CH323016A - Cinema projection installation - Google Patents

Description

  

  Cinematographic projection installation The subject of the invention is a cinematographic projection installation.



  Hitherto, when it was desired to project cinematographic images of larger than normal dimensions on a screen, it was necessary to place the whole of a reel of film on a special projector, in order to enlarge the images of this film. This process lacked flexibility. In addition, the special projector just mentioned had to be equipped with a special lens and a special lighting device, so that instead of using only two projectors as in normal projection installations , we were also obliged to have a third projector which was a very expensive device and which was used only occasionally.



  The main aim of the present invention is to eliminate the drawbacks which have just been discussed and to provide a relatively simple automatic installation by means of which it is possible to easily project images of varying dimensions.



  The cinematographic projection installation which is the subject of the present invention comprises a projector intended <B> to </B> project images <B> to </B> from a film, a screen on which the images are projected, and means for forming an edge of variable interior dimensions surrounding the useful surface of the screen.

   It is characterized in that it comprises a mechanism for actuating said means for forming the variable edge, a mechanism for modifying the dimensions and the surface of the images projected on the screen by the projector, and a control mechanism capable of acting simultaneously on said operating mechanism and on said mechanism to modify the dimensions of the projected image, so as <B> to </B> bring the images <B> to </B> to correspond to the dimensions interior sions of the edge and <B> to </B> the useful surface of the screen, in synchronism with the increase, respectively the reduction of the dimensions and the surface of the projected images.



  The drawing represents, <B> by </B> by way of example, an embodiment of the cinematographic projection installation object of the invention. Fig. <B> 1 </B> is a schematic view. Fig. 2 is an electrical diagram of a control unit and of the electrical wiring of said embodiment.



  Fig. <B> 3 </B> is a schematic view of an objective included in this embodiment. Fig. 4 is a longitudinal section of this lens.



  Fig. <B> 5 </B> is a plan view, <B> in </B> developed state, of a detail of the lens shown <B> in </B> in fig. 4. FIG. <B> 6 </B> is a section along <B> 6-6 </B> of fig. 4.



  Fig. <B> 7 </B> is an elevational view of a screen of variable dimensions that comprises the installation shown <B> to </B> in FIG. <B> 1, </B> in the state in which it has its dimensions and maximum surface area and with its actuating mechanism, certain parts of which are shown schematically. Fig. <B> 8 </B> is a schematic view showing the screen of FIG. <B> 7 </B> in the condition in which it has its dimensions and minimum area; and fig. <B> 9 </B> and <B> 10 </B> are detail views, <B> on </B> on a larger scale, of elements shown in fig. <B> 1 </B> and 2.

      In the embodiment shown, the installation comprises a projector comprising essentially (fig. <B> 1) </B> a source of light <B> <I> A, </I> </B> for example a <B> to </B> arc <B> to </B> graphite elec trode lamp, equipped with a mirror F, an objective B, one or more <B> C devices </B> suitable for passing a film of images <B> D </B> between the light source <B> A </B> and the objective B, and a projection screen <B> E < / B> arranged in a practically invariable position with respect to <B> </B> the objective B. In practice, a projection installation comprises two projectors such as the one described above.



  In addition to the elements listed above, the embodiment shown includes means capable of continuously modifying and during the projection of the film <B> D, </B> simultaneously and in accordance with the useful dimensions of the film. screen and the dimensions of the images projected on this screen. Means are provided for changing the focal length of the lens B so as to <B> </B> change its magnification so that, of course, the focus of this lens is maintained on the screen.

   For this purpose, a <B> N </B> control unit is provided and includes a <B> </B> electric relay assembly which controls all the synchronous motors of the installation and which acts on a servo. motor represented matically dried in M1 and which, <B> in </B> in turn, acts on the optics of objective B, and one or more servo-motors represented schematically in <I> M2 and </I> M3 and capable of increasing or reducing the useful height and width of the screen while maintaining these dimensions in a nearly constant ratio, the <B> N </B> control set being as the picture projected and focused on the screen <B> at </B> any given moment coincides with the useful area or surface of the screen,

   in position as well as in dimensions. The center of the screen should preferably be fixed, but it is not excluded to use additional servo motors, also subject <B> to </B> the action of the control assembly <B > N </B> and serving <B> to </B> correspondingly modify the inclination of the projector and the centering of the useful area or surface of the screen. <B> It </B> is advantageous for the installation to include means coupled <B> to </B> the command set <B> N </B> and serving <B> to </B> vary the flux or luminous intensity of the light projected on the screen, so that the luminosity of each image appears practically constant, regardless of the dimensions given <B> to </B> that image on the screen.

   For example, these means are schematically represented by a servo motor M, subjected <B> to </B> the control action of the assembly <B> N </B> and acting on a device <B> Q < / B> can reduce the light intensity of the <B> A </B> source when the dimensions of the image on the screen are reduced, and vice versa.



  Simultaneous changes in screen and image dimensions should be performed <B> at </B> defined times in the projection, because some scenes need to be projected in large dimensions, others in small dimensions and still others according to intermediate dimensions, according to a program established in advance, in order to produce the best possible artistic effect.



  For this purpose, the <B> </B> operator can be left free to manipulate the <B> N </B> command set in accordance with the specific pre-established program <B>; </B> however, it is preferable and advantageous to operate the <B> N </B> control assembly automatically and in synchronism with the progress of the film. For this purpose, the <B> D </B> film itself where, preferably, an auxiliary or pilot tape R driven in synchronism with the <B> D </B> film by means of a <B> S </B> speed reducer gear train carries marks or signals which, when scanned or detected by an appropriate exploration set T, are capable of connecting the control set < B> N </B> so <B> to </B> operate the various motors in the desired direction.

   These marks or signals can be formed either by a photographic trace having successive zones of dif ferent opacities, this trace then being explored by a light beam acting on a photoelectric cell, or else, preferably, by notches or different slits. or by the mutual arrangement of such notches or slits in a longitudinal direction with respect to the film <B> D </B> or <B> to </B> the strip R, or by the arrangement of these notches or slits in the transverse direction, the exploration of said notches or slits then being ensured by a light beam and by a photoelectric cell, or even by several mobile fingers which established feel electrical contacts <B> at </B> the instant when the or the slits pass in front of them.

   The current pulses thus produced act on the control servomotors shown <B> to </B> in fig. <B> 1 </B> through a <B> to </B> relay set of the <B> N. </B> control set



  In the most general case, when the projection installation comprises two projectors or projection groups ABC or more operating alternately, it is sufficient to provide a single <B> N </B> control assembly acting on the servo-motors MI and possibly on servo-motors M4 co operating with each objective B, as well as on servo-motors M., and gq cooperating with the screen <B> E, </B> the latter 'servo -motors remaining the same, whatever the projection group which operates <B> at </B> at any given moment.

   In the case of automatic operation, the command set <B> N </B> is actuated in such a way <B> to </B> react in any case <B> to </B> an exploration set such as T which is sensitive to marks or signals carried by the film <B> D </B> and which passes <B> to </B> through the projection group considered, or <B> to </B> the tape pilot R which operates in correlation with the drive means for said film <B> D. </B> As regards the objective B <B> at </B> variable focal point, this is made up of a group fixed lenses and by a group of movable lenses in relation to the fixed lenses and one in relation to <B> to </B> the other,

   the movements of these lenses being mechanically slaved so as <B> to </B> modify the dimensions of the projected image of the film while maintaining this image in focus on the screen.



  To this end, we could adopt one or the other of a large number of solutions, but the one we have found the most advantageous is to make an afocal set <B> with </B> variable magnification cooperate. with a normal objective <B> at </B> constant magnification. This afocal assembly does not modify the focusing or the aperture of the ordinary cooperating objective, <B> provided </B> that its lenses are of sufficient size to allow the passage of the entire light beam coming from the lens, regardless of the magnification.



  As shown schematically <B> to </B> in fig. <B> 3, </B> the optics of a <B> variable focal point </B> lens include an ordinary lens comprising, for example, two converging lenses <B> 1 </B> and 2 and a afocal assembly comprising a converging lens 4 placed between two di verging lenses <B> 3 </B> and <B> 5. </B> The lenses <B> 3, </B> 4, <B> 5 </ B> of the afocal set are preferably independently achromatic, as shown.



  The ordinary lens including the <B> 1 </B> and 2 lenses produces images of the movie <B> D to </B> endlessly. The divergent lens <B> 3 </B> then forms a virtual image <B> at </B> its focus F '. In order to make the set of lenses <B> 3, </B> 4 and <B> 5 afocal, </B> the lens <B> 5 </B> is arranged so that its focus F5 coincides with the previous image, that is, it forms an infinite <B> </B> image of this one. A slight movement of the lens <B> 5 </B> serves <B> </B> to transfer the last image <B> to </B> infinity on the screen, E which is <B> at </B> great distance.



  However, lenses <B> 1, </B> 2 and <B> 3 </B> are fixed and lenses 4 and <B> 5 </B> are made movable so <B> to </ B > allow the magnification of the set comprising the ordinary lens 1-2 to be modified in any proportions by means of the afocal set 3-4-5, which constitutes a <B> to </ B lens > variable focus, while mechanically connecting the lenses 4 and <B> 5 </B> so as to <B> </B> maintain the image on the screen, as indicated above.



  For this purpose, as shown <B> to </B> in fig. 4, the lenses <B> 1 </B> and 2 which form the ordinary objective and the lens <B> 3 </B> are fixed in a frame <B> 6, at </B> distance between from each other and in the relative positions shown, the frame <B> 6 </B> itself being fixed <B> to </B> a cylindrical tube <B> 7. </B> The lenses 4 and < B> 5 </B> are respectively fixed in frames <B> 8 </B> and <B> 9 </B> which are placed in the tube <B> 7 </B> so <B> to </B> be able to slide and turn relative to <B> to </B> this tube. The <B> 8 </B> and <B> 9 </B> frames are arranged so that the part of the <B> 9 </B> frame which carries the <B> 5 </B> lens is likely to come to fit <B> inside </B> the inside of the frame <B> 8 </B> and thus allow the lenses 4 and <B> 5 </B> to be brought into contact l 'with each other.

   The <B> 8 </B> and <B> 9 </B> frames are provided with <B> 10, </B> respectively <B> 11, </B> legs which extend <B> to </B> through a longitudinal slot 12 made in the tube <B> 7 </B> and which terminate respectively in helical guide slots <B> 13 </B> and 14 provided in an outer tube <B > 15 </B> coaxial with the tube <B> 7 </B> and capable of rotating without moving longitudinally with respect to <B> to </B> this tube. Thrust bearings <B> with </B> balls <B> 16 </B> are arranged between the two tubes <B> 7 </B> and <B> <I> 15, </I> to < / B> their ends.

   The tube <B> 15 </B> is driven in rotation around the tube <B> 7 </B> by means of a metal cable or a pulling and pushing metal wire <B> 17 </ B > which extends <B> through </B> through protective tubes <B> 18 </B> and around a drum <B> 19 </B> attached to the tube <B> 15 </ B > with which it forms a whole.

   Said cable or metal wire <B> 17 </B> is fixed to the drum <B> 19 </B> at a point <B> 80, </B> in order to prevent any slipping (see especially fig . <B> 6) </B> when this cable is driven as shown <B> to </B> in fig. 2 by one of two drums 30a and <B> 30b. </B> It will be understood that, thanks <B> to </B> these means, it is possible to distribute to lenses 4 and <B> 5 < / B> <B> displacements </B> corresponding to the conditions set above, for a suitable layout of the slots <B> 13 </B> and 14.



  The characteristics of the slits <B> 13 </B> and 14 can be determined, either by calculation or by means of measurements carried out on an optical test bench.



  For the calculation of the slits, one can proceed by counting the distances positively in the direction of propagation of the light and <B> to </B> from marked points to the optical centers <B> 01 <I> to </ I> 05 </B> (see fig. <B> 3) </B> of the corresponding lenses. Let us call f3, f4, f5 the distances or focal lengths of the lenses <B> 3, </B> 4 and <B> 5 </B> respectively, <B> dl </B> the distance between <B> 03 </B> <I> and 04, and </I> d2 the distance between 04 <I> and <B> 0 .. </B> 1 </I> will designate the enlargement <B> G < / B> of the optics compared to <B> to </B> the image given by the lens <B> 1 - </B> 2, in <U> two </U> different ways.

    
EMI0004.0009
    From the relation expressed by the formula <B> (1), </B> it is possible to deduce, as a function of <B> <I> dl, </I> </B> the value which must be given <B> to <I> dl + d2, </I> </B> that is to say as a function of the distance <B> to </B> from the leg <B> 10 </ B> up to a fixed transverse plane, and the distance <B> to </B> from the leg <B> 11 </B> up to the same transverse plane. The shape which is appropriate to give to the slots is deduced from these values. If the slot <B> 13 </B> has, for example, a helical shape such that, if the tube <B> 15 </B> is developed on a plane or unfolded <B> to </B> flat like shown <B> to </B> in fig. <B> 5, </B> the slot <B> 13 </B> would have a rectilinear course and the slot 14 would have the shape of a hyperbolic arc.

      Note that the magnification <B> G </B> which, according to the formula <B> (1) </B> is proportional <B> to </B> the value of <B> <I> dl , </I> up to </B> a constant, is similarly, <B> up to </B> a constant, proportional <B> to </B> the relative angle of orientation of the tubes < B> 15 </B> and <B> 7, </B> in the case where the slot <B> 13 </B> is helical.



  When performing the measurements on an optical bench, give a marked position <B> to </B> lens 4 and look for the position of lens <B> 5 </B> which provides projection of the image on the screen <B> E. </B> If, as before, we know the shape of the slit <B> 13, </B> we get point by point that of the slit 14 .

        In any case, one can easily give the desired characteristics to the tube <B> 15 </B> by starting to shape it <B> from </B> from a thin flat metal plate and by tracing the slits < B> 13 </B> and 14 by cutting or filing, as shown <B> to </B> in fig. <B> 5 </B> and in accordance with the determined profile, either by calculation or by measurements made on the optical bench, and by finally bending said metal plate so as to <B> to </B> form a cylindrical tube .



  An objective B <B> with </B> variable focal point, such as that described above and represented in FIGS. <B> 3, </B> 4 and <B> 5, </B> allows the dimensions of the image obtained on the screen to be modified in large proportions. For example, consider the case in which the objective is constituted by an ordinary conventional objective comprising the lenses <B> 1 </B> and 2 and having a focal length of the order of <B> 100 </B> mm , for example, and by the afocal set of lenses <B> 3, </B> 4 and <B> 5, </B> these having the following respective focal lengths <B>:

  </B> <B> t = <I> + 150 mm, </I> </B> f4 = <B> - </B> 100 MM and # -, <B> = <I> + </ I> </B> 150 <B><I>mm.</I> </B> Lens 4 can be moved between the following two limit positions <B>: </B> <B> - </ B > in contact with the lens <B> 3, dl </B> being equal <B> to </B> zero. By replacing the letters of the first part of the formula <B> (1) </B> by their values, we see that the magnification <B> G </B> is equal to <B> to </B> a half <B>; </B> and <B> - </B> in contact with the mobile lens <B> <I> 5, <U> d, </U> </I> </B> being equal <B> to </B> zero. By replacing the letters of the second part of the formula <B> (1) </B> by their values, we see that <B> G <I> = </I> </B> 2.



  The dimensions of the projected image can thus be modified in a ratio of <B> 1 to </B> 4. which is more than sufficient for the needs of the practice.



  When the installation includes two projection groups or two projectors, as is generally the case in projection rooms, a lens B similar <B> to </B> that shown <B> to </ B > fig. 4 and described above is mounted on each of these projectors, the two lenses being subjected <B> to </B> the same command.

   In this way, when we chain <B> to </B> from one reel of film <B> to </B> a following reel, there is no discontinuity in the di mensions of the image. For this purpose, the two projectors being each provided with an objective B reacting <B> to </B> the rotation of drums l9a, respectively l9b (see fig. 2), in the manner <B> de- < / B> written with reference to the drum <B> 19 </B> and for a single headlamp, this rotation being obtained by means of cables 17a and 17b running in sheaths 18a, respectively 18b,

      it is only necessary to pass said <B> cables </B> over similar control drums 30a, respectively <B> 30b, </B> fixed <B> to </B> the same shaft < B> 31 </B> driven by the motor M1 or by equivalent motors 34 and <B> 35 </B> mounted on a shaft <B> 36 </B> (see fig. 2) by means of 'a reduction gear train comprising a worm <B> 32 </B> attached <B> to </B> the shaft <B> 36, </B> and a toothed wheel <B> 3 3 </B> fixed <B> to </B> tree <B> 3 1. </B>



  As regards the screen <B> E </B> of variable dimensions, its frame or edge may be formed, according to a first solution, by masks capable of being moved parallel <B> to </ B > their edges or, according to a second solution, by a luminous projection of a suitable color formed on the part of the screen which should not receive the image.



  According to the first of these solutions, an ordinary white screen surface 20 is employed (see fig. <B> 7), </B> preferably <B> at </B> high brightness, of at least equal dimensions <B> to </B> those of the largest of the images to be projected. The frame or edge of this screen surface 20 is formed by masks or strips of fabric (sheet, velvet, etc., or of an analogous material), preferably of a dark, gray or black color or of n ' any other suitable color to border horizontally and vertically the surface of the image.

   As shown <B> to </B> in fig. <B> 7, </B> horizontal bands 2la and <B> 21b </B> arranged <B> at </B> distance one <B> from </B> the other can be moved parallel to one <B> to </B> the other and in opposite directions. <B> It </B> is the same for two vertical bands 22a and <B> 22b. </B> These pairs of bands are linked and are interconnected in such a way <B> to </B> maintain a constant relation between the usable height a and the usable width <B> b, </B> this relation or ratio of <I> a < B> to </B> </I> <B> b </B> being in general practically equal to the ratio of <B> 3 to </B> 4.



  For this purpose, the pairs of horizontal and vertical bands are respectively fixed, preferably so <B> to </B> able to move in opposite directions, to the appropriate strands of two endless cables <B> 23 </ B> and 24 respectively arranged on sets of pulleys <B> 23 '</B> and 24' and capable of being moved <B> at </B> speeds proportional to the vertical and horizontal dimensions of the surface image, that is to say that, for example, the cables <B> 23 </B> and 24 pass respectively over two pulleys <B> 25 </B> and <B> 26 </ B > (see fig. 2 and <B> 7), </B> whose diameters are in the proportions alb mentioned above and which are rotated <B> at </B> speeds equal to each other.

   By fixing the two pulleys <B> 25 </B> and <B> 26 </B> on the same shaft <B> 27, </B> it is thus possible to drive the horizontal and vertical bands by means of 'a single <U> M. </U> motor, by means of a reduction drive comprising a worm <B> 28 </B> fixed <B> to </B> a motor shaft <B> 28 '</B> and a toothed wheel <B> 29 </B> (see fig. <B> 7 </B> and 2) attached <B> to </B> the shaft <B> 27, < / B> instead of using two engines <U> M., </U> and e? as provided in the general diagram of FIG. <B> 1. </B>



  According to the second solution for the framing of the image surface of the screen by means of a light projection, the screen is preferably provided with double-walled <B> </B> edges (not shown) , that is to say that it comprises an opaque wall on the side of this screen and a translucent and diffusing wall, for example made of plastic, on the side facing the projector. Light sources of various colors are arranged between these walls and are capable of forming horizontal and vertical edges in various positions corresponding <B> to </B> those taken by the mobile bands 21a, <B> 21b, </ B > 22a and <B> 22b </B> described above, the light sources being controlled by switches actuated by the motor <B> 37. </B>



  As regards the means for modifying the intensity of the light projected on the screen, they are intended to eliminate the following disadvantage <B>: </B> the objective B <B> to < / B> variable focus, which has been described above, presents, as was said above, an aperture which is equal <B> to </B> that of the ordinary lens formed by the len lenses <B> 1 </B> and 2 cooperating with the afocal set formed by the lenses <B> 3. </B> 4 and <B> 5. </B> The light flux spread over the image would therefore be constant and the small images would receive much more light than the large ones, which would risk producing a rather unpleasant effect, if this phenomenon was not eliminated.



  For this purpose, the means for modifying the intensity of the light are formed by providing the objective with a diaphragm which can either be actuated by the motor M4 (see fig. <B> 1) </B> under command of the control assembly <B> N, </B> or, even more simply, be connected in a determined angular position to the tube <B> 15 </B> which controls the lenses of the afocal assembly. A -third slit (not shown) can, <B> to </B> this effect, be made in the tube <B> 15 </B> and cooperate with a tab to actuate the diaphragm by means of a transmission ap property, so that this diaphragm is actuated in synchronism with the objective, <B> from </B> from the shaft <B> 3 1. </B>



  The means acting on the intensity of the light source <B> A </B> can, for example, alternatively, comprise a rheostat connected in a determined angular position to the tube <B> 15 </B> and actuated in synchronism with this tube.



  In any event, the law or conditions governing the operation of the diaphragm or rheostat should be determined by experience, so as <B> </B> to please <B> </B> as much as possible. The viewer's eye which, in general, requires that small images be illuminated a little more intensely than large ones.



  Finally, when the <B> N </B> command set is started, it functions to <B> to </B> command and <B> to </B> operate the M motors, <I> and </I> AJ #, and possibly g # <B> at </B> speeds strictly equal to or proportional to each other.

       Since the angular displacements of the drum <B> 19 </B> or of the corresponding drums 19a and <B> 19b </B> to which the enlargements <B> G </B> are proportional are themselves proportional to the angular displacements of the pulleys <B> 25 </B> and <B> 26 </B> to which the dimensions of the screen are <B> to </B> their turn proportional, one thus obtains in a constant manner a coincidence between the surfaces of the image and the screen, <B> with </B> condition of course that the proportionality coefficients, that is to say especially the reduction ratios between the worm <B> 32 </B> (or <B> 28) </B> and the toothed wheel <B> 33 </B> (or <B> 29), </B> the diameters of the pulleys <B> 25 </ B> and <B> 26 </B> and the pitch of the helical slot <B> 13 </B> have been carefully determined.



  As regards the speed of the motors <I> Ml and M. ,, </I> it has been observed that the increase in the dimensions of the image and, consequently also that of the useful dimensions of the screen, should , to satisfy the viewer, take place <B> at </B> a greater speed than their decrease. For this reason, the motors operate so <B> to </B> rotate faster in one direction than the other.



  In a particularly advantageous embodiment of the <B><I>N,</I> </B> control assembly, the control is ensured, on the one hand, by means comprising a main motor arranged at the vicinity of the projectors and capable of actuating their objectives B and, on the other hand, by a motor controlled by the main motor, arranged in the vicinity of the screen and capable of operating the means provided for masking this screen. This arrangement makes necessary a single <B> to </B> relay assembly forming part of the <B> N </B> control assembly and acting on the main motor.



  This main motor is preferably housed in a box, with the relays of the control assembly and a mechanism for <B> </B> controlling the objectives, and it is controlled in a <B> to </ B manner. > turn forwards with a certain speed and backwards with a speed approximately half the speed of its forward travel, for the purpose indicated above.



  Instead of a two-speed <B> </B> motor, it is possible and advantageous to use two motors 34 and <B> 35 </B> (see fig. 2) constituting the main motor means, which rotate <B> at </B> different speeds and in opposite directions and which are attached <B> to </B> the control shaft <B> 36 </B> which carries the worm < B> 32. </B> The pair of motors 34 and <B> 35 </B> corresponds to the motor M, of fig. <B> 1 </B> which it replaces.



  The motor <B> 37 </B> is preferably used to constitute the motor M2, so that the one which actuates the means for masking the screen is slaved to the main motor 34 <B> - 35, </B> the motor <B> 37 </B> operating <B> in </B> the manner of a receiver and being powered by a generator <B> 38 </B> attached <B> to </B> the tree <B> 36, </B> as shown in fig. 2 and <B> 7. </B> At <B> 39, </B> we see the circuit for supplying the assembly with alternating current and, at 40, the connections forming a synchronization circuit.



  <B> Care should be taken to operate motors 34, <B> 35 </B> so that they <B> </B> run <B> at </B> a speed lower than that at which the motor <B> 37 </B> would be able to operate as a synchronous motor. For example, the synchronous speed of a bi-polar motor is equal to <B> at 3000 </B> or <B> at 3600 </B> revolutions per minute for an alternating current supply circuit of a frequency equals <B> to 50 </B> and <B> to 60 </B> periods per second respectively.

   Consequently, motors 34, <B> 35 </B> having rotation speeds markedly lower <B> than </B> these values, for example of the order of 1440 or <B> 1700, are used. </B> revolutions per minute for <B> 50, </B> respectively for <B> 60 </B> periods per second for forward movement (increase in dimensions) and <B> 720 </B> respectively of <B> 850 </B> revolutions per minute for a current of <B> 50 </B>, respectively <B> 60 </B> periods per second, for the backward displacement (reduction of the dimensions ).



  Three electric circuits are provided to control the motors 34 and <B> 35, </B> respectively to increase the dimensions of the image, to make them decrease and to stop the motors, the latter control being provided in order to allow Pro ject according to the intermediate dimensions. Each of the first two circuits is provided with limit switches capable of stopping the motors in the two limit positions corresponding respectively to the maximum and minimum dimensions of the image.



  The three electrical circuits mentioned above can be respectively closed by means of three actuated contacts or switches, either <B> by </B> by hand <B> by </B> using buttons mounted < B> within range of the operator, either automatically <B> with </B> using the film <B> D </B> or the pilot tape R.



  In the latter case, the pilot tape R for each film or projector advantageously comprises, as shown in FIGS. <B> 9 </B> and <B> 10, </B> a section of normal film of <B> 35 </B> mm which is moved by <B> to </B> that of the projector of the movie D,

     <B> to </B> a the gear mechanism propor- ting this band comprising, for example, a pinion 41 (see fig. <B> 9) </B> of the projector over which the film <B> D, </B> a reduction gear <B> S, </B> and a pinion 42 on which the pilot strip passes R. Pinion 41 is coupled <B> to </B> the gear <B> S </B> reducer which it drives by means of an input shaft 41 ', while the pinion 42 is driven by an output shaft 42.



  <B> If, </B> for example, you want to move the pilot tape R <B> at </B> the speed of one perforation 43 per second (see fig. <B> 10), </B> two pinions 41 and 42 of the same size are used and a reduction gear train <B> S </B> of ratio <B> 1/96, </B> the normal film of <B> 35 </ B > mm <B> D </B> moving <B> at </B> the speed of <B> 96 </B> punctures per second. Marks are obviously provided on the <B> D </B> film and on the R tape to ensure their synchronization.



  The three control contacts for each headlamp, intended <B> to </B> operate the three motor control circuits, are respectively actuated by three similar exploration fingers 47, 48 and 49, shown in plan < B> to </B> fig. <B> 10 </B> and urged against the pilot band R by springs such as the tension spring <B> 50. </B> Holes or slits are made in the band R and pass under the fingers <B> to </B> as this band moves.

   The holes, such as those indicated at <B> 51, 52 </B> and <B> 53 to </B> in fig. <B> 10 </B> are distributed across the pilot strip in three rows designated by <B> 1, </B> n and m corresponding respectively <B> to </B> the increase in the dimensions of the image, <B> to </B> decreasing said dimensions and <B> to </B> stopping the increase or decrease in the dimensions of the image. When a hole comes under a finger, the latter lowers and closes <B> the </B> electrical contact for the corresponding control.

   Fig. <B> 9 </B> is a side view of a <B> </B> control switch and <B> </B> finger device with fingers 47, 48 and 49 mounted <B> with </B> pivoting on a rod <B> 72 </B> which extends across the band R and in the vicinity thereof, and which is supported by suitable means, not shown.

   Each finger has a rounded protrusion <B> 73 </B> which slides over the band R and which allows the fingers to swing counterclockwise when this protrusion can enter a hole, such as the hole <B> 52, </B> and as indicated in phantom line <B> to </B> in fig. <B> 9. </B> Fingers 47, 48 and 49 respectively actuate control contacts 44a, <I> 45a </I> and 46a (fig. 2) of electrical switches, in the manner shown <B > to </B> fig. <B> 9 </B> for finger 49, contacts 46a closing a circuit passing through connections <B> 76 </B> and <B> 77. </B>



  If one wishes to obtain <B> at </B> a certain moment or for a certain part of the film <B> D </B> the most large <B> a </B> ande image possible, one practices a hole 51 <B> at </B> the corresponding place of the pilot strip R passing under the finger 47 (row P which is a finger increasing the dimensions of the image.

   When the largest dimensions have been reached, the assembly stops functioning by itself. <B> It </B> is the same for the reduction of the dimensions of the image (hole <B> 52 < / B> in row n). If we want the whole to stop in an intermediate position corresponding <B> to </B> intermediate dimensions of the image, we make a hole <B> 53 </B> which passes under a finger 48 (row m), called stop finger, <B> at </B> the desired location after a hole <B> 51 </B> or <B> 52 </B> which caused the start a modification of the dimension of the image, taking into account that the total length of the stroke, for example in the direction of the increase of the dimensions of the image,

   corresponds <B> to </B> six perforations 43 and corresponds <B> to </B> twelve perforations in the direction of the reduction of dimensions of the image. In practice, in order to ensure a pleasant visual effect, the speed of separation of the masking means from the screen, that is to say the time necessary to pass from the smallest dimension of the image < B> to </B> the largest, must be about six seconds and the closing time of said means must be about twelve seconds.

        Under the conditions generally prevailing and in which two projectors or projection groups each comprise a pilot strip which moves and a mechanism for exploring this strip, the excitation circuit of the relays which control the motors is connected in parallel. so <B> to </B> be able to operate respectively under control of the band itself operating in synchronism for each of the headlamps, and under manual control, three switches being provided for each of these operating modes and each of these switches comprising contacts capable of being actuated, either <B>:

  </B> contacts 44a, <I> 45a </I> and 46a for the first projector, contacts 44b, <I> 45b </I> and 46b for the second projector, and contacts 44c, <I> 45c </I> and 46c for manual actuation, the whole as shown <B> to </B> in fig. 2. Contacts 44, 45 and 46 correspond respectively to <B> to </B> the operation of increasing the dimensions of the image, <B> to </B> the stop operation and <B > to </B> the operation of reducing the dimensions of the image.



  Fig. 2 shows, <B> to </B> by way of example, a possible embodiment of the control relays 54 and <B> 57 </B> for the motors 34 and <B> 35. </ B > The contacts for increasing the dimensions of the image 44a, 44b and 44c are connected by connections 74 and <B> 77 to </B> a supply circuit and actuation of the relay 54 by means of a a low voltage <B> </B> current source such as a battery <B> 55, </B> said relay 54 being capable of closing contacts <B> 56 </B> of a circuit of excitation <B> 91 </B> of engine 34,

   to supply actuating current <B> to </B> from connections <B> 39 </B> and <B> to </B> through branch connections <B> 92 </B> connected < B> to </B> four relay switches 54 and <B> 57. </B> The size reduction contacts of the images <I> 46a, 46b </I> and 46c are connected by connections <B > 76 </B> and <B> 77 </B> in a circuit for supplying and actuating relay <B> 57 </B> by means of the current source <B> 55, </ B> this relay being able to close contacts <B> 58 </B> of an excitation circuit <B> 93 </B> of the motor <B> 35, </B> to supply current to 'actuation: <B> to </B> from connections <B> 92. </B>



  When one of the contacts 44 is closed, current flows <B> to </B> from the source <B> 55 </B> and <B> to </B> through connections <B> 78 </B> and <B> 79, </B> the normally closed switch of relay <B> 70 </B> and the connection <B> 77 </B> to contact 44 which is then closed, then <B> to </B> through connection 74 to the actuating winding of relay 54 and, <B> to </B> through a <B> 82, </B> connection up to 'to contacts <B> 65 </B> and <B> to </B> a connection <B> 83 </B> ending <B> at </B> the other pole of <B> there </ B> current source <B> 55. </B> Similarly, the closing of Pun of contacts 46 causes current to flow <B> to </B> from source <B> 55 </ B > and <B> through </B> through connections <B> 78, 79 </B> and <B> 77 </B> and the contacts- 46 thus closed,

   then <B> to </B> through the connection <B> 76 </B> up to the actuating winding of the relay <B> 57 </B> and, <B> through </B> through a connection 84, up to contacts 64 and <B> to </B> a <B> 85 </B> connection ending <B> at </B> the other pole of the current source <B> 55. < / B>



  Relays 54 and <B> 57 </B> include holding contacts <B> 59, </B> respectively <B> 60, </B> which are connected in parallel with control contacts 44, respectively 46, and in series with the corresponding normally closed limit switches <B> 61 </B> and <B> 62, </B> which are brought into the open position, by a finger <B> 63 </B> which protrudes <B> to </B> from a disk or drum <B> 63 '</B> attached <B> to </B> the tree <B> 31. < / B> The contact of switch <B> 61, </B> which corresponds to the largest dimensions of the image, is connected in series with the winding of relay 54 and connects it to the contacts <B> 59 < / B> of this relay which controls the increase in the dimensions of the image and the screen,

   and the contact of the switch <B> 62 </B> is connected in series with the coil of the relay <B> 57 </B> and connects it to the contacts <B> 60 </B> of this relay which controls the reduction of image and screen dimensions.



  When relay 54 is actuated, it is maintained <B> to </B> the state attracted by current from source <B> 55 </B> and flowing <B> to </B> through the connections <B> 78, 79, 77, </B> the contacts <B> 59 </B> then closed, a connection <B> 86 </B> comprising the switch <B> 61, </ B> a connection 74 ending <B> at </B> the actuating winding of the relay 54, a connection <B> 82 </B> connecting it to the contacts <B> 65 </B> and a connection < B> 83. </B> The relay <B> 57 </B> is similarly maintained, when it has been activated, by current coming from the connection <B> 77 </B> and passing <B> to </B> through the contacts <B> 60 </B> then closed, a connection <B> 87 </B> comprising the switch <B> 62,

  </B> a connection <B> 76 </B> ending <B> at </B> the actuating winding of the relay <B> 57 </B> and a connection 84 connecting it to the contacts 64 , this current ends up <B> at </B> the other <B> pole </B> of the source <B> 55 at </B> through a connection <B> 85. </B>



  Relays 54 and <B> 57 </B> have interrupt contacts 64, respectively <B> 65, </B> which are normally closed and which are connected in series with the actuating winding of the other relay, so that if one of these relays is actuated, the other cannot be actuated.

   The relays 54 and <B> 57 </B> also carry a pair of contacts <B> 66, </B> respectively <B> 67, </B> which are normally open and which are capable of triggering the power supply of an actuating winding <B> 68 to </B> from connections <B> 92 </B> and <B> to </B> through connections <B> 88, </B> respectively <B> 89. </B> The winding <B> 68 </B> is the actuation winding of a shoe <B> 69 </B> of an electric brake rod which acts on a brake drum <B> 71 </B> fixed <B> to </B> the shaft <B> 36, </B> to release this brake as soon as one of the motors 34 and <B> 35 </B> is supplied with current.

    When the current supplying the motor 34 or <B> 35 </B> is interrupted, <B> the </B> current supplying the bearing <B> 68 </B> is also interrupted and the brake <B> 69 </B> energetically acts and brakes the shaft <B> 36, </B> and stops the entire assembly actuated by this shaft.



  The stop contacts <I> 45a, 45b </I> and 45c act on a relay <B> 70 </B> which controls the contacts of the normally closed switch connected in the circuit of the connection <B> 79 , </B> itself connected in series in the excitation circuit of relays 54 and <B> 57. </B> In this way, the supply circuit of these relays is interrupted when one of the contacts <I> 45a, 45b </I> and 45e is closed, current then flowing <B> to </B> by firing from the source <B> 55 </B> and <B> to </B> through connection <B> 78, </B> contact 45 closed and connection <B> 75 </B> up to the actuation winding of relay <B> 70 </B> and, < B> at </B> through a connection <B> 90, </B> to the other pole of the source <B> 55. </B>



  Whatever the automatic or manual operating mode, the cinematographic projection installation, equipped as has just been described, operates accordingly in the way which will now be described. Suppose, for example, that the projector is working and that a hole <B> 51 </B> (fig. <B> 10) </B> belonging to <B> to </B> row <B> 1 </B> of a pilot band R has moved to under finger 47 of the corresponding exploration set. The contact 44a or 44b closes for a short period of time and ensures the excitation of the relay 54 which corresponds <B> to </B> the increase in the dimensions of the image and the screen, this relay being maintained <B> to </B> the excited state by the <B> 59 </B> connection contacts of its winding.

   The motor 34 begins <B> to </B> rotate and operates the lens, and the motor <B> 37 </B> rotates in synchronism and operates the screen masking means. Since the hole <B> 5.1 </B> is not followed, during the period corresponding to the six following perforations 43, by a hole <B> 53 </B> appearing under the contact finger 48 , the assembly stops by itself under the action of the finger <B> 63 </B> which opens the switch <B> 61 </B> and interrupts the flow of current <B> to </ B> through the holding contacts <B> 59 </B> up to the actuation winding of the relay 54, this in the position corresponding to the maximum dimensions of the image and the screen.



  Let us now assume that a hole <B> 52 </B> of row n moves up to under finger 49. Contact 46a or 46b corresponding <B> to </B> the reduction of the dimensions of the image and of the display is closed for a short period of time and ensures the energization of the relay <B> 57 </B> which causes the rotation of the motor <B> 35 </B> and, at the same time as it, of the motor <B> 37, </B> which actuate the objective and the screen masking means, respectively, so as <B> to </B> reduce the dimensions of the image and of the screen. If this <B> 52 </B> hole is not followed, during the next twelve seconds, by a <B> 53 </B> hole coming under the finger 48, the assembly will stop itself by opening the switch <B> 62 </B> using the finger <B> 63 </B> and in the position corresponding to the minimum dimensions of the image and the screen.



  However, if the <B> 52 </B> hole is followed, for example after six seconds, that is to say after the passage of six perforations 43, by a <B> 53 </B> hole coming under finger 48, stop contact 45a or 45b closes and actuates relay <B> 70, </B> thus interrupting current flow <B> to </B> through the holding circuit of the relay <B> 57 </B> which includes the holding contacts <B> 60. </B> The unit then stops in an intermediate position corresponding <B> to </B> of the average dimensions of image and screen, since the duration of a complete reduction of image and screen dimensions is twelve seconds. <B> A </B> from <B> of </B> In this position, the assembly can subsequently operate in the direction of increasing or reducing the dimensions of the image and <B> of </B> the screen, in the manner indicated above.

      It will be understood that, when the means for modifying the light intensity in correlation with the variations in the dimensions <B> of </B> the image and of the screen are actuated <B> from </B> from the 'objective, as described for one embodiment, the brightness of the images projected on the screen is changed during the operations just described so as <B> to </B> to ensure the effect of optimum lighting. The same result is obtained if the motor M4 is actuated <B> to </B> from the control shaft <B> 36, </B> for example by using an assembly comprising a generator and a receiver such as that used for actuating the screen masking means.



  As will be understood from the above descriptions, the specified installation may only be subject to manual control only, for example by means of buttons operating contacts such as contacts 44c, 45c and 46c, without the aid of pilot tape or a similar automatic coordination assembly.

 

Claims (1)

CLAIM <B>: </B> Cinematographic projection installation comprising a projector intended <B> to </B> project images <B> to </B> from a film, a screen on which the images are projected, and means for forming an edge of variable interior dimensions surrounding the useful surface of the screen, characterized in that it comprises a mechanism for actuating said means for forming the variable edge, a mechanism for modifying the dimensions and area of the images projected onto the screen by the projector, and a control mechanism capable of acting simultaneously on said actuation mechanism and on said mechanism to modify the dimensions of the projected image, so <B> to </B> bring the images <B> to </B> to correspond to the internal dimensions of the edge and <B> to </B> the useful surface of the screen, in synchronism with the increase, respectively reduction, of the dimensions and the surface of the projected images. SUB-CLAIMS <B>: </B> <B> 1. </B> Installation according to claim, characterized in that the mechanism for modifying the dimensions and the area of the projected images comprises a variable projector lens , a mechanism for changing the focal length of the lens, and means operable during projection, sensitive to the operation of the projector and arranged to actuate the mechanism for changing the focal length of the lens . 2. Installation according to claim, characterized in that it comprises a variable light source for the projector and means capable of being actuated by said control mechanism to increase and decrease the intensity of the light projected onto the screen by the projector. light source, in synchronism with the increase, respectively reduction, of the dimensions and the surface of the projected images. <B> 3. </B> Installation according to claim, charac terized in that said control mechanism comprises electric motors, an electric <B> relay </B> circuit arranged to control the operation <B> of these motors, this circuit being capable of being put into operation during the projection of the images in order to increase, respectively reduce, the dimensions and the surface of the projected images and the effective interior dimensions of the edge and for ar stop this increase, respectively this reduction, and switches for actuating said <B> relay </B> circuit and respectively producing said increase, <B> </B> reduction and stop operations. 4. Installation according to claim, characterized in that it comprises means capable of being actuated during the projection of the images and sensitive to the operation of the projector, arranged to control the operation of said control mechanism. <B> 5. </B> Installation according to sub-claim 4, characterized in that said means responsive to the operation of the projector comprise signaling means indicating determined changes <B> to </B> made in the dimensions of the images <B> to </B> to project and in the useful dimensions of the screen during projection, means for detecting said signaling means when the film passes through the projector, and means responsive to the signaling means for controlling the operation of said control mechanism. <B> 6. </B> Installation according to sub-claim <B> 5, </B> characterized in that said signaling means are carried by the film. <B> 7. </B> Installation according to sub-claim <B> 3, </B> characterized in that it comprises a mechanism capable of acting on said electric circuit <B> to </ B > relay to stop said operations when there is an increase, the respectively projected images and the useful <B> '</B> reduction dimensions of the screen reach a determined maximum value, respectively minimum. <B> 8. </B> Installation according to sub-claim <B> 5, </B> characterized in that said signaling means are carried by a band, a drive mechanism of which has a drive link. with the headlamp, so that the strip carrying the signaling means is interfered with <B> at </B> a speed proportional <B> to </B> that of the headlamp. <B> 9. </B> Installation according to sub-claim <B> 3, </B> characterized in that the electrical <B> relay </B> circuit comprises a pair of similar electrical relays actuated one < B> to </B> both to excite the motors, a common source of electric current to actuate said relays, a maintenance circuit for each relay, and means sensitive to the operation of the stop switch-switch to open the circuit. of each relay when this switch operates. <B> 10. </B> Installation according to claim, characterized in that said control mechanism comprises common reversible electric driving means having a connection for actuating the mechanism for changing the dimensions and the surface of the images projected on the screen, these reversible means comprising an electric generator, an electric motor for actuating the mechanism acting on the forming means of the variable edge, and means for electrically connecting the generator with the aforesaid electric motor in order to be able to reverse this motor. <B> 11. </B> Installation according to sub-claim <B> 1, </B> characterized in that the variable objective comprises a system of lenses composed of lenses forming an ordinary objective and of lenses forming a afocal objective placed in front of and aligned with the ordinary objective, the afocal objective having a first diverging lens, fixed relatively <B> to </B> the ordinary objective, a converging lens and a second diverging lens placed in series, said mechanism for changing the focal length of the lens being actuated to move said converging lens and said second diverging lens relatively <B> to </B> the first diverging lens and relative to <B > to </B> the other, in a manner determined to change the dimensions of the projected images. 12. Installation according to sub-claim <B> 11, </B> characterized in that it comprises a fixed cylindrical tube surrounding said lenses and on which said fixed diverging lens is mounted, a separate frame for each mounted movable lens <B> sliding in this tube, the latter having a longitudinal slot, a tab fixed <B> to </B> each of said movable lens frames and extending <B> through </B> through said slot, a rotating cylindrical tube coaxial with the fixed tube and surrounding the latter, having slots capable of receiving said tabs respectively, the slot of the rotating tube receiving the tab corresponding <B> to </B> the movable converging lens being d-shaped 'propeller, and the slit of the rotating tube receiving the corresponding tab <B> to </B> the movable diverging lens being in the form of a hyperbolic arc diverges relative to <B> to </B> said helical slit, and an electric motor arranged to rotate said rotary cylinder around the stationary cylinder to axially move said movable lenses in a determined manner controlled by the characteristics of the slots of the rotary cylinder. <B> 13. </B> Installation according to sub-claim <B> 8, </B> characterized in that said strip has separate parallel rows of signaling means for increasing, reducing, respectively stopping, the either of the increase and decrease operations, and separate detection means for each of said rows for actuating the corresponding electric switches in the electric control circuit.