DE1235025B - Projector for slides - Google Patents

Description

Projection apparatus for slides The invention relates to a projection apparatus for slides with a lifting mechanism for lifting and lowering the slides from a magazine into a Projection window and back into the magazine and a switching device for step-by-step Transport of the magazine.

In such projection apparatus, the switching device is known to be coupled with the elevator so that the transport of the magazine between the lowering one slide and the lifting of the next slide takes place.

A disadvantage of this known projection apparatus is that to each Image change the elevator and the switching device must be driven by hand. Especially when showing a large number of slides, the drive is from Hand very annoying.

The invention is based on the object of a projection apparatus to create with the simplest possible mechanical structure and with as possible simple control means enables fully automatic operation, so that after After the start signal, no further actuation is required until all slides in the magazine are projected.

This object is achieved according to the invention in that a clutch, by means of which the elevator and the switching device with a constantly running Motor can be coupled, and a cooperating with the driven part of the clutch Actuator are provided that the clutch in the position of the elevator turns off, in which a slide is lifted into the projection window, and that the actuator a switch-on device controlled by the motor is assigned which, according to a selectable Time the clutch switches on again.

Through the use of the clutch, which couples the constantly running motor with the gearbox of the projection apparatus until a slide is lowered out of the projection window, the magazine is moved one step forward and the next slide is lifted back into the projection window, it is achieved that all operations required between projecting two slides can be performed continuously in a single operation cycle. The duration of the individual work steps to be carried out is completely independent of the time in which the slide is to remain in the window. This uninterrupted working cycle can therefore be carried out in the same way for all cases. The only thing that still has to be regulated here for fully automatic operation is the time interval between the end of a previous work cycle and the start of a subsequent work cycle, i.e. That is, the time within which a slide is in the projection window. This time is determined by the switch-on device assigned to the actuator and controlled by the motor, which switches the clutch on again after a selectable period of time. As a result of the self-disengaging clutch and the combination of all movements of the parts of the projection apparatus in a single, coherent work cycle, it is achieved that the fully automatic operation can be carried out with the simplest possible control means. The clutch creates the possibility of making the mechanical structure as simple as possible, since this allows the entire transmission in the projection apparatus to be built together and individual assemblies do not have to be switched separately.

In order to be able to carry out the slide change fully automatically and still have the possibility of keeping the individual slides in the projection window for a certain preselectable time, the switch-on device can be equipped with an adjustment device that has various switch-on positions assigned to the selectable time periods and a switch-off position in which the closing device remains in a rest position which does not cause reclosing. Is achieved in that after each expiration of a - working cycle, after the clutch is turned off after the set beforehand by means of the adjusting time a new operating cycle of the slide change begins.

In a preferred embodiment of the invention it is provided that the lifting mechanism and the switching device are coupled to one another via a drive device which has a crankshaft connected to a hand crank, and that the driven part of the switching clutch is connected to the crankshaft via a unidirectional coupling which only a force directed in a particular direction of rotation of rotation of the actuator is transferred to the crankshaft, is but effective upon application of an external torque to the crank handle los.

To be able to take out individual slides without taking out the whole magazine To remove the projector from the projector, a hand-operated issuing device be provided, by means of which a slide located in the projection window in a Position can be lifted out in the hand out of the projector is removable. In order to avoid a slide being lifted out of the projection apparatus can be switched on while the auto-starter is on Locking means are provided that connect the dispensing device to the adjustment device couple in such a way that it is normally blocked and only released when the automatic switch-on device is switched off.

To the switching device of the slide magazine independent of the elevator to be able to operate, so that the slide magazine can be moved without changing the slide can, can act between the drive device and the slide magazine Parts of the switching device a switchable by means of a hand-operated organ, normally engaged transmission coupling may be provided. Will the hand operated Organ coupled directly to the parts acting on the slide magazine, then can by actuating this organ after disengaging the transmission clutch the slide magazine can be moved without operating the elevator. To continue now to achieve that the slide magazine only then moved by means of the hand-operated organ can be when the elevator is in its lowest position, in the the slide captured by the elevator is in the magazine, the hand crank for the manually operated organ form a lock that disengages the transmission clutch by means of the organ only allows if the drive device is in a predeterminable Phase of a work cycle is, namely in the phase in which the elevator is its has reached the lowest position.

The invention is described below with reference to an exemplary embodiment shown in the drawings. les described in detail. 1 shows a diagrammatic representation of the structure of the projector for slides, FIG. 2 is a perspective view of the hand crank shaft and the mechanisms for moving the elevator and bezel, as viewed from the top left of the projector, FIG . 3 is a diagrammatic representation of a magazine for cardboard-framed slides, FIG . 4 is a diagrammatic partial representation of a magazine for glass-framed slides, FIG . 5 shows a partial view of the magazine base with ventilation slots, FIG. 6 is a partial illustration of a top view of the lens and projection window systems of the projector, FIG. 7 is a rear view of the projection window, dispensing mechanism and ratchet wheels, FIG . 8 is a front view of the projection window, elevator and shutter mechanisms, and ratchet wheels, FIG . 9 is a cross-sectional illustration of the left side of the projection window, the elevator and delivery mechanisms and the switch carriers, FIG . 10 shows a section along line 10-10 in FIG. 7 through details of part of the issuing mechanism, FIG. 11 is a plan view of the control and shift transmissions, FIG. 12 is a diagrammatic representation of an electromagnet for switching the clutch, FIG . 13 is a right-hand side view of the control and manual transmissions, FIG. 14 is a view of a section along the line 14-14 in FIG . 13 from the front, with the manual transmission and its control, F i g. 15 is a plan view of the gearbox for the motor drive, an automatic switch-on device with an adjustment device for setting the switching periods and the fan, FIG . 16 is a right side view of the mechanism of FIG . 15, fig. 17, 18 and 19 a plan view of the automatic switch-on device with the setting device in a second, a third or a fourth position, FIG. 20 is a left side view of the hand crank coupling in half-cycle position during manual forward drive, FIG . 21 shows a section along line 21-21 in FIG . 20 seen from the front, FIG. 22 is a left side view of the winch clutch in an intermediate position for the automatic forward-drive, showing the operation of the hand crank, when a fault occurs in the machine, F i g. 23 is a left side view of the hand crank coupling in an intermediate position for reverse hand drive and for maintaining automatic operation by hand, FIG. 24 shows a bottom view of the preheating channel, FIG . 25 shows a representation of the preheating channel from the front, and FIG. 26 is a schematic diagram of the electrical circuit in the projector.

During each slide change cycle of the projector, a slide holder with its slide is lowered by a lifting mechanism from the projection window into a compartment of a slide magazine, the slide magazine is preceded by a slide compartment, and a new slide holder is brought back into the projection window by the lifting mechanism, where the slide follows aligned with the optical axis of the projector. A shutter is removed from the optical axis when the slide holder is fully seated in the projection window and is returned to its old position before the holder is removed from the projection window. The in F i g. 6 , which are arranged along the optical axis, comprise a reflector 10, a projection lamp 12, a series of condenser lenses 14, 16 and 18, a projection window, which is designated as a whole by 20, and a focusing unit 22. The reflector and the condenser lenses are held in special frames 11, 15, 17 and 19, respectively, which are held in slots 24 by two side walls 26 and 28 . The reflector and condenser lenses are easily removable for cleaning and replacement when a lid 30 of the machine is folded back, as shown in FIG. 6 shown. When the cover 30 (see also FIG. 1) is closed, a series of spring fingers 32 (see also FIG. 7) engage the surfaces of the respective frames 11, 15, 17 and 19 to prevent the To hold the reflector and the condenser lenses firmly in their given positions.

In the F i g. 6 to 9 shows that the projection window 20 comprising a support plate 36 having a pair of forwardly extending vertical Flanscheu 38 (s. Also F i g. 2) that are adjacent to an opening 40. A pressing runner 42 is pressed against the flanges 38 by a spring member 44.

The runner 42 and the spring 44 both have the general shape of an open square that surrounds the opening 40. The pressure skid is bent forward at 43 (FIG . 9) to form a sliding surface for inserting a holder 46 for slides between it and the flanges 38 .

The focusing or adjustment unit 22 ( FIG. 6) is arranged on a plurality of rails 48 for longitudinal displacement thereon by means of a focus adjustment knob 49.

The lamp, the reflector, the condenser lenses, the projection window and the adjustment units are well known in the art and are here only shown and described in association with the other elements of the projector, the embody the invention.

A slide change cycle can be started by turning a hand crank in one of be carried out in two directions. The only difference in the cycles as between The two directions of hand crank rotation is the direction in which the slide magazine is switched. One direction is called a forward shift, the other is called a reverse shift designated. The following is the movement of the slide magazine from the front to the rear of the projector is called forward switching.

A slide change cycle can also be performed by manually pressing a push button triggered and then continued automatically. During this cycle will the slide magazine is only switched in the forward direction. When the push button is depressed is held, slide change cycles follow in rapid succession and allow a control by observing the slides in the magazine.

A third means of initiating a slide change cycle, during which only a forward shift occurs, is a button to select one of several cycle times, such as 4, 8 and 16 seconds. However, the automatic operation can be skipped at any selected cycle time either by pressing the push button to switch forwards or by pressing the hand crank to switch in any direction. The hand crank can also be held in order to prevent a slide change, which would otherwise happen in automatic operation.

A manual switch is provided to turn the magazine in the projector to switch in any direction. About the mutual action of two slides to prevent each other in a compartment of the magazine is the button with the Hand crank coupled so that manual switching can only be carried out when all slide holders are in the magazine. A special trigger mechanism for emergencies is provided to remove the magazine from the switching mechanism, regardless of the position the hand crank to release, if a malfunction occurs in the projector, z. B. is due to a bent slide holder.

A release lever is provided to keep a slide holder from the projection window position in a higher position in which the slide in the holder by hand an opening in the lid of the machine can be removed from the projector. Through this it is possible to change or rearrange individual slides without having to do that Magazine moved in the projector.

A single motor is provided both for the automatic slide change and for the push-button operation as well as for the operation of a ventilation blower The magazine is preheated and dried. This prevents the slides from warping in a non-adjusted position if they are later exposed to the elevated temperature created by the projection lamp in the projector. Holder for slides and magazines As in Fig. 3 As can be seen, each slide holder 46 consists of a U-shaped frame with leaf springs 52 for holding a slide 50 inserted into the socket of the frame, a pair of orientation tabs 54 arranged on one side of the frame which are perpendicular to the surface of the holder The noses 54 serve to ensure that each slide holder is only read into the magazine 60 in a front and back orientation can be used. The orientation noses 54 cooperate with partitions of the magazine compartments, which consist of relatively long ribs 62 on one side of the magazine and of relatively short ribs 64 on the opposite side of the magazine. The respective lengths of the ribs 62 and 64 are such that a slide holder can only be inserted into the magazine if the lugs 54 are on the same side of the magazine as the ribs 64. If an attempt is made, a slide holder in the reverse orientation to be inserted into a magazine, as in 50 a. the lugs 54 abut the longer ribs 62 and block the further penetration of the holder. Although two orientation tabs are shown, the same result can be achieved using only one such tab.

A pair of lifting lugs 56 are attached to the top of each slide holder and extend outwardly therefrom. Lugs 56 never cooperate with the lifting mechanism, as described later herein, to convey the slides between the magazine and the projection window.

A toothed strip 66 forms part of one side of the magazine 60 and cooperates with a gear 67 ( FIGS. 7 and 9), which is the smaller of two indexing gears 67 and 77 . Both gears are mounted on a switching shaft 69 which, as described later, is driven by the switching mechanism in order to switch the magazine in the projector. The tooth spacing of the rack 66 (F i g. 3) corresponds to the space between the successive ribs 62 and 64, such that the Längsbewe- "ung 0 of a magazine by means of the feed of a toothed strips tooth the projection window with the next magazine compartment brings into agreement.

The magazine and the holder in FIG. 3 can be understood as a cardboard diamond magazine and holder, in which the tooth spacing of the toothed bar and the space between the shelves are relatively short. In Fig. 4 shows a second magazine 70 which is provided with a toothed strip 76 which has a relatively wide tooth spacing. The space between the successive septum ribs 72 and 74 corresponds to the larger tooth spacing of the toothed strip 76. The toothed strip 76 is arranged lower on the magazine 70 than the corresponding toothed strip 66 on the magazine 60 ( FIG. 3) and protrudes further out of the magazine, see above that when the magazine 70 is inserted into the projector, the rack 76 meshes with the gear 77 ( Figs. 7 and 9) . The wider compartments of the magazine 70 allow it to hold thicker slide holders that are suitable for holding cardboard or glass slides.

A corresponding guide 68 and 78 ( FIGS. 3 and 4) is attached to each magazine 60 and 70 on the side opposite the toothed rack and, together with a bow bar 71 ( FIG. 7) in the projector, serves to guide the magazine through the projector.

In Fig. 5, which shows the bottom view of a magazine, it can be seen that each magazine has a series of slots 79 distributed along its bottom to cooperate with a preheat channel in a manner to be described later herein. The Elevator The present projector includes an elevator which, during a slide changing cycle, lowers one slide holder from the projection window into the magazine and lifts a next slide holder into the window for projection.

The in the F i g. 2, 6, 8 and 9 elevator, designated as a whole at 80 , includes a guide member 82 and an elevator member 84 which are riveted or otherwise connected as shown at 86. The outer front member 82 is used to guide the elevator in a vertical path between the magazine and the projection window, while the inner, rear member 84 is used to raise and lower the slide holder.

The projection window support plate 36 ( Fig. 2) has a forwardly extending vertical flange 34 disposed along its inside. The flange 34 has a vertical groove 35 which cooperates with a pair of upper and lower guide feet 88 which are attached to the guide member 82 by means of corresponding washers 89 . The outer front edge of the support plate 36 forms a sliding surface 37 which cooperates with a third guide foot 90 which is arranged on the link 82. The guide feet 88 and 90, which are preferably made of plastic or the like known commercially under the name nylon, guide the entire lifting mechanism up and down along the groove 35 or the surface 37 .

An arm 92 with a fork-shaped end protrudes forwards from the guide member 82 and is designed to receive a stub shaft 94 which is arranged at one end of a lifting lever 96. The other end of the lever 96 is rotatably supported about a pin 97 on the aforementioned inner vertical wall 26 of the projector. A fine spring 98 is secured between the stub shaft 94 and the member 82 in a position between the guide feet 88 and 90. The spring 98 presses the guide feet 88 and 90 against the vertical groove 35 and against the guide surface 37 and holds the entire lifting mechanism in a vertical plane. The lever 96 swings back and forth about the pivot 97 , as described below, to move the elevator up and down.

The lifting member 84 of the elevator that moves with the guide member 82 has, on each side of a pair of lifting brackets 85. The brackets 85 engage the previously described lifting lugs 56 of the slide holder 46 at as best shown in F i g. 7 and 8 can be seen to transport the slide holder from the magazine 60 to the projection window and back again.

Release mechanism To enable slides in the projection window position The projector can be removed and replaced is a release mechanism provided that lift a slide holder from the projection position into one position by taking the slide out of the projector by hand can.

The release mechanism is best illustrated in FIGS. 7, 9 and 10 and has a lever 100 which is rotatably mounted at 102 on the support plate 36 of the projection window. The right arm of the lever 100 protrudes as shown in FIG. 7 , through a vertical slot 104 in the machine cover 30 and has a button 106 (see also FIGS. 1 and 6) by means of which the lever can be pivoted clockwise around the pin 102 against the tension of a helical spring 108 . A cam lever 110 is mounted pivotably about the pin 102 and attached to the lever 100 at a point 111 of the lever arm facing away from the spring 108. The lever 110 is made of spring steel or the like, and its left end is, as in FIG. 7 shown, pushed away from the lever 100 resiliently. A sliding tip 114 on the lever 110 presses against a guide surface 116 on the support plate 36 of the projection window and normally holds the lever 110 parallel to the lever 100, as shown in solid lines in FIG. 10 shown. When the lever 100 (in Fig. 7) is pivoted clockwise, the lever 110 pivots clockwise with it, and as soon as the tip 114 comes up, it slides to the right on the guide surface (Fig. 10) . A nose 118 provided at the end of the slide lever 11-0 moves with it to the right and grips the nose 54 of the slide holder 46, which is located in the projection window, and lifts it out above its window position. When the lever 110 has been raised to the position shown in phantom at 110a, the upper side of the slide 50 in the slide holder is in the position shown in FIG. 9 position shown raised. The upper part of the window 20 is extended upwards, as shown at 21 ( Figs. 1 and 9), and forms a recess so that the slide can be removed from the projector by hand. When a slide is removed from the projector in this manner, the lever clamps 85 ( FIG. 8) cooperate with the lifting lugs 56 of the slide holder to retain it in the window.

Hand crank drive Both the previously described hoist and a shutter and a cyclic magazine switching mechanism are always through a Hand crankshaft operated. The hand crankshaft can alternately either d; rect be driven by a hand crank or indirectly by a motor.

In Fig. 2, the hand crankshaft is designated by 120. This shaft is keyed to the hand crank as shown at 122 (see also Figures 1 and 6) and is hollowed out to receive a clutch shaft 124 which will be described below. The crank handle is operated by a protruding button 123 attached to it. The shaft 120 is supported in a bearing 126 of the vertical wall 26 previously described. On the other side of wall 26 , shaft 120 is keyed to a gear 130 (Figs. 11 and 13). The gear 130 meshes with a gear 138 that is attached to a shaft 140. A steering wheel 142 is also mounted on the shaft 140. The ratio of gears 130 and 138 is one; therefore, the wheel 142 rotates once per revolution of the hand crank. An inner curve 144 is provided in the side surface of the wheel facing the wall 26. A pin 146 engages the cam 144 and extends through a slot 148 in the wall 26. On the other side of the wall 26 , the pin 146 is connected to the elevator lever 96 . The shape of the curve 144 is such that during one full revolution of the wheel 142, the lever 96 is pivoted back and forth in its own vertical plane about its pivot 97 ( FIG. 2) to lower the elevator to the magazine 60 first and then lift it into the projection position. Iris Wheel 142 ( Fig. 13) also operates an iris during each revolution of the hand crank. The periphery of the wheel 142 has a flat 150 which interacts with a pin 152 which passes through a slot 154 in the wall 26 . A fine spring 1.51, which is arranged on a first projection 153 of the wall 26 , is located between the pin 152 and a second projection 155 of the wall and keeps the pin in contact with the flat 150 on the wheel 142. On the other side of the wall 26 (FIGS . 2, 5 and 11) the pin 152 is connected to a diaphragm bracket 156 carrying the diaphragm 158 . The bracket 156 is rotatably mounted in the wall 26 at 160. During each revolution of the hand crank and wheel 142, the diaphragm bracket 156 is pivoted down about its pivot 160 and then up again ( FIG. 2). The position of the flat 150 ( FIG. 13) is with regard to the shape of the curve 144 such that the diaphragm is lowered just before the lowering of the elevator to a position in which it lies in front of the projection window opening 40, and after that Hebewerk has just placed the next slide holder in the projection window, is lifted from this position. Therefore, movement of the slides is not projected. Cyclic switching Each revolution of the hand crank switches the C magazine in the projector by an additional distance, which corresponds to the distance between the successive compartments in the magazine. As previously explained, the movement of the magazine is brought about by a toothed wheel 67 or 77 ( FIG. 7) according to the type of magazine in cooperation with a toothed strip 66 or 76 ( FIGS. 3 and 4) on the magazine. During each revolution of the hand crank, the two gears 67 and 77 are given an additional rotation in the following way: A locking disc 162 ( Fig. 11 and 1.3) of a Geneva cross is attached to the crank shaft 120, and a Geneva gear pin 164 is on the one before Gear 130 of the shaft 120 described is attached. Locking disk 162 and pin 164 cooperate with a Maltese cross 166 , which is arranged on a stub shaft 168 so that it can rotate freely. A gear 170, which is fastened to the Maltese cross 166 , engages in a gear 172 (see also FIG. 14) which is rotatably mounted on the switching shaft 69 described above. A driving part 176 of a multi-toothed clutch 180- is rotatably arranged on the shaft 69 and attached to the gear 172. A driven part 178 of the clutch 180 is mounted on the shaft 69 which is supported in the vertical wall 26 . A coil spring 182 is arranged on a hub 173 of the gear 172 and is compressed between the gear 172 and a vertical plate 184 in which the hub 173 is mounted. The spring 182 normally presses the driving part 176 of the clutch 180 into engagement with its driven part 178 and thereby normally closes a flow of force between the hand crank and the shift shaft 69.

The Maltese cross gear pin 164 ( Fig. 13) causes the Maltese cross 166 and gear 170 to rotate once during each revolution of the crank handle. The translation of the gears 170 and 172 is such that, during one revolution of the hand crank, the shaft 69 ( FIG. 14) is rotated by an angle which corresponds to one tooth of the drive wheel 67 or 77 ( FIG. 7). The angular position of the pin 164 ( FIG. 13) on the gear wheel 130 is such that the cyclic switching action occurs approximately at the changeover point of the hand crank rotation. At this time the elevator is completely down. Therefore, when the magazine 60 ( FIG. 7) is switched, the lifting lugs 56 of the next slide holder 46 come into a common position with respect to the lifting clamps 85 located at the very bottom, so that this next slide holder is in a position in which it is located can be lifted out by the hoist during the second half of the hand crank movement.

Manual Shift The manual shift is accomplished by first disengaging the clutch 180 ( Fig. 14) and then manually rotating the driven portion 178 of that clutch independently of the driving portion 176 of the clutch.

A manual switch knob 190 (F i g. 1, 6 and 20) to a shaft 192 (g F i. 6, 9, 11 and 14) attached, which for longitudinal sliding movement in holes of two vertical walls 26 and 28 (F i g 6 and 14) is held. On the side of wall 26 opposite the projection window, a gear 194 ( Figs. 11, 13 and 14) is mounted on shaft 192 . The gear 194 has a large hub 196 with a flange 198 which rotatably and slidably rests against a protruding surface 175 of the gear 172. When the manual control button 190 ( FIG. 1) is pressed against the center of the machine, the shaft 192 and gear 172 move to the right, against the tension of the spring 182 , as in FIG. 14, and so uncouple the clutch 190. When the button is pressed against the center of the machine, it can be used to rotate the gears 194 and 179 and the control shaft 69 independently of the hand crank and thus to move the magazine as far as desired to move in either direction. When the switch button is subsequently released, the spring 182 pushes the gears 172 and 194, the shaft 192 and the switch button 190 ( FIG. 1) back to their original position. Pointed teeth 181 ( FIG. 14) on the driving and driven parts of the clutch 180 mesh with one another during rotation, so that the engagement of the clutch always corresponds to a full cycle.

To prevent the magazine from being switched when the elevator is not all the way down, the switch button is coupled to the hand crank and can only be pressed against the center of the projector when the hand crank is in its position corresponding to half a cycle. At that time is that Elevator at the bottom, and all slide holders are in the magazine; therefore, the operator can the machine doesn't lock up when trying to capture two slides at the same time in one single compartment of the magazine.

Like F i g. 1 and 20 show, the manual shift knob An arcuate recess 125 intersects 190 the hand crank 122 in the hand crank the knob 190 only matched and the button can be thus only pushed down when the hand crank half cycle position is in "". In all other positions of the hand crank, as in FIG. 22 and 23 , the edge of button 190 is over the edge of the hand crank and the button cannot be depressed.

Uncoupling of the circuit in an emergency As it is possible that a bent The slide holder is jammed in the projection window or other blockages occur, when the elevator is at the bottom is an aid for such emergencies provided to disengage the clutch regardless of the position of the elevator.

As in Fig. 11, 13 and 14, a lever 200 is supported at 202 in a vertical wall 204 of the projector. The lever 200 has an upper horizontal arm 201 which extends through a slot 206 in the wall 26 and has a finger grip 208 at the end. A vertical arm 203 of the lever 200 connects the arm 201 to an underlying horizontal arm 205 from which a nose 214 extends perpendicular to the plane of the lever and contacts the above-described protruding surface 175 of the gear 172. A spring 210 is attached between the wall 26 at 215 and a nose 212 of the arm 203. Depression of the finger piece 208 on the arm 201 actuates the lever 200, as in FIG. 14, counterclockwise and against the tension of the spring 21.0 and moves the nose 214 and the gear 172 to the right. This disengages the clutch 180. It can be seen that operation of the lever 200 disengages the clutch 180 even though the switch button 190 ( FIG. 1) cannot be depressed. This allows the magazine to be removed from the projector by hand in order to carry out necessary repairs or adjustments. Since gear 194 ( Fig. 14) is always in mesh with wide gear 179 even when the switch button is not depressed, that button in conjunction with lever 200 can be used to remove the magazine from the projector. Motor drive The manual crank shaft 120 (Figs. 2, 11 and 13) is operated by a motor by means of a spring clutch, the above-mentioned coupling shaft 124, a hand crank coupling and the hand crank shaft 120 for the slide change effected by the push button or automatically.

The in the F i g. 15 and 16 , denoted by 220, the motor of the projector is fastened to a vertical angle frame 222 by two bolts 224, 226. The frame 222 is attached to the aforementioned vertical wall 184 at 228 and to the projector floor at 230 and 232 , as at 234 in FIG. 16 shown. A motor shaft 236 protrudes to the left and right of the motor, as shown in FIG. 15 and 16 shown. The left piece of the motor shaft protrudes through an opening 238 in frame 222.

A worm gear 240 is attached to the left end of the motor shaft and meshes with a worm wheel 242 which rotates freely on the clutch shaft 124. The end of the coupling shaft is held in a bearing bushing 243 which is attached to a Carrier 244 is mounted. The carrier is supported on frame 222 at 246.

A gear 250 and. a hub 252 is integral with the worm wheel 242 and rotates freely on the coupling shaft 124. The gear wheel 250 is in operation, as described below, during the automatic slide change. The hub 252 ( FIG. 11) is keyed to a sleeve 254 that is rotatably disposed on the shaft 124. The sleeve 254 and a second sleeve 256 mounted on the shaft 124 have reduced diameters on the corresponding and facing sides. The reduced diameters of the sleeves 254 and 256 are closely supported in a coil spring 258 , one end of which is attached to the sleeve 256 and the other end of which is tangent to the sleeve at 260 (Figs. 11, 12 and 16). The sleeves 254 and 256 form a spring clutch of a known type with the spring 258. When the free end 260 of the spring 258 can rotate, the spring tightly biases the sleeves 254 and 256 together and couples the motor 220 to the coupling shaft 124. When the free end 260 of the spring 258 is held, the coils of the spring loosen and the sleeve 254 rotates within the spring without driving the sleeve 256 and shaft 124.

Fi g. 12 shows that the mechanism provided for selectively holding or releasing the free end 260 of the spring 258 consists of an armature plate 262 of an electromagnet 264. The plate 262 has a recess 266 that forms a hook 260 when the armature is in its upright or anti-clockwise position (as shown in F i g. 12), the spring end then and only then detected. A coil spring 263 ( Figs. 12 and 16) normally holds the anchor plate 262 in its counterclockwise position against a stop 264 '( Fig. 16) in which it holds the spring end 260 of the coupling in place. When the coil 268 of the solenoid 264 is energized, the armature plate 262 is lowered to its clockwise position with respect to the coil, as shown in FIG. 16 , thus releases the spring end 260 of the coupling for rotation, thereby enabling the coupling to be fixedly connected to the drive shaft 124. When the shaft 124 is driven, it normally drives the crank shaft 120 ( Figs. 2 and 11) through a hand crank clutch described below and thereby also drives the elevator, shutter and cyclic indexing mechanism as set forth above.

The solenoid 268 of the electromagnet 264 ( Figs. 12 and 16) can be energized for any desired length of time by means of a push button switch, described below. If the solenoid is energized for only a moment, as is usually the case, the armature plate 262 is released from its clockwise position (Fig. 16) before the spring 258 (Fig. 11) has completed one revolution; therefore, after the first full turn of the spring 258, the plate 262 again grips the spring end 260 and thereby switches off the spring clutch. If the solenoid 268 remains energized for more than one revolution of the spring 258 , the spring clutch remains engaged for a corresponding number of revolutions but is always disengaged in its position corresponding to a full cycle. Automatic Slide Change The projector of the present invention includes means independent of the solenoid 268 (Figs. 12 and 16) which can actuate the armature plate 262 of the solenoid 264 and thereby engage the spring clutch. These means are automatically actuatable at each of a large number of selected frequencies.

The above-described gear wheel 250 ( FIGS. 15 and 16), which forms a whole with the worm gear 242, meshes with a gear wheel 270 which is mounted on a shaft 272 for free rotation. Gear 274 is integral with gear 270 and meshes with gear 276 which is mounted on shaft 278 for free rotation and sliding movement. The shafts 272 and 278 are attached to the vertical wall 184 described above. A coil spring 280 ( Fig. 15) is compressed between a hub 282 of the gear 276 and a washer 284 which is held at the free end of the shaft 278 by a spring clip g 286 (Fig . 16) . A steering wheel 288 forms a whole with the gear wheel 276 and has a flat end face 298 which cooperates with a rectangular curve 300 . The cam is rotatably mounted by a bolt 302 to a horizontal flange 304 of the wall 184, extends through a rectangular opening 306 in the wall 184 and contacts the surface 298 of the steering wheel 288. The bolt 302 has a button 303 ( FIG. 1 and 16) for manual rotation and is offset from the center of curve 300. By turning the bolt 302 and the cam 300 by means of the knob 303 , the edge surfaces of the cam are turned towards the steering wheel 288 , so that this and the gear wheel 276 assume four different axial positions in relation to the shaft 278 , as shown in FIG. 15, 17, 18 and 19 , respectively. The spring 280 ( FIG. 15) holds the gear 276 and the wheel 288 firmly against the facing edge surface of the cam 300 and thus acts as a detent for holding the rotated cam setting.

The steering wheel 288 has four lugs 290, 292, 294 and 296 evenly spaced around its periphery. The lugs 290 and 294 extend from the surface of the gear 276 a predetermined distance against the wall 184; the projection 296 is about twice as long and the projection (y 292 about three times as long. The projections of the wheel 288 are provided for cooperation with a vertical arm 265 on the armature plate 262 of the electromagnet 264. The arm 265 is best in F i g. 12, but g also in F i. shown 15 to 19. for F i g. 16 it can be seen that the tip of the arm is disposed in such a vertical position 265 as to each of the approaches of the wheel 288 When a lug engages arm 265 , it momentarily moves anchor plate 26-1 clockwise, as shown in Figure 16 , thereby engaging the spring clutch for one cycle of operation.

When the cam 300 is supported as in FIG. 15 , it sets the steering wheel 288 to the shaft 278 in such a position that only the two longest lugs b 292 and 296 grip the arm 265 . Lugs 292 and 296 are located opposite one another on wheel 288; therefore, a slide change cycle takes place twice at equal time intervals during one revolution of the steering wheel. The ratios of the various pairs of gears 240, 242, 250, 270, 274 and 276 can be selected so that the steering wheel rotates in any desired period of time. In the projector shown, the steering wheel rotates every 16 seconds. Therefore, a slide change cycle occurs every 8 seconds when the curve 300 as in FIG. 15 is shown.

When the curve 300 in the, in FIG. 17 is brought all four lugs on the dial are in the same vertical plane with the arm 265 of the anchor plate 262, so that each of the lugs causes a slide change cycle and a cycle takes place every 4 hours. When curve 300, as shown in FIG. Is mounted 18, only the longest approach 292 detects the steering wheel arm 265, and a Diawechselzyklus is caused only once during each rotation of the control wheel, d. H. every 11 seconds. Finally, when curve 300, as in FIG. 19 is mounted, none of the lugs on the dial is in the same vertical plane with the arm 265, and an automatic slide change cannot occur. This position of curve 300 is referred to as “manual”. Issue interlock It is desirable to prevent the above-described issue lever from operating during automatic slide change, thereby eliminating interfering interactions between the issuing mechanism and the lifting mechanism which would occur if the latter were to be operated automatically while the one is being operated manually. In order to prevent such a malfunction, the release lever is coupled together with the curve 300 ( FIGS. 15 to 19) so that the pressing down of the release lever is inevitably blocked when the curve 300 is not in the "manual" position.

A horizontal plate 310 ( FIG. 15) lies between curve 300 and a flange 304 of wall 184. Plate 310 has a U-shaped recess 312, as best shown in FIG. 19 with the U reversed. The recess 312 is designed to receive a round, disk-shaped projection 314 at the bottom of the curve 300 . The extension 314 is offset in relation to the center of the curve 300 and to the axis of rotation 302 of this curve; therefore, the plate 310 moves right and left as the curve rotates, as in FIG. 15 to 19 shown by the arrows. The plate 310 has a vertical flange 316 with a recess 318 ( FIG. 16) through which it is secured to the vertical wall 184 with a pin 320. The recess 318 allows the plate 310 to slide back and forth along the wall 184.

Of Issue lever 100 (F i g. 7, 15 and 17 to 19) has an arm 101 which extends through a recess 27 of the vertical wall 26 and cooperates with the vertical flange 316 on the plate 310. When the cam 300 is in any position (FIGS. 15, 17 and 18) other than the "manual" position (FIG . 19) , the flange 316 of the plate 310 comes to rest over the foot 101 of the lever 100 and prevents the lever from being depressed and moved beyond its bearing 102. Hand crank clutch As mentioned, in each of the two modes of operation, i. H. Push-button or automatic operation, the elevator, the bezel and the cycle switch are operated by the projector motor 220 ( Fig. 15) by means of the coupling shaft 124 ( Fig. 2), a hand crank coupling and the hand crank shaft 1120.

The hand crank coupling is essentially one-sided Coupling, with the help of which the hand crank 122 is used to change slides in both directions is rotatable by hand without driving the crankshaft 124, but with the drive shaft the hand crank and hand crank shaft 120 in the forward direction during either mode of operation can drive. To throttle the projector motor in the event of an inhibition in any of the cyclic mechanisms operated by the hand crankshaft 120 To prevent the hand crank clutch is disengaged when the hand crank during the power operation is stopped.

Like F i g. 20 and 21 show, the crank handle button 123 is rotatably attached to one end of a lever 330 , the other end of which is rotatably mounted on a pin 332 which forms a whole with the crank handle 122. A weak, hairpin-shaped spring 334 attached to the pin 332 engages with one end on a nose 336 on the lever 330 . The other end of the spring 334 engages a lever 340 on a nose 338. The spring 334 pushes the lever 330 slightly clockwise around the pin 332 against a lever stop 331. The lever 340 is rotatably mounted on a pin 342, which forms a whole with the hand crank, and is turned clockwise around the pin 342 by the spring 334 pressed. An arm 344 on the lever 340 engages a nose 335 on the lever 330 and thus keeps the clockwise movement of the lever 340 within limits. A pawl 346 is rotatably mounted on the lever 340 at 348 and is pulled counterclockwise about its bearing by a coil spring 350 attached to the pawl between the lever 340 and a lug 352. Another lug 354 on the pawl 346 detects a shoulder 356 on the lever 340 and thus limits the opposite clockwise movement of the latch relative to the lever 340. A ratchet wheel 360 in the form of a spiral-shaped cam is fixed to the end of the coupling shaft 124 and has a tooth 362 , which is designed to cooperate with the nose 354 on the pawl 346.

While the hand drive is in the forward direction, the hand crank 122 is also moved clockwise by moving the knob 123 clockwise, causing the levers 330 and 340 and the pawl 346 to rotate clockwise about the ratchet 360. The inside of the nose 354 slides up the incline of the ratchet disk during each revolution of the hand crank and then down over the tooth 362 so that the clutch shaft 124 is not given drive by the ratchet disk. As the nose 354 of the pawl 346 slides up the incline of the ratchet disc 360 , the pawl and the lever 340 connected to it are moved together counterclockwise against the tension of the weak spring 334 around the pin 342. The stronger coil spring 350 holds the nose 354 of the pawl with the shoulder 356 of the lever 340 in contact.

During the reverse rotation of the hand crank, counterclockwise movement of the knob 123 first moves the lever 330 counterclockwise around the pin 332 until this lever contacts a stop 337 , as shown in FIG. 23 shown. A further counterclockwise movement of the knob 123 causes the entire crank mechanism to rotate around the ratchet disk 360 in a counterclockwise direction. The nose 335 on the lever 330, which engages the arm 344 of the lever 340, moves this lever and the pawl 346 connected to it against the tension of the spring 334 counterclockwise around the pin 342. It moves the nose 354 of the pawl radially away from the center of the crank so that the nose does not catch the tooth 362 of the ratchet 360. As a result, the shaft 124 is not given any drive by the ratchet washer.

During the force drive, which is always in the forward direction of switching erfolA the ratchet wheel 360 rotates clockwise with the shaft 124. The teeth 362 of the ratchet disk normally detects the nose 354 of the pawl 346 and causes the pawl, as well as the lever 340 clockwise rotate (F i g. 20). The arm 344 on the lever 340, which engages the nose 335 of the lever 330 , drives the lever 330, the stop 331, the hand crank 322 and the hand crank shaft 120 in a clockwise direction with the shaft 124.

If a slide is to be held in the projection window for more than one cycle during automatic operation, the operator can stop the button 123 with a light hand pressure. The crank handle continues to rotate until the lever 330 contacts the stop 337 (Fig. 23). Exactly as described above in connection with the reverse drive of the hand crank, the lug 335 on the lever 330 moves the lever 340 and pawl 346 counterclockwise around the pin 342 and thereby moves the lug 354 radially away from the ratchet disc 360. As a result, the nose 354 can not grip the tooth 362 of the ratchet, and the hand crank is not given any drive by the ratchet.

If a fault occurs in the machine during power operation and the hand crank 122 cannot rotate as a result, the hand crank clutch is disengaged in the following way: The ratchet disk 360, which until the fault occurs, the nose 354 of the pawl 356 by means of the tooth 362 in a clockwise direction drives, continues to rotate and takes the nose 354 with it. When the hand crank is stopped, the ratchet 360 moves the pawl 346 clockwise against the tension of the spring 350 about its bearing 348 and moves the tab 354 tangentially and radially away from the center of the hand crank until the tooth 362 is free, as in FIG i g. 22 shown. The spring 350 then brings the nose 354 back into contact with the shoulder 356 of the lever 340. As long as the disturbance continues and the power drive continues, the sequence described above is repeated during each revolution of the ratchet disk 360 through the shaft 124. Preheating of the slides If on Slide from a relatively cool magazine is transported into the projection window and one side of the slide is exposed to the heat of the projector lamp, so it can be discarded from its normal plane and thus defocused. This discarding is prevented in the projector according to the invention by preheating the slides while they are still in the magazine.

# Air that passes over the projector lamp 12 (Fig. 6) flows through a large opening 29 ( Fig. 16) in the vertical wall 26 and is sucked into a centrifugal fan 370 attached to the right end of the motor shaft 236 is mounted. Most of the air entering the fan is drawn up through a series of slots 372 ( Fig. 1) in the top of the projector. A smaller portion of the air entering the fan is, as indicated by arrows in FIG . 25 , directed downwards and deflected by an inclined plate 274 ( FIGS. 16, 24, 25) past a resistance heater 376 and through an opening 25 in the wall 26 into a preheating channel 380.

From Fig. 7 it can be seen that the channel 380 consists of a chamber formed by the floor 234 of the projector and a support plate 73 for the magazine 60 or 70. The plate 73 is bent down on the sides to close the channel, as at 75 in FIG. 25 shown. A number of flaps 382 (F i g. 24) in the plate 73 lying on top of the channel 380 (g F i. 5) among the above-described slots 79 at bottom of the magazine 60 or 70. The from the blower 370 (F i g. 16) as directed below air is heated so at 376 (F i g. 24 and 25) and flows through the channel 380, the slots 382 and 79 (F i g. 5) and located on the magazine 60 or 70 Slides that she preheats. The electrical circuit as in Fig. 26 shows, the projector is supplied with power through a connector 390 and a switch 392 , which has four contacts 396, 398, 400 and 402. Contact 396 is the shutdown contact and is not connected to the circuit. The contact 398 is connected to the plug 390 via a line 404, the heating resistor 376 (see also FIGS. 24 and 25), and a return line 406. The motor 220 of the projector (see also FIGS. 15 and 16) is connected in parallel to the heating coil 376 via the lines 404 and 406. The coil 268 of the electromagnet 264 (see also FIGS. 12 and 16) is in series with the above-mentioned one in FIG . 26 , push-button switch shown at 408, also connected to lines 404 and 406. A pair of remote control terminals 4110 and 412 are connected in parallel with push button switch 408 and can be used in a known manner to complete the push button circuit via a remote control cord by means of a separate push button or under control of an indicator signal.

The contact 400 of the switch 392 is connected to the return line 406 via a dropout resistor 414 and the projection lamp 12 (see also FIG. 6). The contact 402 is connected directly to the lamp 12 and the line 406 via a line 416.

The switch 392 has an arcuate switch blade 394 which is adapted to sense up to three of the contacts 396, 398, 400 and 402 at the same time. When sheet 394 is in the position shown in FIG. 26 is in the position shown in solid lines, it only senses contact 396 and no power is applied to any part of the projector circuit. When the switch blade is rotated one step clockwise, it engages contacts 396 and 398, thereby energizing heating wire 376 and motor 220, and energizing the push button switch. This activates the fan 270 ( FIGS. 15 and 16) which is mounted on the motor shaft 236 as described above. When the circuit sheet 394 ( Fig. 26) is rotated one more step clockwise, it engages the contacts 396, 398 and 400 and thereby feeds not only the heating wire, motor and push button switch, but also the lamp 12 through the resistor 414. When the circuit sheet 394 clockwise one last time up to the position shown in FIG. 26 is rotated further in broken lines, it detects contacts 398, 400 and 402, supplies power to line 404 for the heating wire, motor, push button switch and projection lamp directly through line 416 by shorting resistor 414.

The parameters of the lamp 12 and resistor 414 are such that the lamp will operate at about 300 watts when energized through the resistor and at approximately 500 watts when energized by line 416. The two mentioned energy levels are chosen arbitrarily and can of course be varied according to requirements, but these currents allow the operator to select a lamp brightness that is appropriate for the density of the slides and the format of the projection screen in most practical situations.

Claims (2)

Claims: 1. Projection apparatus for slides with a lifting mechanism for lifting and lowering the slides from a magazine into a projection window and back into the magazine and a switching device coupled to the lifting mechanism for the step-by-step transport of the magazine between lowering one slide and lifting the next slide , characterized in that a clutch (254,256,258), by means of which the lifting mechanism (96, 138 to 146) and the switching device (67, 77, 162, 164, 166) can be coupled to a continuously running motor (220), and one with the driven part (256, 258) of the clutch cooperating actuating member (262) are provided, which disengages the clutch in the position of the elevator in which a slide is lifted into the projection window, and that the actuating member (262) a motor-controlled switch-on device (256, 288 to 296) is assigned, which switches on the clutch again after a selectable period of time. 2. Projection apparatus according to claim 1, characterized in that the switch-on device with an adjusting device (300, 302, 303). is provided, which has various switch-on positions assigned to the selectable time periods and a switch-off position in which the switch-on device remains in a rest position which does not cause a restart. 3. Projection apparatus according to claim 1 or 2, characterized by a manual switch (408) controlling the actuating member (262). 4. Projection apparatus according to one of claims 1 to 3, characterized in that the lifting mechanism (96, 138, 142, 144, 146) and the switching device (67, 77, 162, 164, 166) via a drive device (130, 164) are coupled to each other, which has a crankshaft (120) connected to a hand crank (122, 123) , and that the driven part (256) of the clutch with the crankshaft (120) via a unidirectional clutch (330, 340, 346, 354, 360 , 362) , which only transmits a rotation of the output in a certain direction of rotation to the crankshaft (120), but is ineffective when an external torque acts on the hand crank (123). 5. Projection apparatus according to one of Claims 1 to 4, characterized by a manually operable issuing device (100, 106) for lifting out a slide (50) located in the projection window (20) into a position in which it can be opened by hand can be removed from the projection apparatus and by locking means (310, 316) which couple the dispensing device (100) with the setting device (300, 302, 303) in such a way that it is normally blocked and only released when the automatic switch-on device (300, 302, 303) is switched off. 6. projection apparatus according to any of arrival claims 1 to 5, characterized by a switchable from the manual switch (408) electromagnet (264) for actuating the actuating member (262) formed as an anchor. 7. Projection apparatus according to one of the preceding claims, characterized in that a coupling is provided between the drive device (120, 130, 164) provided with a crank handle (122, 123) rotatable in two directions for the switching device and the lifting mechanism and the motor consists of the following parts: a) a first part (360) which can be driven in one direction by the motor (220), b) a second part (122) attached to the hand crank (123 ), c) a part (122) for transmitting the drive the third part (346) normally connecting the two first parts, d) means (330, 340) which can be actuated in any direction by manual operation of the hand crank (123) for uncoupling the third part (346) from the first (360). 8. Projection apparatus according to claim 7, characterized in that the first part consists of a ratchet disc (360) and the third part consists of an arrangement to which a lever (340), a pawl (346) and connecting parts (350) between the lever (340) and the pawl (346) belong to their normally common movement, the ratchet disc (360), normally operated by the motor (220), engaging the pawl (346), and that the pawl (346) is pivotally arranged so that when the hand crank is stopped during the motorized drive of the ratchet disk, the pawl moves relative to the lever (340) and thus disengages from the ratchet disk. 9. Projection apparatus according to one of claims 1 to 8, characterized in that between the drive devices (120, 130, 164) and the parts (67, 77) of the switching device (162, 164, 166 ) acting on the slide magazine (60, 70) , 67, 77) a normally engaged transmission coupling (180) which can be switched off by means of a manually operated member (190, 192, 194, 198) is provided. 10. Projection apparatus according to claim 9, characterized in that the hand-operated member (190, 192, 194) is coupled directly to the parts (179, 69, 67, 77) acting on the slide magazine (60, 70). 11. Projection apparatus according to claim 9 and 10, characterized in that the hand crank (122, 123) for the manually operated member (190) forms a lock which only allows disengagement of the transmission coupling (188) by means of the member (190) when the drive device (120, 130, 164) is in a predetermined phase of a work cycle. 12. Projection apparatus according to one of claims 9 to 11, characterized by an emergency release device (200) for disengaging the transmission coupling (180) at any time. 13. Projection apparatus according to any one of claims 9 to 12, characterized in that the hand-operated member consists of a switch button (190), a shaft connected to the button (192) and means (182, 175) normally the shaft (192) in hold a first axial position from which the shaft can be moved into a second axial position by actuating the button (190) by hand to disengage the transmission coupling (180). 14. Projection apparatus according to claim 13, characterized in that the hand crank is designed as a disc (122) which has a recess (125) at its edge, and that the switch button (190) covers the edge of the disc (122) with a surface , which is smaller than the recess (125), so that the switch button (190) can only be axially displaced to disengage the transmission coupling when the recess (125) and the part of the button (190 ) covers. Documents considered: German Auslegeschrift No. 1003 969; British Patent No. 2,655,075.