can be formed at predetermined positions of an upper or lower edge of the loaded film. in the film advancing means. Stereoscopic slide projector according to claim 1 or 2, in which a ground glass distance adjustment mechanism is provided, in which the masking amounts of the outer areas of the right and left images are variable, in which movable punch units on the right or left are mounted above or below the pair of windows of the film advancing means, in which notches can be formed on the upper or lower edge of the film loaded in the film advancing means, in which an interconnection mechanism of the film is provided. distance adjustment mechanism of the ground glass with the gap adjustment mechanism of the perforation units, and in which the adjustment mechanism has a structure by which the left ground glass and the left perforation unit are moved symmetrically to the optical center of the left lens as axis of symmetry and the right ground glass and the right perforation unit are moved symmetrically to the optical center of the left lens as an axis of symmetry. A stereoscopic slide projector according to claim 11 or 12, wherein the shapes of the perforation of the pair of perforation units are different. 14. Frame for stereoscopic slides comprising a base frame and a cover frame aligned with respect to two rectangular windows, in which a positioning unit is formed on the base frame to make the images of two films coincide with the windows by means of the coupling with the notches of the film obtained with the perforation units. The stereoscopic slide mount according to claim 14, wherein a plurality of types of cover frames are formed in which the widths of the cover frames between the right and left windows are the same as those of the base frames and the window widths are gradually reduced in relation to the width of the film, the cover frames are selected to be mounted on the base frame to thereby adjust the shielding areas of the outer right and left areas of the stereoscopic slide film.