DE3502463C2 - - Google Patents

Description

The invention relates to a microfilm projector with a Objective, with a focusing screen, with one or more Deflecting mirrors in the beam path between the lens and the Focusing screen and with an electronic control for Drives that shift the microfilm from the Effect the lens in two mutually perpendicular directions and with at least one light-sensitive edge sensor for the position detection of the microfilm from which a Control signal for the drive control for positioning of the microfilm can be derived in a target position.

In general, a microfilm is moved against the lens with the help of a sled onto which the microfilm is placed in an adjusted position. Either the sled will be perpendicular to each other in two Directions by one drive in each brought necessary situation. Or it is with another Carriage can only be moved in one direction, while there is a transport device on the sled that is moving the microfilm in this perpendicular direction.  

In general, microfilms are to be projected that in terms of size and in number and Arrangement of the individual representations are standardized. In In this case it is sufficient to adjust the microfilm Position on the projector's sled. Out this situation can be done with the help of an appropriate designed automatic control every display selected the microfilm using a keyboard and are automatically brought into the beam path. Here it is guaranteed that the on the ground glass projected representation is in the middle position.

But it is also conceivable that a microfilm is not in shape a standardized microfilm card, but for example only as a film strip with a few Illustrations. In this case, one becomes transparent Material existing bag - often called "jacket" - used in individual strip-shaped compartments is divided. The microfilm strip is then cut into one the fan inserted. Since the microfilm compared to the Subject has a certain game, there is a first Already inaccuracy. Furthermore, the distance between adjacent images in a row be different if the subject with multiple short Filmstrip is filled. Finally the bag in turn standardized dimensions, so that the for Projection selected image in the same way as for the standardized microfilm cards in the beam path could be, but in practice are often as strong Dimensional inaccuracies exist that at automatically controlled film movement a central Figure position on the focusing screen does not result.  

A generic microfilm projector at the beginning mentioned type is known from GB-PS 15 28 579. To Positioning of the images of the microfilm are used in this known device uses separate markings, the outside of the pictures, for example in the form of Bar code lines are attached. The application of such additional markings on the microfilm required on the one hand a time and cost expenditure and reduced on the other hand the one for storing the information on the Micro film available space.

On the other hand from DE-PS 27 09 608 is another Microfilm projector known in the immediate area markings or guidelines of the pictures has between the rows or columns of the film are imprinted. To position the desired Images in the projector are in this known device on the one hand edge sensors to determine the beginning or the end of the Mark and on the other hand each Direction of displacement of the microfilm requires two photodiodes, which then emit a signal when the dark marking is right between them. In addition to the above Disadvantages are also in this known device relatively high electronic effort due to the large number of the sensors required.

The invention is therefore based on the object Microfilm projector of the type mentioned on the one hand to simplify the structure and on the other hand also for the Projection of microfilms without markers.  

According to the invention, this object is achieved in that the edge sensor (s) ( 15, 16; 18, 19 ) is or are arranged at a defined distance from the desired position of an image edge of a projected image and the drive control after a sensor ( 15, 16 ; 18, 19 ) on the appearance of the image edge causes the microfilm to be transported further by a distance which corresponds to the distance of this sensor from the desired position of the captured image edge.

The particular advantage of the invention is that additional marking or guidance in the area outside the microfilm images are not necessary because the edges of the picture itself the signal for the edge sensors deliver. So that the sensors project the light of the Do not shade the image, they are defined with a Distance to the edge of the picture.

There are several for the arrangement of the sensor Opportunities. It can either be on the focusing screen or but also be arranged on a deflecting mirror, because it all that matters is that its position is relative to the Beam path is the right one.

According to the invention, it is also conceivable that the deflecting mirror is then partially permeable and that the sensor on the Rear of the deflecting mirror or arranged behind this is. In this embodiment, there are also many relatively short line connections to one also arranged in the housing of the microfilm projector Circuit board.

It is particularly advantageous according to the invention if two Sensors are provided that detect the location of various Capture the edges of the projected image. The second Sensor can either be in the cross-direction  Feed direction effect the adjustment when it is one edge of the image running parallel to the feed direction assigned. However, the second sensor can according to the invention but also be arranged so that both Sensors assigned two mutually parallel image edges are transverse to the direction of advance of the image. It there is a simplification of the control and a Improve accuracy when the location of each of the two parallel image edges for each by a sensor is detected.

Independently of this, a further sensor can be used according to the invention an image edge running parallel to the feed direction be assigned, this sensor via the controller and the drive provided for this purpose, the figure across adjusted to the feed direction.

A further embodiment of the invention consists in that one sensor or several sensors in a lower Distance from a deflecting mirror are arranged and that the light incidence side of the sensor (s) Deflecting mirror is facing.

This ensures that external light that may enter through the focusing screen cannot influence the sensors. Rather, it is only hit by the beam path incident via the deflecting mirror.

Below is an embodiment of the invention dung described with reference to a drawing. in the individual shows

Figure 1 shows schematically the position of an image on a ground glass.

Fig. 2 also schematically shows the structure of a microfilm projector in the area between the lens and the focusing screen.

The microfilm projector has an optic 10 . The beam path emerging from this is shown in dash-dotted lines and initially strikes a first order steering mirror 11 . From this, there is a reflection on a second deflecting mirror 12 which projects the beam path or the image onto the back of a matt disk 13 . The electronic circuit of the controller is located on a printed circuit board 14 .

The micro film lying below the lens 10 and the other parts of the projector are not shown because they are known in terms of structure and function. However, the control located on the printed circuit board 14 is now additionally subject to the influence of light-sensitive sensors 15 and 16 , which can be designed, for example, as photodiodes.

In a first embodiment, the sensors 15 and 16 are arranged on the back of the focusing screen 13 . Two sensors 15 are provided which influence the lateral alignment of an image designated by reference number 17 in FIG. 1. The sensors 15 are at a certain distance from the figure 17 shown here in an already adjusted position. This is automatically taken into account by the control. The sensor 16 , viewed in the vertical direction of FIG. 17 , is also at a distance from it, which is also taken into account by the control.

As an alternative to this arrangement of the sensors 15 and 16 , an arrangement in front of the second deflecting mirror 12 is also possible, as is also shown in FIG. 2. In an arrangement corresponding to the sensors 15 , two sensors 18 are provided, the light incidence surface of which faces the deflecting mirror 12 . The same applies to a sensor 19 , which corresponds to the sensor 16 in its arrangement and function. As indicated by small arrows, light only impinges on the sensors 18 and 19 from the deflecting mirror 12 , while the rear side thereof faces the focusing screen 13 . This ensures that the sensors 18 and 19 cannot be influenced by external light that may come in from the focusing screen 13 .

The exact shifting of a microfilm or a microfilm strip located in a pocket such that the desired image appears in the central position on the focusing screen 13 occurs as follows:

The individual compartments of a bag of the type mentioned at the outset are to be filled with microfilm strips, at least some of which are relatively short film strips which are combined into a row within a compartment. In particular, this can result in different distances between adjacent images of different film strips. The bag is brought into an adjusted starting position by the automatic film feed of the microfilm projector. As already indicated, a first inaccuracy can result from the fact that the outer dimensions of the pocket do not correspond enough to the standardized dimensions. If a specific image is now selected for projection, the drives provided for the lateral movement and the movement in the vertical direction of the image are set into a corresponding movement. Starting from the state that an image 17 is located above each of the two sensors 15 and 18 , when the film is shifted, a transition from the cover to an uncovered state by an image 17 takes place with respect to the one sensor 15 and 18 , ie at this or from this point in time, the two sensors record different brightnesses, ie they detect a dark-light contact. In other words, the first sensor 15 or 18 registers a change in brightness. When the filmstrip is moved further, the condition is finally reached that the second sensor 15 or 18 is also released from the cover and detects a transition from dark to light, so that the two sensors now do not detect any different brightness. The state is thus reached that the figure 17 is between the two sensors 15 and 18 . However, since the sensors 15 and 18 are at a greater distance from one another than corresponds to the width of a figure 17 , this means that the figure 17 is still not at the same distance from the sensors 15 and 18 . This equality has yet to be established through the influence of the control. The controller knows the distance between the sensors 15 and 18 , ie that a corresponding electrical quantity is stored. The same applies to the width of a figure 17 . Based on these values, the controller can automatically determine from a reference point, i.e. the leading or lagging image edge recorded by a respective sensor, how far Figure 17 can still be shifted in the lateral direction after the image edge has been recorded until the center position is reached.

The following applies to the functioning of sensors 16 and 19 :

The control is designed so that the correct row is controlled, but that during the lateral displacement the controlled image row is in such a position that the figure 17 of this row is still at the level of sensors 16 and 15 , ie Sensors 16 and 19 still register the dark field in Figure 17 . Finally, a final height correction is then carried out in such a way that the pocket or the microfilm is displaced in the height direction to such an extent that the sensor 16 or 19 reaches the brightness range of the imaging edge. As soon as this is the case, the control system specifies an additional shift in the height direction based on corresponding stored values until the middle position is also reached in this direction.

For a better understanding of this Description 1 is in each case still an adjacent Figure 17 shown adjacent to the ground glass indicated schematically 13 on three sides, although this Figure 17 including the bag are, of course, on the carriage of the projector in Fig..

Claims (8)

1. Microfilm projector, with a lens, with a focusing screen, with one or more deflecting mirrors in the beam path between the lens and the focusing screen and with an electronic control for drives that cause a displacement of the microfilm relative to the lens in two mutually perpendicular directions as well with at least one light-sensitive edge sensor for the position detection of the microfilm, from which a control signal for the drive control for positioning the microfilm in a target position can be derived, characterized in that the edge sensor or sensors ( 15, 16; 18, 19 ) relative to the target position of a Image edge of a projected image is or are arranged at a defined distance and the drive control after response of a sensor ( 15, 16; 18, 19 ) to the appearance of the image edge causes the microfilm to be transported further by a distance which is the distance of this sensor from the target position of the captured image edge speaks. 2. Microfilm projector according to claim 1, characterized in that the one or more sensors ( 15, 16 ) are arranged on the focusing screen ( 13 ). 3. Microfilm projector according to claim 1, characterized in that the one or more sensors ( 18, 19 ) are arranged on a deflecting mirror ( 12 ) or at a short distance therefrom. 4. Microfilm projector according to claim 3, characterized in that the Deflecting mirror is partially transparent and the or Sensors arranged on the back of the deflecting mirror are. 5. Microfilm projector according to one of claims 1 to 4, characterized in that two sensors ( 15, 16; 18, 19 ) are provided which detect the position of different image edges of the projected image. 6. Microfilm projector according to claim 5, characterized in that the two sensors ( 15, 16; 18, 19 ) are assigned two mutually parallel image edges which run transversely to the direction of advance of the image. 7. Microfilm projector according to one of the preceding claims, characterized in that a sensor ( 16; 19 ) is assigned a parallel to the feed direction image edge and that this sensor ( 16; 19 ) on the control and the drive provided for this purpose the image transversely adjusted to the feed direction. 8. Microfilm projector according to one of claims 1 or 3 to 7, characterized in that the one or more sensors ( 18, 19 ) are arranged at a short distance in front of a deflecting mirror ( 12 ) and that the light incidence side of the one or more sensors ( 18, 19 ) facing the deflecting mirror ( 12 ).