DE2545499A1 - Programmed microfiche reader - with coded inputs from frame number selector to two orthogonal stepping motors - Google Patents

Abstract

The microfiche reader is fitted with a table moved in two orthogonal directions by two stepping motors to position any selected frame in the viewing setting. The operator punches out the frame number on a keyboard and the number is decoded and translated into X-Y sets of signals, with each motor operating independently. The required frame is then rapidly positioned for viewing. The system requires little training to operate and can be used to position selected frames for alteration, in special equipment. The logic system is transistorised.

Description

Microfilming device The invention relates to a reading device which an automatic input and output of a microfilm card and an automatic setting different fields of the microfilm card depending on keyed commands should enable.

Due to the enormous increase in technology and administration Accruing data and the correspondingly increased costs and difficulties, storage media and to provide storage space for the storage of this data, Has Microfilm as a means of storing DaZen has gained increasing importance since it enables the content of documents to be recorded in a very small space, so that there are considerable advantages over keeping the original documents result in terms of space requirements and weight and ease of transport. In order to be able to read the contents of the document, the microfilm copy of the document must be brought into a device that enlarges the document and on a suitable Projected screen and / or provides an enlarged copy of the microfilm image. To the Storage of a large number of documents on microfilm are two basic systems common. The recording and in particular the retrieval and reading of the documents causes certain problems with both systems, mainly because of the order of the Documents is fixed once and for all and rearrangement is difficult. at In one system, the documents are displayed one after the other in the specified order recorded on a roll of film, with the documents in a single row or several rows are arranged side by side on the film tape. This system has the advantage that it is very compact; on the other hand, a later insertion is one new document on an intermediate place in the sequence almost impossible, and therefore the system is mainly useful where documents are produced in a, final fixed order should be recorded and it is before especially for storing files of considerable size suitable, otherwise a film strip is filled with a multitude of different files would have to be, which leads to difficulties in classification and classification the filmstrip itself can come. In the other system, the microfilm detectors arranged in a right-angled matrix arrangement on sheets of paper that are used as microfilm cards (microfiche) are known, each with a group of related documents is placed on the same microfilm card. There is something about this system requires more space than the film roll system, but has the advantage that a certain changes to a file and the addition of new documents to an acute case are possible are because a specific field on a microfilm card has been removed or replaced without affecting the other fields and a new microfilm card with microfilmed documents, you can choose between previously made microfilm cards inserted. This system is therefore mainly used for applications which relatively often involves checking and changing the order of the documents require, and also to store files, each of which is only a relatively small one Number of individual documents included.

To an enlarged reproduction of a field of a microfilm card To obtain the microfilm card must be inserted into a reader that facilities for enlargement, Having focus and projection, and they must be set in a certain position relative to these facilities. In conventional devices, this setting of the microfilm card must be made by hand will; considering the enormous miniaturization of what is contained in a given field Document this is obviously a time-consuming process, which is also for the user requires a certain level of skill or practice, even if mechanical Adjustment means are provided to facilitate. For example, if a field has only one minor misalignment and displacement relative to the magnification and Projection system for generating an enlarged, observable image of the field on a screen becomes a substantial part of the content of the microfilm field do not appear on the screen.

In other words, the field must be set with great accuracy and it is desirable that a reader has means for fine adjustment the setting. If only one document at a time, that is a relatively large Amount of data is needed, then the time for introduction and adjustment of a field is not a particular problem. However, as is known, it is common in practice necessary to examine and read a large number of documents one after the other, taking it often is not necessary, each. Document to be fully examined, rather it will be often only one or two pieces of data from the successive documents are required. In such cases, the adjustment and positioning requires successive steps Fields, each of which contains a document, an excessive amount of time with conventional devices. These difficulties in the recovery of the data have hitherto been the full one Exploitation of the above mentioned advantages of storage in microfilm form significantly stood in the way.

In addition, it is often desirable to have a microfilm reader can be used as a connection device of a computer system, and that the numbers of the individual microfilm fields designated by the central processing unit and can be addressed. The creation of a corresponding body will be then very difficult if the fields are set by hand got to.

The invention therefore aims to provide an improved reading device for creating microfilm cards that allow quick and easy retrieval the data enables.

In particular, the reading device according to the invention is intended to be a control system for the automatic positioning of a microfilm card depending on a enable simple keyed in command signal. The microfilm device should also preferably automatic insertion and re-release of a microfilm card enable. In a preferred embodiment, it should be the device according to the invention allow the user to only enter the sequence number of a desired microfilm field inputs so it is not required is that for hiring to specify the required coordinates of the field, To solve this task looks the invention proposes a microfilm reader in which a command signal is keyed in can, which is converted into electrical signals that drive a setting device are supplied, which carries the microfilm card and with her depending on the the keyed in command can be moved automatically in the respective directions, to set the selected microfilm field. There is also an automatic facility for inserting the microfilm card into the device and for its output.

In particular, the device according to the invention has a stationary one Magnification and projection device, an adjustment device, which is a microfilm card carries and is movable in different positions to different fields of the microfilm card to bring into a position in which the enlargement and projection device can produce an enlarged image of the field on a viewing screen, as well as an input and output transport device that automatically transfers a microfilm card to the Adjustment device feeds in response to signals generated by switches removed from the microfilm card when it is partially inserted into the device are actuated, and also the output when a corresponding key is pressed the microfilm card causes.

The adjustment device includes a slidable frame that to rectilinear displacement is guided, and a holder that is attached to the frame whose displacement is taken along and also relative to the frame and independently displaceable therefrom along a direction perpendicular to the first direction is, so that by appropriate displacement of the frame and the holder any Field of the microfilm card in the position required for the projection of this field can be brought. In order to cause such a shift, the user needs just enter the number of the desired field using keys and a start key to operate. The keyed in indication is converted into electrical signals that the drive for the sliding frame and the holder according to the required Control shifts. Furthermore, additional facilities are provided for small Displacements of the frame and the holder regardless of the number entered to be carried out so that a fine adjustment of the field setting is possible. For the Looking at another field it is only necessary to enter the number of the new Field, whereupon the required shift, starting from the previous field, calculated and performed. Thus, the setting of a field can only be done by pressing the appropriate button. The inventive Reading device thus enables considerable time and effort to be saved Access to the stored data.

According to a preferred embodiment of the invention, the controller designed for the setting device that the number of a desired field in an arrangement of m rows and n columns decreased by "1" and then by the decimal number divided by m. The quotient and the remainder in this division represent the number of units that the microfilm card must be moved along the X-axis and the Y-axis, starting from a reference field to bring the desired field into the viewing position.

Embodiments of the invention are described below with reference to the drawings explained.

1 shows schematically an example of an arrangement of microfilm fields on a microfilm card.

Fig. 2 shows in perspective the general structure of the microfilm reader according to the invention.

Fig. 3 shows a perspective view of details of the construction of the microfilm reader of Fig. 2.

4 shows a block diagram of a control circuit for the alignment of the microfilm fields according to an embodiment of the invention.

Pig. 5 shows an example of the arrangement of the operation panel for the control circuit according to FIG. 4.

Figure 6 is a block diagram of a tag control circuit the microfilm fields for use with the control panel geR: iB ig. 5.

FIG. 7 shows a schematic circuit diagram of the circuit according to FIG. 6th

Figure 8 is a block diagram for an alignment control circuit of the microfilm fields according to another embodiment of the invention.

Fig. 9 shows the example of a control keypad for use with the control circuit according to Pig. 8th.

Fig. 10 shows a display device for the position of the microfilm fields.

11 shows a perspective illustration, partially cut open, a device for fine adjustment of the microfilm fields in connection with the control circuit according to FIG. 8.

Before the actual description of the embodiments according to Invention it should be noted that when arranging fields in shape a rectangular matrix on a microfilm card is the most convenient way of setting of a certain microfilm field consists in moving the microfilm card into a starting position or to bring the index position in which the microfilm field designated by number 1 on the microfilm card is in the observation position, and then if number 1 not the desired field is the microfilm card by a certain number of units to move in two axis directions, hereinafter referred to as the X-axis and Y-axis and parallel to the rows and columns of the matrix of microfilm fields are. Units along the X-axis or "X-Units" are each equal to length of a microfilm field and units along the Y-axis or "Y-sinuses" each equal to the width of a microfilm field. Perhaps you can see this better from Fig. 1, in which schematically a typical arrangement of fields on a microfilm card M is shown. The fields are in an arrangement of eight lines accordingly the Y-axis, labeled with the letters A through H, and ten columns accordingly the X-axis, identified by the numbers 1 to 10, with this designation the rows and columns corresponds to normal practice. The fields are continuous numbered from 1 to 80, the numbering along the successive columns, starting with the left column. If any number in this order, e.g., 18, a user would normally use the X and Y coordinates of field numbered in this way with X = 3, Y = B (i.e. 2nd line), and would have a Command to move the microfilm card by two X units and one Y unit, by pressing the keys 3 and B in the keypad 9 shown in FIG. However, as mentioned above, the reader counts down from 1 as the microfilm card is already in the starting or index position and the coordinates of a field in the viewing position X = 1, Y = A (i.e. 1st row). So if the microfilm is moved by three X units and two Y units, the box with the coordinates X = 4, Y = C (i.e. 3rd line) brought into the observation position, i.e. the field Number 27. The calculation to be carried out is very simple, since you can only use the The value of the coordinate for the two axes of the matrix must each subtract lltl; but the calculation is also tedious, as it has to be considered for each field should, must be repeated, and it is easily forgotten, with the result that the setting of a desired field is incorrect and must be repeated.

A microfilm reading device for a corresponding shift of the microfilm card is shown in FIG. It comprises a control panel 1 on which a power switch 2 is arranged, which when closing the whole microfilm reading system connects to the power supply and a light source 11 can light up. Further there is a keypad 3 on the control panel 1 to designate the number a desired Field on an ikrofilmkarte using the X- and Y-axis, further a group of buttons 4 for start, return and fine adjustment movements a microfilm card carrier, as will be explained in detail, and a display device 5, which indicates the number of the field in the viewing position. One Microfilm card on which there is a microfilm field to be viewed is provided by Hand entered into the reading device via two guide plates 7, which are horizontal arranged and bent apart to accommodate the insertion of the microfilm card facilitate. You lead the microfilm card to a field setting device, the is formed by a sliding frame 30 and a holder 8.

The sliding frame 30 is slidable on the stationary Base 6 of the microfine reader is stored and can only be positioned along a line that extends from the front to the rear of the microfilm reader and hereinafter referred to as the Y-axis. The holder 8 that holds the microfilm card holds, is taken along the axis by the sliding frame 30, can however, move freely along the frame in the direction of the X-axis, which is perpendicular to the Y-axis. By moving the holder 8 carrying the microfilm card by appropriate Stretching along the X and Y axes will focus a desired microfilm field under one Lens 12 or a lens system are brought.

This lens 12 is in a substantially central position with respect to of the frame 6 arranged, and the frame 6 comprises a flat which is slightly larger than four times the area of a microfilm card, so that each field the microfilm card can be brought under the lens 12. In the following the Position immediately below lens 12 is referred to as the viewing position. When a desired panel has been brought into the viewing position, a shutter 69 attached under the sliding frame 30 is opened, whereupon light from a light source 1i, which is operated when the switch 2 is closed and in the is arranged essentially at the same height as the diaphragm 69, on an inclined Mirror 13 can fall, which is also arranged under the frame 30. The mirror 13 throws the light from the light source 11 upwards through the respective microfilm field to lens 12, which provides a focused image of the contents of the microfilm field throws on a mirror 14. The image is from the mirror 14 on a mirror 15 and from this to an at least approximately perpendicular viewing screen 16 thrown, which is arranged in the front part of the microfilm reading device. the Elements 11 to 16 and the diaphragm 69 are all fixed in position by fastening on suitable parts of the housing (not shown) or the base of the microfilm reading device held. Of course, the screen 16 can be photocopied or other known means for creating a copy of the contents of the Microfilm field to be replaced.

The construction of the microfilm reading device and the shifting device is shown in more detail in FIG. The microfilm card closes when inserted correctly in the guide 7 two switches 82 and 89. These are at such a distance from each other arranged that it was introduced incorrectly, e.g. with the narrow side first Microfilm card cannot be closed. Closing both switches 82 and 83 causes a signal to be output to a control circuit 87 shown in FIG. 4 is shown whereupon a motor 77 starts up. The motor 77 operates via gears 78, 79 the forward drive of two rollers 75, 76, the horizontally immediately behind the guide 7, i.e. a little further inside than the guide with respect to the reader 7, are arranged. These then rotate in such a direction that the microfilm card is transported into the reading device and to the sliding frame that at this point in time immediately behind the rollers 75, 76. The rollers 75 and 76 can also be driven in the opposite direction to remove the microfilm card from the Move device out, as will be described.

After sufficient time to complete the microfilm card to move onto the sash, the control circuit 87 stops the motor 77 and thus the movement of rollers 75 and 76.

The sliding frame 30 is a rectangular member with a Central opening and has rollers 31 to 34 on the opposite short sides, two on each side. The rollers 31 to 34 run on guide rails 35 and 36, which are arranged on opposite sides of the fixed base 6. In this way, the frame 30 can be guided and shifted along the Y-axis, the movement of the frame 30 being effected by a stepper motor 59 which acts via a pull wire 85. One end of the wire 85 is via a spring or a other means of maintaining wire tension on part 30a of FIG Fixed base 6 and is initially parallel from this attachment point guided to the X-axis, runs with deflection by 900 around a roller 51 on the underside of the sliding frame 30, then runs around a friction part on a bracket 30b on the lower surface of the frame 30, runs back from there and is over rollers 52, 53, 55 and 56 out, which on the fixed base 6 at the corners of an imaginary Rectangles are arranged so that the wire 85 forms a loop parallel to the Y-axis describes. The other end of the wire 85 is attached to a bracket 30c, which is attached to the lower surface of the frame 30. In that of the rollers 52, 53, 55 and 56 defined loop section, the wire is wound around a cell 54, which can be rotated by the stepper motor 59, the sliding frame 30 is shifted along the Y-axis by a distance which is determined by the number of to the Motor 59 supplied pulses is determined. The construction of the engine 59 and the diameter of the shaft 54 are such that the motor 59 supplied to each Pulse, the frame 30 is moved 11Y units ", i.e. an equal distance the width of a microfilm field.

The holder 8 comprises a sliding frame 26, a transparent one Support plate 21 and a transparent pressure plate 84. The sliding frame 26 defines a central opening and is provided with rollers 49, 50, 27 and 28 which run on guide rails 29 and 70 parallel to the X-axis along the edges the long sides of the sliding frame 30 are arranged so that the holder 8 can be moved along the X-axis independently of the frame 30. The transparent one Support plate 21 is held horizontally and firmly in the sliding frame 26. At the opposite short sides of the support plate 21 are Abieck- and Pührungswandteile 17, 18 are provided which are parallel to the direction of movement of the microfilm card at whose input or output are arranged and the correct movement of the microfilm card to ensure during this transport. Near the rear edge of the platen 21 two stop pins 19 and 20 are provided, which are on a parallel to the Y-axis Line are arranged and as a stop for the leading edge of one in the reading device used microfilm card so that it is correctly positioned.

The transparent pressure plate 84 is on the support plate 21 or the frame 26 by means of pivot pins 24, 25 pivotable near the two rear corners stored and has outwardly protruding pins 22 at or near the front corners, 23. If the sliding frame is in an input or output position immediately behind the rollers 75 and 76 is adjusted, the pins 22 and 23 run in a fixed position wedge-shaped veile 72, 73 with sloping surfaces next to the ends of the rollers 75, 76 are arranged, whereby the pressure plate 84 in its hinges 24, 25 is pivoted upwards so that the microfilin card is unimpeded on the Support plate 21 can be pushed forward. When the sliding frame to the rear is moved out of the input / output position, as will be described below the pins 22 and 23 free from the wedge-shaped parts 72 and 73 and the pressure plate 84 can gradually move downward under her weight and onto the microfilm card Press so that it is placed flat against the platen 21.

When the sliding frame is returned to the input / output position is, the pressure plate 84 is again by the on the wedge-shaped parts 72, 73 raised pins 22 and 23 so that the microfilm card is smooth and can be withdrawn from the support plate 21 without hindrance.

The holder 8 is on the sliding frame 30 along the X-axis movable by a stepper or pulse motor 58 which acts via a wire 86. One end of the wire 86 is via a suitable spring element for Maintaining the tension on a part 6a in the left front part of the base 6 attached, as can be seen in Fig. 2 on the far left. The wire 86 follows from there rear, by 900 by a roller 37 on the sliding frame 30, by a roller 38 on the sliding frame 26, back and again by 900 around a roller 39 on the sliding one Frame 30 and then an arrangement of rollers changing its direction and height 40, 41, 42, which are arranged in the rear left corner of the base 6. The wire then runs parallel to the rear edge of the base 6 and is around the output shaft 57 of the Pulse motor 58 wound, then continues to run over a direction and height changing Arrangement of rollers 43, 44, 45 in the rear right corner of the base 6, from there to a roller 46 on the slidable frame 30, from there by 900 umgeleilift um a roller 47 on the sliding frame 26, back to the right edge of the sliding Frame 30, around 900 around a roller 48 on frame 30, and then forward to the front right part of the base 6 where the other end of the wire 86 is attached. Since the The length of the wire 86 is constant when the shaft 58 is rotated by the pulse motor 57 in one direction or the other of the sliding frame 26 and thus the support plate 21, the pressure plate 84 and the microfilm card held by them along the X-axis moved, regardless of the sliding frame 30 and regardless of the position this frame 30 along the axis. The sliding frame 26 is in each case by an "X-unit", i.e. a distance equal to the length of a microfilm field for each of the pulse motor 57 applied pulse moves. The movement of the holder 8 along the X-axis can be easy performed simultaneously with the movement of the sliding frame 30 along the Y-axis because when the frame 30 is moved, the wire 86 for the 3 movement of the Sliding frame 26 leading rollers 37, 39, 46 and 48 are always on straight lines move and thus only a change in the length of the sections of the wire 86 between these pairs of rollers and the front and rear corners of the base 6 takes place while the distances between these pairs of roles and the roles 38, 47 on the sliding frame 26 and thus the position of the holder 8 on the X-axis can only be determined by the rotational position of the shaft 57. Thus, starting out from any position of the adjustment device by moving accordingly of the holder 8 along the X-axis and the sliding frame 30 along the Y-axis by a desired amount and in the right direction any field one microfilm card held by the carrier 8 in the viewing position, i.e. below the lens 12 can be brought. This movement is caused by the one to be described Control device, which the number of steps in the amount of a field length or width defines around which the adjustment device in one direction or the other lengthways the X and Y axes, the pulses supplied to the motors 58 and 59 must be moved counts and the motors 58 and 59 according to the desired shift the adjuster stops, and which also determines when the desired field moved to the viewing position and then an electromagnet 67 turns on. The armature of the electromagnet 67 is connected to a connecting element 68 connected, which is pivotably mounted on a pin 74 and with an extension rod 68a is connected, in turn with the above-mentioned shutter 69 between the light source li and the mirror 13 is connected. When the electromagnet is excited 67, the connecting element is pivoted in such a direction that the shutter 69 is opened so that light from the light source 11 falls on the mirror 13 and reflected therefrom up through the desired microfilm field to the lens 12 and the content of the field is displayed on screen 16.

Referring to FIGS. 2 and 3, there is the following process in FIG Input and output of the microfilm card and the setting on a specific field. It is assumed for the sake of simplicity that the microfilm card has 10 x 8 fields in an arrangement with OK columns (X-axis) and 8 rows (Y-axis), from left to right in the successive lines, starting from the top one Line, numbered ind. Obviously this is an unrealistically low one Number of fields and that the fields can be numbered in other ways. It is also assumed that first Peld number 25 and then field Number 18 to be looked at. After pressing the power switch 2, the Microfilm card placed on the setting device by rollers 75 and 76, which is in the input / output position described above. Then the Number 25 keyed in on the keypad and the start key in key group 4 pressed.

The sequence of operation, namely inserting the microfilm card, Keying in the field number, pressing the start key allows the use of a relatively simple circuit, although it is of course possible suitable Provide memory and hold circuits that allow the field number, e.g. before the Insert the microfilm card. When the adjuster is in the Input / output position is located, actuates one from the underside of the slide frame 26 protruding projection a switch 65, which prevents the supply of current to the motor 58 and stop moving along the axis; similarly actuates the slidable Frame 30 a switch 63, which prevents the power supply to the motor 59 and the Movement along the Y-axis stops. The switches 63 and 65 are activated by pressing the Start button made ineffective and remain ineffective until a return button is pressed, whose mode of operation will be described later, this being achieved, for example can by sending the pulses to motors 58 or 59 through a parallel connection that in one branch has a normally closed contact of the switch 63 or 65 and usually one in the other branch open contact the start button in series with a normally closed contact of the return button having.

Pressing the start button also causes a signal to be transmitted to the control circuit 87 which in response thereto the supply of pulses to the Y-axis motor 59, but not to the X-axis Zotor 57, so that the holder 8 remains immobile relative to the displaceable frame 30 and the adjusting device only along the Y-axis away from the input / output position into an index position is moved, i.e. into the position in which field number 1 is in the viewing position located under the lens 12. During this movement, the impulses for the Y-axis motor not counted. When the adjustment device arrives in the index position actuates a lower projection on the sliding frame 30 a switch 62, whereupon a signal is fed to the control circuit 87 which, in response thereto, the pulse counting circuits for both motors 58 and 59 closes and also the pulse feed circuit for the X-axis motor 58 closes. Since the microfilm card has an arrangement of 10 x 8 fields if field number 25 must be brought into the viewing position should, the sliding frame 30 two Y-units to the rear and the carrier 8 can be moved four X units to the left in the drawing. This is because of this causes motor 58 to be supplied with two pulses and motor 59 to be supplied with four pulses and both motors 58 and 59 are actuated in the forward direction so defined will that they a movement of the holder 8 and the sliding one Frame 30 in the direction of lines or

Corresponds to columns with higher numbers. These impulses are counted and motors 58 and 59 are stopped when they have the desired number of pulses received, whereby field number 25 remains in the viewing position. the Shutter 69 is open and the content of field number 25 is on the Screen 16, as already mentioned, is shown. After considering the content of Peld Number 25, the user keys in number 18 on keypad 3, whereupon the motor 58 is actuated in the forward direction and three pulses are supplied to him during the Motor 59 is driven in the reverse direction and a pulse is supplied to it. this brings the field number 18 into the viewing position.

Of course, the fields are set in the viewing position substantially the same when the number of the motor 58 or 59 to be fed Impulses that cause a frame shift by an X-unit or a Y-unit, is a number other than one.

After pressing the return button, both motors 58 and 59 driven in reverse direction, whereby the counter of the pulses is interrupted. The holder 8 is to the right in Fig. 3 and the sliding frame 30 to moves forward, and the adjustment device as a whole moves in the direction on the index position. When the holder 8 approaches the position furthest to the right, actuates a projection on the underside of the sliding frame 26 a Switch 64, which causes a slowing down of the drive of the motor 57, so that the Holder 8 is slowed down. When the holder 8 reaches the position furthest to the right has, a projection on the underside of the frame 26 actuates a switch 65, which interrupts the supply of pulses to the motor 58 so that the movement of the Halters 8 stops. Press 30 as the sliding frame moves forward Projections on its underside one after the other switches 61, 60 and 63, which intermittently Bringing the frame 30 to a halt, slowing down or stopping completely. If the sliding Frame 30 actuates switch 61 before sliding frame 26 actuates stop switch 65 has actuated what, for example, when the adjustment device is returned from a position in which field number 18 is in the viewing position, the case would be then the supply of pulses to the Y-axis motor 59 is temporarily interrupted, so that the adjustment device is only moved along the X-axis. After closing of the switch 65 through the slide frame 26 is the supply of pulses to the Y-axis motor 59 resumed, regardless of the actuation of the switch 61, and the setting device is thus moved forward along the Y-axis when switch 60 is actuated slowed down and stopped when the switch 63 is actuated, whereupon the Sinstellvorrichtung is now in the input / output position. You can see that braking and stopping of the holder 8 and the sliding frame 30 gently because of the actuation of the brake switches 64 and 60 takes place.

The actuation of the stop switch 63 also causes a feed Signal to the control circuit 87, which in response to the drive of the rollers 75 and 76 caused by the motor 77 in the reverse direction, whereby the microfilm card is moved out through the guide 7, the switches 82 and 83 during this Movement to be closed. The microfilm card is moved outward until its The rear edge just touches the rollers 75 and 76 and the middle part of the Guide 7 is supported. Subsequent removal of the microfilm card by the user causes switches 82 and 83 to open, whereupon the motor 77 stops and the system is brought into the starting position.

For the control unit 87, which is not shown in detail, various known constructions are possible.

It must of course be able to distinguish whether the Input and output rollers 75 and 76 driven in a forward or reverse direction are to be, and further, when the start button 4a is pressed, whether a microfilm card has just been entered and the adjuster in the input / output position is whether the adjustment device has already been moved into a position, in which a microfilm field is in the viewing position. These distinctions can easily be done as follows. The forward drive of the rollers 75, 76 to Insert a microfilm card depends on the presence of one Signal from switches 82 and 83 next to guide 7 and the absence of a signal from the return button; the reverse drive may initially depend on the presence a signal from the return button and then the presence of a signal from the return stop switch 63 for stopping the sliding frame 30 and the switches 82 and 83, the drive of the rollers 75 and 76 when removing the microfilm card and stopping the signal from switches 82 and 83, as above described; the reverse drive can also be triggered by a signal from the return button and held long enough to allow the microfilm card moved back from any position in the broom to the dispensing position and can be pushed by the rollers 75 and 76 through the guide 7. The general Position of the adjuster is easily made by the switch mentioned above 63 for stopping the sliding frame 30 is determined. When the switch 63 is closed when the start button is pressed, then it is known that the Adjustment device is in the input / output position, and the sliding Frame 30 is therefore moved until the switch mentioned above is closed 62 has been effected. Once the adjuster has reached the input / output position leaves, the switch 63 is opened; this will determine if another Field on the same microfilm card should be viewed and the start button after to the Keying in a new field number is actuated again that. the adjustment device is already in a position in which a microfilm field is in the viewing position and the required movement along the X-axis and Y-axis will be carried out immediately, the pulses for motors 58 and 59 being counted.

The circuit for effecting the adjustment of the above described Fields is shown in the block diagram in FIG.

Fig. 4 shows only that part of the circuit that relates to the movement in the axis refers; Construction and operation of the circuit for the movement in the Y-axis is essentially identical with the exception that the control unit 87 the drive of the sliding carriage 30 between the input / output position and the index position controls while the input signal to the X-axis motor 58 is interrupted as described above. The motor 77 of the rollers 75 and 76 is through the control unit 87 is actuated when this control unit 87 receives an input signal from an AND gate with two inputs, which receives the input signals from switches 82 and 83 are fed. The motor 77 remains after the termination of the input signal switched on to control unit 87 for a predetermined time. The number of the first desired microfilm field is keyed in on the keypad 3, and its content is then fed to a decoder 102 and from decimal to binary coded decimal format converted while at the same time a signal that indicates that a field number has been keyed in is fed to the control unit 87, this signal to a signal from the start button 4a, which is actuated later, is added. The content of the decoder 102 is fed to an input register 88 and stored there. This supplies a corresponding output signal to a display unit 89, at which the user can check that the correct number has been keyed in and to a decoder 90 which converts the value into the corresponding values of the Converts X and Y coordinates, e.g. for field number 18 column 2 for the X axis and row 8 for the axis if the film fields are in a 10 x 3 matrix are arranged, or column 2 for the X-axis and row 3 for the Y-axis, if the fields are arranged in an 8 x 10 matrix, etc. for other matrix arrangements.

When the decoding is complete, decoder 90 completes the process the decoding indicating signal to the control unit 87, which in turn is a command signal outputs to the content of the decoder 90 related to the X-axis Specification register 91 for the X coordinate, referring to the Y-axis related data in a corresponding manner to a specification register, not shown for the Y coordinate are supplied. The contents of the X coordinate register 91 is fed to a subtraction stage 93 which also receives an input signal from a Register 92 contains the X coordinate value of the previously selected Field is stored on the respective microfilm card. When the microfilm card is in the reader is inserted, the control unit 87 sets the value 't1' in the Register 92 for the previous field. The absolute value of the in the subtraction stage 93 obtained result is fed to a comparator 94, while the sign the result of a forward-reverse control stage 99 is fed to the motor 58 switches to reverse drive if the sign is minus, and to forward drive, when the sign is plus. The comparator 94 compares the input signal from the subtraction stage 93 with an input signal from a pulse counter 95.

Pulses for driving the X-axis motor 58 become continuous generated by a pulse generator 96 after actuation of the start button 4a and via a speed control stage 97, a gate 98 and the forward-reverse control stage 99 to a drive stage 100 which drives the motor 58.

The pulses from gate 98 are external to the drive control unit 99 is also fed to the pulse counter 95.

If the input signals from the pulse counter 95 and the Subtraction stage 93, the comparator 94 outputs a signal in order to close the gate 98 and stop the motor 58. At the same time, the comparator 94 inputs this agreement indicating Signal to control unit 87. This signal is maintained until input another field number through the keypad 3. Upon receipt of a corresponding The control unit gives signals from the comparator for the movement in the Y-axis 87 an actuation signal to the shutter control stage 103, which excites the electromagnet 67 and thus the opening of the shutter 69 causes.

For example, if the value of the X coordinate of the previously selected field Was "2" and that of the now desired field was "8", then that is in the subtraction stage 93 result obtained "+6. In this Pall, the drive control circuit 99 effects a forward drive of the motor 58, which moves the holder 8 to the left in Fig. 3, until the counting result fed from the pulse counter 95 to the comparator 94 has the value "6!" reached, whereupon gate 98 is closed; the shutter 69 is opened, when the sliding carriage 30 reaches the desired Y coordinate.

The speed control stage 97 receives an input signal from Comparator 94 and the control unit 87. The control unit 87 causes a reduction the drive speed during start-up of the motor 58, i.e. immediately after pressing the start button 41 to difficulties with the drive torque to avoid. The comparator 94 supplies a signal to reduce the speed, when the difference between the values of the input signals from the pulse counter 95 and the subtraction level 95 is lower than a certain value to be excessive sudden stop of the holder 8 or its movement beyond the target avoid.

It is expected, however, that continued use of the reading device almost inevitable over a long period of time with a certain change in voltage of wires 85 and 86 that hold the sliding frame 30 and holder 8 along the X and Y axes. This leads to the fact that even if the pulses are correctly supplied to the motors 58 and 59, the desired ones Fields are not always brought exactly into the viewing position. If a desired Field is slightly shifted from the viewing position, so that some of the content this field is not projected on the screen 16, fine adjustment can be made the position of the field is carried out by pressing a corresponding key 4c will. There are four such buttons provided, as can be seen from Fig. 5, in the an example of the design of the control panel is shown, the buttons 4c are provided with arrows, each indicating the direction in which the adjustment device is moved while the respective key is pressed. For example, if the left If part of a field does not appear on the screen 16, the lower right button will be 4c pressed in the drawing. Signals from the Control unit 87 supplied, which then sends out signals that are in the speed control stage 97 cause an increase in the duration of the output pulses, gate 98 open and cause the direction control stage 99 to operate in the forward direction, whereby the holder 8 slowly forwards, i.e.

is moved to the right in FIG. During this process will be the pulses from counter 95 are not counted. If the desired field is completely open the screen 16 is visible, the button 4c is released, whereby the input signal to the motor 58 is ended and the holder 8 is stopped. The opposite movement of the holder J or a forward or backward movement of the sliding carriage 30 can take place in a corresponding manner by pressing the associated key 4c. After looking at a field on the icrofilm card, the number of another becomes Field is keyed in, and then pressing the start button 4a causes the delivery of signals from the control unit 87 that initially require a reset or cancellation of all circuits and then setting the content of the field address register 91 in the register 92 of the previous field. Then the Conversion of the content of the keypad 3 by the decimal BCD converter 102 and the further processes as described above. When you press the return button 4b all registers are cleared and pulses are sent to the X-axis motor without being counted 58 and the Y-axis motor 59 depending on the closing of those described above counter 60, 61, 62, 63 fed, and working the whole Switching is terminated when the switches 82 and 83 are opened when the Microfilm card from the reader.

As can be seen from FIG. 5, there is a preferred exemplary embodiment for the keypad 3 for the reader described from a simple rectangular Arrangement of keys, which are designated with the decimal digits O to 9 and also comprise a delete key 3c. In this arrangement, the number of the desired Field first the digit with the higher priority and then the digit with the keyed lower priority; if e.g. the number of the desired field is 27 the user presses key # 2 and then key # 7 this type of designation or addressing is applied to the arrangement of the keypad 9 of the fields made possible by the control circuit shown in the block diagram in Fig. 6, which will now be described. The keypad content, which is a decimal number 3a is converted to binary-coded decimal format by a decimal ECD converter 202. Its output signal is set in an input register 203. The content of the input register 203 is fed to a display unit 204 at which the user can check whether the correct number has been keyed in, and is also used as an input signal to a comparator 205 throughout the field positioning process fed. The comparator 205 receives also an input signal from a pulse counter 206; as long as there is no match between the input signal from the counter 206 and from the register 203, the comparator 205 delivers Signal to an AND gate 207 with three inputs. This also receives an input signal in the form of control signals 212 from a start switch, not shown, and clock pulses 213. Its output signal is input to counter 206 and also a first subtraction stage 208 subtracting the value "1" Counter 209 and a second counter 210 supplied. The AND gate 207 can thus Clock pulses 213 only pass if control signals 212 and a signal from comparator 205 is present. In other words, leaves the UI gate 207 after actuation of the start switch, not shown, the clock pulses 213 for so long until the number of pulses 213 allowed to pass is equal to that in register 203 stored number is. The subtraction stage 208, which attracts the value tut1 ", prevents that the first clock pulse passed by gate 207 is fed to counters 209 and 210 but allows the following clock pulses to reach these counters. The first Counter 209 can count up to the decimal number 7 and is activated when every eighth pulse is received cleared and then gives a signal of the value "1" to the second counter 210. If so for example, a total of ten pulses are fed to the first counter 209, then After this entry has been completed, the first counter 209 contains the decimal value 2tt and the second counter 210 has the value 't1lt.

If those coming from register 203 and counter 206 match On the one hand, the comparator 205 causes the input signals to the comparator 205 to close of the gate 207, in that it does not give any further impulses to this, and the delivery a signal to the control unit 87 to indicate this correspondence, whereupon the control unit 87 feeds the contents of the first counter 209 and the second Counter 210 causes drive units, each with a servo amplifier 100 and supply them with an input voltage proportional to the The content of the first counter 209 or the content of the second counter 210; through this becomes a microfilm card by the required number of X units and Y units driven out of the index position to bring the desired field into the viewing position bring to. Of course, this can also be achieved when the holder 8 and the displaceable carriage 30 are driven by means other than those shown in FIG will. For example, the holder 8 and the carriage 30 can be driven by pulse motors are driven, in which case the output signals from the first counter 209 and converted by the second counter 210 into the required number of pulses and fed to these motors.

For example, assuming that the desired field is the Number 18, the keys 1 and 8 are pressed in the keypad 3a, whereby the value "18" in the input register 203 stored in the Display unit 204 is shown and constantly fed to the comparator 205. Then the start button is pressed, which initially causes the deletion of all circuits and then the application of the signals 212 to gate 207. Since at this point the Input signal from counter 206 to comparator 205 has the value "O", the comparator supplies 205 also an input signal to gate 207, which thus a clock pulse 213 to the counter 206 and via the subtraction stage 208 to the counters 209 and 210 lets through. This clock pulse 213 is counted by the counter 206, its content thus Becomes "1"; however, the subtraction stage 208 prevents this clock pulse from the first counter 209 reached; the first counter 209 and the second counter 210 have thus both have the content "O". The next clock pulse 213 increases the content of the counter 206 by "1" and runs through the subtraction stage 208 to the first counter 209. Thus the counter 206 has the content 2, the first counter 209 the content "1" and the second Counter 210 has the content "0", and the comparator 205 continues to deliver a signal to Gate 207, since the input of the value "2" from counter 206 is not the same as the input is of the value "18" from register 203. The total number of clock pulses 213 that the first counter 209 is supplied to is "1" less than the total number that the Counter 206 is supplied, since only the clock pulses 213 following the first Run through subtraction stage 208 and all of them are fed to the first counter 209. Thus brings the eighteenth clock pulse passed by gate 207 the contents of the counter 206 to 18 "and the total number of the first counter 209 supplied clock pulses to "17".

Since the comparator 205 is now from both the register 203 and the counter 206 receives the value "18", it stops the supply of signals to gate 207, which therefore does not let any further clock pulses through. Because the first counter 209 in total seventeen pulses have been supplied, and since this first counter 209 upon reception of the eighth clock pulse is deleted and the content of the second counter 210 is increased by 1 " has been, the content of the first counter 209 is now t and that of the second Counter 210 is 2. If the contents of the first counter 209 and the second Counter 210 is fed to the above-mentioned drive units, the microfilm card becomes moved out of the index position by one Y-unit and two X-units, whereby, As can be seen from Fig. 1, the field number 18, i.e. the desired field, in the Viewing position is brought. Since the user is thus able to directly enter the number of each Field can be keyed in without having to do any calculation the invention saved time and avoided mistakes.

The circuit for causing the above-described operations is detailed shown in detail in FIG. The parts of the circuit in Fig. 7 that make up the blocks of Fig. 6 correspond, are framed with dashed lines and denoted by the same reference numerals. The input register 203 consists of a shift register with parallel input and parallel output with two flip-flops 224 and 225 of four bits each, each of which has outputs a, b, c, d. Input signals can be supplied from the field selection keys 3 via inputs 217A to 217D. The first in The digit selected on the keypad 3a is fed to the flip-flop 224 upon occurrence the control edge, in this circuit the positive edge, of a signal, which when pressing the start key or another key in the keypad 3a is produced. When the negative edge of signal 216 arrives, the content of the Flip-flops 224 pushed into flip-flop 225, and the value of the next key 3a, if one has been pressed, a setting is made in the flip-flop 224. After that will be the states of the flip-flops 224 and 225 are maintained until a reset signal 221 arrives, and the output signals from the outputs 224a to 224d and 225a to 225d become the display windows 222 and 223 of the display unit 204 as well as further fed to the comparator 205. The window is located in the display unit 204 223, which indicates the content of the flip-flop 225, i.e. the tens digit of the desired Field number, if it has two digits, to the left of the window as seen by the viewer 222. If the required field number is less than ten, only one digit of of the display unit 204, namely in the window 223. Of course the input register 203, that in the illustrated embodiment can only store values up to the decimal number 99, easily by adding a another 4-bit flip-flops can be expanded so that it can store decimal numbers up to 999 can.

The comparator 205 consists of exclusive-OR gates 226-233 each with two inputs, and all of their outputs are as inputs to a OR gate 254 connected.

Each of the exclusive OR gates produces an output signal when a Input signal is present at one of its inputs, but not both. The OR gate 234 produces an output when there is an input from any of the Exclusive OR gates 226 to 233.

The counter 206, which is also an input signal for the comparator 205 outputs is a binary coded decimal register with two counters 235 and 236, each of which can store four bits and has outputs A to D. Clock pulses are supplied to the counter 235 from the gate 207, and the counter 235 is cleared and the counter 236 increased by 1 each time every tenth clock pulse arrives at Counter 235.

If a two-digit field number is selected using keys 5, the exclusive OR gates 226 to 229 are assigned to the ones digit of the selected number and receive an input from flip-flop 224 and counter 235; the Exclusive-OR gate 230 to 233 are assigned to the tens of the dialed number and received receives an input from flip-flop 225 and counter 236. More specifically, receives an input of the exclusive OR gate 226 a signal from the output 224a of the flip-flop 224, while its other input receives a signal from the output 235A of the counter 235. Similarly, gates 227, 228 and 229 each receive a signal from the outputs 224b, 224c and 224d of the flip-flop 224 and a signal from the outputs 23 so, 235C and 235D of counter 235. Gates 230, 231, 232 and 233 receive one, respectively Signal from the output 225a, 225b, 225c and 225d of the flip-flop 225 and respectively a signal from output 236A, 236B, 2360 or 236D of counter 236. If incomplete Correspondence of the content of the flip-flop 224 with that of the counter 235 and the content of flip-flop 225 with that of counter 236, thus generates at least one the exclusive OR gates 226 to 233, and thus also generates an output signal the OR gate 234 has an output signal which is supplied to the gate 207 and in the presence of signal 212, the passage of signals 213 through the gate 207 allowed. Since the signals 212 are generated after a start key is pressed, the passage of the clock pulses 213 through the gate 207 depends on the Gate 207 receives a signal from OR gate 234. If the contents match of flip-flop 224 and counter 235 and of flip-flop 225 and counter 236, respectively there are none of the gates 226 bis 233 an output signal, thus hears also the output from gate 234 and gate 207 is closed.

The output signal from gate 207 is fed to counter 235, as described above, and also via the subtraction stage 208, which subtracts the value '11 ", which still is supplied to the counters 209 and 210. The counter 209 is a 3-bit counter with corresponding outputs 214, and can count up to the decimal number 7. The counter 210 is a 4-bit counter with outputs 215 and can at least up to a decimal number 10 count. As already mentioned, every eighth pulse arrives at the meter 209 this is deleted and the content of the counter 210 is increased by "1". While closing of gate 207 causes a signal to be output from OR gate 234 via line 218 is supplied, the supply of the contents of the counter 209 and the counter 210 to the Drive units with associated servo amplifiers 100, whereby the motors 59 and 58 are actuated to the carriage 30 and the holder 8 lzm the desired amounts to move (Fig. 2 and 4). A signal indicating the transfer of the contents of the counter 209 and 210 to the drive units can be generated, for example be that on the line 218 an inverter is arranged, which has an output signal generated only when receiving no input from OR gate 234.

The subtraction stage 208 consists of an AND gate 237, AND gate 238 and a trigger flip-flop 239. AND gate 237 has two inputs 237a and 237b and receives clock pulses 213 as an input signal, which are sent via gate 207 to the input 237b, as well as an output signal from the trigger slip-flop 239, which is fed to the input 237a. The output from AND gate 237 becomes the first counter 209 supplied. The AND gate 30at also has two inputs 238a and 238b and receives the clock pulses 213 as input signals, which are transmitted via the gate 207 are fed to input 238b, as well as the reset output from the trigger-flip-flop 239, which is fed to the input 238a. The output from AND gate 238 forms the trigger input for the xrigger flip-flop 239, that of the negative going Edge of this input signal is triggered. At the start of this circuit the trigger flip-flop 239 is reset by a signal 221, which at initial Actuation e.g.

one of. Keys 3a is generated and also all other memory elements in the control circuit clears. The signal 221 can of course also through Pressing a separate delete key can be generated. Because in the subtraction stage 208 the grigger flip-flop 239 is in its reset or basic state, when the first clock pulse 213 from gate 207 is passed, the AND gate has 237 no signal at its input 237a and thus does not generate an output signal, despite the supply of a clock pulse to its input 237b. At the entrance 238b of the AND gate 238, however, is a signal, so that this gate at Arrival of the clock pulse at the input 238a generates an output signal which the Plip-flop 239 triggers. The basic state output of the flip-flop 239 thus opens "0" and the working status output to "1", so that an input signal is sent to the input 237a of the AND gate 237 is fed, which thereby in the readiness for Passing subsequently applied clock pulses 213 is offset, and on the other hand the input signal from the input 238b of the AND gate 238 is removed, which is thereby closed, with the result that no trigger signal is sent to the flip-flop 239 is fed. The trigger flip-flop 239 thus remains in its working state and the AND gate 238 cannot be opened again until the trigger flip-flop 239 is reset by a signal 221 and at this point the AND gate 237 is closed again. Thus, the clock pulses 213 that are on the first Follow clock pulse, fed to the counters 209 and 210 and counted by them. There the trigger flip-flop 239 by the negative edge of the output signal from the AND gate 238 has been triggered, the first clock pulse 213 cannot use the AND gate 237 run through.

Looking back at the example above, in which the number of the desired microfilm field 18, the circuit described works as follows. By pressing the Key 1 in the keypad 3a is obtained ! i1! t on line 217A and "O" on lines 217B, 217C and 217D. These values go to inputs 224A to 224D of flip-flop 224.

Pressing key 8 gives "1" on line 217D and "Q" on lines 217A, 217B and 217C. These values go to the flip-flop 224, and the previously stored content of the flip-flop 224 is put into the flip-flop 225 transferred, these operations with the occurrence of the positive and negative edges of the signal 216 go hand in hand. The flip-flop 224 now has the outputs 224a, 224b and 224c the value "O" and at the output 224d the value 't1 ", while the outputs 225b, 225c, 225d of the flip-flop 225 have the value "O" and the output 225a have the value "1". The contents of all other registers or counters in the circuit are all "O" due to the cancellation caused by the reset signal 221. The value "18" becomes is displayed by the display unit 204, and an input signal is taken from the output 224d of the flip-flop 224 an input of the exclusive CDER gate 229 and from the output of the flip-flop 225 is supplied to an input of the exclusive-OR gate 230. There no further input signals fed to the exclusive OR gates 226 to 233 are present are, gates 229 and 230 produce an output which is sent to the OR gate 234 is supplied so that it generates an output signal which the gate 207 allows clock pulses 213 after actuation of one of the signals 220 generating To let through the start switch.

The first clock pulse 219 is fed to the counter 235, the output of which 235A thus generates the value ni ", but it is due to the subtraction stage 208 is not supplied to the counter 209, the content of which thus remains "0", so that hence the other outputs of counter 235 and all outputs of counter 236 11011 and the content of the counter 210 is also "O". Subsequent clock pulses 219 are fed to the counter 209 and increase its content and also increase the contents of counter 235. Exclusive-OR gates 229 and 230 continue to generate an output that will hold gate 207 open until the arrival of the eighth Clock pulse 219. The eighth incoming clock pulse 219 brings the value at the output 235D of the counter 235 to "1", so that the input signal at both inputs of the Exclusive-OR gate 229 has the value '1i "and the gate 229 thus temporarily stops, generate an output signal. Exclusive OR gate 230, however, continues to generate an output signal, since there is only a signal from output 225a at one of its inputs of blip-flop 225 receives. This state continues until the tenth arrives Clock pulse 219, whereupon the counter 235 is reset to ttott, whereby the Output signal from the exclusive OR gate 229 is continued, and the output 236A of counter 236 produces "1" which is the output of the exclusive OR gate 230 is terminated. Since a total of nine pulses have been fed to the counter 209, the content of the counter 209 is now i (output A = 1, B = 0, C = 0), and the The content of counter 210 is also “1 (output h = 1, B = O, C = O). The exclusive OR gate 229 continues to generate an output signal until the value at output 235D of the Counter 235 11 11? and corresponds to that of the output 224d of the flip-2lop 224, i.e. until the eighteenth clock pulse arrives at counter 235, this clock pulse is the seventeenth pulse applied to counter 209.

The input to OR gate 234 now stops, causing the gate 207 is closed and counters 209 and 210 hold the values "1" and "2" (i.e. 209A = 1, B = 0 and 210k = O, B = 1, C = O). The arrival of the from OR gate 254 The signal supplied on the line 218 causes the contents of the counters to be supplied 209 and 210 to the power inputs of the servo amplifier 100, and the setting device is moved out of the index position by two 1-units and one Y-unit, whereby field number 18 is brought into the viewing position.

According to another embodiment of the invention, instead of one step-by-step positioning of the setting device this by an analog control device take place as shown in FIG. This is a certain field characterized by the combination of a letter from a group of letters on a row of keys 104 with a number from a group of numbers on a row of keys 105, these keys having an arrangement accordingly Fig. 9 have can. The row of keys 104 corresponds to the X coordinate and the row of keys 105 the Y coordinate. Pressing certain keys in rows 104 and 105 causes the supply of input voltages with a selected voltage level to servo amplifiers 110 and 111. The servo amplifiers 110 and 111 provide drive voltages for the X-axis motor 58 and the Y-axis motor 59, which in turn drive shafts for drive the slides of potentiometers 112 and 113, at which bending voltages are applied, which are rack-coupled to servo amplifiers 110 and 11 via potentiometers 112 and 113 are. These thus drive the motors 58 and 59 until there is input and feedback voltage are in equilibrium, i.e. until the adjustment device is in the correct position, that brings the selected field into the viewing position. If this is the case, signals indicating the balance are sent to a control unit 109, which then causes the shutter 69 to open.

As indicated in Fig. 10, the display of the number of the moment in the viewing position can be caused by a Arm 117 is attached to the holder 8 at one end and a small one at the other end Lamp 116 carries under a transparent plate 115 made of plastic or other suitable material is moved over which a suitable enlarging device is located and which is divided into a number of rectangles, which are equal to the number of fields on the microfilm card and a corresponding one Wear numbering. As the adjuster moves, the lamp 116 becomes moved with and brought into a position in which they put the number on the plate 115 lights up, which is equal to the number of the microfilm field in view is.

To fine-tune the position of a microfilm field to be able to, a small lever 114 can be provided according to FIG. 11, which via the Control panel 1 protrudes and can be operated by the user, and after extends below through slots in semicircular brackets 120 and 121, the below the control panel 1 are arranged and are crosswise at right angles to each other. The bracket 120 is rotatable with one end on a fixed wall and with the other End firmly connected to a button 118. The bracket 121 is mounted accordingly and connected to a button 119. Because of the slots in the two brackets 120 and 121, the lever 114 can be freely moved, thereby causing a pivoting movement one or both brackets 120 and 121 and thus a rotation of one or both buttons 118 and 119. Buttons 118 and 119 control the slides of potentiometers 107 and 108 (see FIG. 8), to which suitable additional voltage sources are assigned, the the servo amplifiers 110 and 111 via the potentiometers 107 and 108 with voltage apply. if the lever 114 is perpendicular, get the Servo amplifiers 110 and 111 do not have any additional voltage, and the adjustment device moves not yourself. However, if the lever 114 is moved out of the perpendicular, will the slide of the potentiometer 107 and / or 108 by moving the button 118 and / or 119 moved, causing an imbalance in the servo amplifier 110 and / or 111 is generated, causing a corresponding movement of the adjustment device longitudinally the X-axis and / or the Y-axis.

The advantages of the invention should be based on the foregoing description be clear. In the device according to the invention, a microfilm card is entered automatically and their fields can be changed quickly and easily one after the other by simply One-touch can be set. It verde found that with the device according to the invention less than two seconds are required after entering the microfilm card, to place the microfilm card in any field on any other Reset field. This represents a significant improvement in terms of time required for information acquisition with conventional devices. Of the User can thus also many consecutive documents quickly and with minimal Stop fatigue.

Modifications and refinements of the embodiments described are possible within the scope of the invention.

Claims (17)

Patent claims ö Reader for microfilm cards with a large number of in rectangular matrix arrangement of arranged microfilm fields, with a holder for the microfilm card, which is parallel to the in two mutually perpendicular directions Edges of the microfilm card is movable to fit individual fields of the microfilm card a viewing position under a magnifying and projecting device to bring an enlarged image of the microfilm field on a viewing screen generated, thereby noting that a dialing device for dialing of individual fields of the microfilm card identifying data is provided and that the hold he for the microfilm card an adjusting device with drive means for movement in the two axes, which depends on the selection device is controllable and shifts by specific shift units or causes multiple of it. 2. Reader according to claim 1, characterized in that g e k e n n -z e i c h n e t that the setting device is only one on a stationary part of the reader having displaceable frame along the first axis, and that the holder on the sliding frame is arranged and guided that it is together with the sliding frame along the first Axis moved and relative can be moved to the frame and independently of this along the second axis, wherein independently operable drive means for the frame and the holder are provided. 3. Reader according to claim 2, characterized in that g e k e n n -z e i c h n e t that the independently operable drives for the frame and the Holder each from a motor and its drive on the frame or the Holder transmitting transmission exist. 4. Reading device according to claim 3, characterized in that g e k e n n -z e i c h n e t that each of the two motors is a pulse motor or stepper motor that is used for a control signal can be fed to each setting process, which is composed of a certain number consists of pulses proportional to the one set on the dial Is worth. 5. Reading device according to claim 3, characterized in that g e k e n n -z e i c h n e t that the two motors are servomotors and that each motor is a servo amplifier is assigned to a control signal with a voltage level for each setting process can be supplied, which is proportional to a value set on the dialing device is. 6. Reader according to claim 2, characterized in that g e k e n n -z e i c h n e t that it has a control device consisting of a first control part for consists of the sliding carriage and a second control part for the holder, each control part comprising: a first register for storage a value that was selected for the previous setting process Characteristic of the field is a measuring device for measuring the displacement of the frame or holder along its axis and storing one for the total amount of Shift characterizing value, a second register for storing a for the newly selected field on the dialing device, a subtraction level to determine the absolute value and sign of the difference between the contents of the first Register and the second register, a direction control stage that controls the shift direction of the frame or holder depending on the sign of the difference, and a comparator which has an input signal from the measuring device and an input signal receives from the absolute value of the difference obtained in the subtraction stage and at If the input signals match, the actuation of the associated drive is terminated. 7. Reader according to claim 1, characterized in that g e k e n n -z e i c h n e t that the control device for the drives has an additional fine adjustment device has, with the the drives independent of the one on the dialing device set value can be actuated for the purpose of fine adjustment. 8. Reading device according to claim 6, characterized in that g e k e n n -z e i c h n e t that the control device has a speed control stage for each of the two Has drives, each speed control stage the speed of the associated drive both at the beginning of its actuation and towards the end, if the difference delivered by the subtraction stage below a predetermined value has fallen, belittles. 9. Reading device according to claim 3, characterized in that g e k e n n -z e i c h n e t that the drive transmission for the sliding frame (30) is one of the associated Motor driven shaft (54), rollers (52, 53, 55, 56) and a first wire (85), which has both ends on the sliding Frame (30) is attached and passed around the rollers and looped around the shaft (54) is, and that the drive transmission for the holder (8) from one of the associated Motor-driven shaft (57), rollers mounted on the sliding frame and a second wire (86), one end of which is on a first side of the housing of the device is attached and from there via a roller (37) on this side adjacent side of the frame (30), a roller (38) on the adjacent page of the holder (8), another roller (39) on the same side of the frame (50), several Rollers (40, 41, 42) at a first corner of the housing and from there along one to the first side vertical side of the housing is looped around the shaft (57) is and via rollers (43, 44, 45) at a second corner of the housing, a roller (46) on the side of the frame (30) opposite the first side, a roller (47) on the corresponding side of the holder (8), another roller (48) on this Side of the frame (30) is guided and the other end on one of the side opposite Attachment point is attached to the housing. 10. Reader according to claim 1, g e k e n n z e i c h -n e t through an input and output device for automatically inserting and executing a Microfilm card. 11. Reader according to claim 10, characterized in that g e k e n n -z e i c h n e t that the input and output device comprises the following components: A Guide (7) for inserting the microfilm card into the device, from the one in the guide switches (82, 83) located on the microfilm card, by the setting device the holder actuable switches, rollers (75, 76) for transporting a Kikrofilkarte into or out of the reader and a drive device for the rollers, which is controlled by the switches and independent of the main control device the device is working, around the rollers in the forward or reverse direction to drive and to adjust the adjustment device for the holder (8) between one of the Rolls adjacent input / output position and a reference position from which a desired field of the card can be adjusted into the viewing position. 12. Reading device according to claim 1, characterized in that g e k e n n -z e i c h n e t that the viewing device for the microfilm card consists of a viewing screen consists. 13. Reader according to claim 1, characterized in that g e k e n n -z e i c h n e The viewing device includes means for copying the image. 14. Reader according to claim 1, characterized in that g e k e n n -z e i c h n e t that the control device for the movement of the holder in two mutually perpendicular, has the following devices in directions parallel to the edges of the microfilm card: An externally operable dialing device (3) for setting the number of a desired one Field on the microfilm card, a first register (88) for storing the selected Number, a pulse generator (96), a gate (98) for passing or blocking of the generated pulses, a pulse counter (95), the passed by the gate (98) Impulse counts and the count result in the same format like the one in first register (88) stores a comparator (94) which stores the Compare the contents of the first register (88) and the contents of the count of the pulse counter (95) and if the two values are equal, the gate (98) blocks, and a conversion device (99), which converts the pulses allowed through by gate (98) into an indication of the required Converts displacement of the adjustment device along the first or second axis, which are necessary for setting the selected field in the viewing position, and the converted values of the first and second drive means (58, 59) feeds. 15. Reading device according to claim 14, characterized in that g e -k e n n z e i c h n e t that the conversion device (99) has a subtraction stage (208), which subtracts one from the total number of pulses supplied to the converter, and further a division stage having a first counter (209) and a second counter (210), which is the total number thus reduced by the number of rows in the matrix arrangement of the fields on the microfilm card are divided, the quotient of the division in the second counter (210) and the remainder are stored in the first counter (209) and a measure of the required displacement of the microfilm card from the index position along the first and second axes. 16. Reader according to claim 14, characterized in that g e k e n n -z e i c h n e t that the comparator (94) has a number of exclusive-OR gates (226-233) each of which has an input signal representing part of the content of the first Register (91) and an input signal corresponding to a corresponding part the content of the pulse counter (95), receives, and an OR gate (234) which receives input signals from all exclusive OR gates and an output signal the gate (98) supplies. 17. Reader according to claim 14, characterized in that g e k e n n -z e i c h n e t that the subtraction stage (208) has a triggerable blip-flop circuit (239) which can be reset by an externally supplied signal and a trigger input, an output for the basic state and an output for the Having working state, and also a first UED gate (237) with two inputs, at one input the pulses passed by the gate (207) and at the other Input receives the output pulses from the working state output of the flip-flop (239), and the output signals of which can be fed to the division stage (209, 210), as well as a second AND gate (238) with two inputs, which is connected to one input from the gate (207) let through clock pulses and at the other input the signal from the ground to the status output of the flip-flop (239) receives, and its output signal as a trigger signal can be fed to the input of the flip-flop element (239). Blank page