DE1187638B - Control device for controlling the individual units of a printing machine for making prints from changing printing forms - Google Patents

Description

Control device for controlling the individual units of a printing machine for producing impressions from alternating printing forms. The invention relates to a control device for controlling the individual units of a printing press for making impressions from alternating printing forms in several lines carry arranged key characters that respond to the key characters Signal transmitters can be read, with which the control of a particular individual unit effecting controls are coupled.

A control device of this type is a photographic one Registration device has become known, which information of a recording medium, z. B. a punch card under control of sensing elements for the records registered on a photographic tab. With this well-known The encrypted information on the punch card should be entered into the device in plain text eighty different lines of characters of the registration strip can be transmitted. to for this purpose the device has a support consisting of a rotatable disc for the plain text characters, which has as many radially arranged columns as different ones Characters are to be printed. Each column has the number of lines to be printed eighty different line positions, each with the same plain text characters stands. Each column and the multiple characters contained therein are included assigned a combination mark that corresponds to the combination marks on the Punch card corresponds.

Are those contained in the combination markings on a punch card Information scanned, they are assigned to the relevant line alone Comparator entered. So there are also eighty comparators. Each of these Comparator acts as a control element for a single unit assigned to it the printing machine in the form of an arc, which the plain text carrier in the associated Shine through the line position and thus a plain text mark on the registration strip can register. The registration process is triggered when the comparator determines that the combination marking scanned on the punch card with the combination marking of the one just passed the arc arrangement Column matches.

In the device described above, come the eighty Control elements and individual units (comparator and arc) supplied signals from eighty different places. Each individual unit is therefore a very specific one Marking position on the recording medium controlling the registration process assigned. So far, other control devices have also worked according to this principle for printing machines of this type, in which different types of individual units under Control brought to response by identification marks on a recording medium should be. For example, there is a table printing machine that has several different sensors each have a specific marking point on the machine monitoring the controlling recording medium and upon detection of a marking operate a specific control magnet. With a tape controlled, Registering business machine are the photoelectrically scanned dot marks also assigned to each specific relay, the specific working aggregates of the business machine steer.

The present invention is based on the object of a control device to control the individual units of a printing machine, in which the number of the controllable individual units is increased beyond the number of character lines.

In order to achieve this, a control device is of the type mentioned at the beginning Kind of the invention so designed that at least two of the from the key markings of the printing forms excited signal transmitter with the electric Control element are combined into a logic circuit. Preferably an additional signal generator is provided, which when reading a key symbol responds in any of the lines in addition to the signaling device assigned to the line, whereby all of the signals emitted by the signal generators are approximately equal to each other in amplitude same and the control elements take effect when they each two signals that are added together can be entered. The arrangement of the additional signal generator enables a control element to be used both when scanning markings in different, lines associated with the control as well as when scanning a selection only can address in a line assigned to the control element. The additional signal generator ensures that the control element also receives two signals that are added together, when only one line is scanned.

The arrangement of an additional signal transmitter is the same for machines The type in question has hitherto only been known for the purpose of determining the location of a Position signal indicating the key character field for locking the scanning device admit. An additional signal transmitter of this type can also be used in the invention use.

A further increase in the control options can be achieved according to the invention be created in that each control element by separate, of your choice manufacturable and lockable connections can be coupled with each of the signal generators. This arrangement enables full use of the logical decision-making ability of the circuits used in the invention. It can be the response of a control element from the scanning of markings in one or more lines and at the same time can be made dependent on the non-occurrence of a marking in another line. The separate connections, which can be made and locked as required, are practical created by a pegboard. The use of peg consoles is on printing machines, which are controlled by key characters on the printing form, known per se. In such a known printing machine, the individual printing forms wear in different ways Spacing from their leading edge key characters. On a peg desk you can get any of these at different distances from the preceding one Store key characters arranged on the edge. If the machine is then on a Printing form scans a key character which is stored with the one stored on the stopper desk If the key characters match, a specific operation of the printing machine will be carried out triggered. However, such an arrangement is not sufficient to increase the control possibilities of the machine by combining several appearing in different line positions Key characters.

The control elements are preferably in a manner known per se Storage elements which can be transferred from a normal state to a storage state are. Preferably, each of the control elements is a magnetic core memory element with several input windings and one output winding, which consists of a normal magnetic state can be converted into an actuated magnetic state if two magnetically adding signals are input to the input windings , wherein further means are provided to the magnetic core memory elements to supply an interrogation signal, on which in the output windings of the magnetic Core memory elements generate control signals that control the magnetic state of the cores.

The control device according to the invention has numerous applications able to. The main area of application is in such machines, where individual information the printing form must either be printed or skipped. So, for example on a printing form strip bearing a series of addresses depending on the individual Marks assigned to addresses, individual addresses can be printed or omitted. The invention is also suitable for such machines in which with an address letters to be printed depending on the encrypted information accompanying the address one or more brochures or leaflets must be attached. For magazine subscriptions for example, people whose subscription has expired for more than 6 months is to be sent a different prospectus than those whose subscription is has expired for 3 months. Other people whose subscription is just about to expire can, with the help of the control device according to the invention, automatically third prospectus will be sent. On the other hand, the arrangement can also be made in this way that the scanning of various, encrypted specified expiry dates of Subscriptions can address one and the same control element, so that one and the same Brochure is sent. It may also be desirable to have two subscribers To send copies so that the address printing process has to be repeated.

The above examples show that a printing press may depending on the content of the information specified in encrypted form on the printing form perform numerous different operations and therefore numerous individual units must have. Nevertheless, the for the encrypted information on the printing form is for The number of lines available is often very limited. The invention makes it possible the possible combinations of the individual items given by the limited number of lines To fully utilize marking positions and thus the application possibilities of the printing machine to enlarge.

An embodiment of the invention is based on drawings described. In these, F i g. 1 is a diagrammatic front view of a Printing press equipped with the control device according to the invention is, F i g. Figure 2 is a diagrammatic enlarged view of a portion the control device, FIG. 3 is a side elevation of part of the control device; F i g. 4 is a schematic drawing of an adjustable one contained in the control device logic circuit, F i g. 5 is a schematic block diagram of a control device according to a preferred embodiment of the invention, F i g. 6 shows an individual circuit diagram of a scanning device and a coincidence amplifier, the components of the control device of FIG. 5 form, F i g. i an individual circuit diagram one in the control device of FIG. 5 contained drive circuit, F i g. 8 shows an individual circuit diagram in the control device according to FIG. 5 included Output circuit, F i g. 9 is an individual circuit diagram in the control device according to FIG. 5 contained, adjustable time circuit, F i g. 10 the contact desk the control device according to FIG. 5, with the circuit for a given Combination of control functions, FIG. 11 one of the F i g. 10 similar illustration of the contact desk, but in a different control function circuit,, F i g. 12 one used to explain certain working steps of the control device Zeitkarte and F i g. 13 shows a typical section of a transfer tape like him is used to control the control device according to the invention.

The in F i g. Contains printing machine 20 illustrated 1 a mounted on a table 22, the vertical frame 21. The table 22 rests on a base 23. On the vertical frame 21 is located a supply reel 24 25 for a Umdruckstreifen from the supply reel 24 from passing the strip or band 25 by a pair of idler rollers 26 and 27 to a tensioning roller 28 . The tension roller 28 sits on a support arm or lever 29 (see FIG. 2). The arm 29 is attached to the vertical frame, as shown at 31 , pivotably relative to this. A prestressing spring 32 is connected to the support arm 29 and prestresses the arm 29 in the sense of a counterclockwise rotation. This keeps the strip 25 under tension.

The printing forme or transfer printing strip 25 runs from the tensioning roller 28 to a drive or pin wheel 33 which engages in it. The drive wheel 33 has several outwardly projecting pins 34 which engage in openings seated at a certain distance on the strip 25. From the drive or pin wheel 33 runs, as shown in FIG. 1 shows the strip 25 into and through a printing station 35 to then engage a second drive or pin wheel 37 behind an idler roller 36. The strip 25 is then guided over a second tension roller 38 and an idler roller 39 to a take-up reel 41.

The structure and mode of operation of the printing press 20, as far as it has been described so far, are essentially known from US Pat. No. 2,740,354. During operation, the printing forme or transfer printing strip 25 is advanced from the supply reel 24 by means of a drive connected to the two drive wheels 33 and 37. The movement of the strip is not uniform, but rather gradual. The length of the strip section conveyed during each step corresponds to the spacing of the pins 34 on the drive wheel 33, and this spacing is the same as between the openings 42 of the strip. The drive wheel 37 carries equally spaced pins. When a section 43 of the printing form strip 25 is at the printing station 35, a pressure plate 44 belonging to the transfer printing machine is moved downward and presses the strip 25 against a sheet or other part to be printed, which lies on a stationary counter holder 45. The printing press 20 can be set so that two or more impressions are taken from each section 43 of the printing form strip 25. This operation of the machine and also other functions are controlled by the control device described in detail later. When the desired number of impressions has been taken from a given section of the printing form strip 25, a further strip section 43 is fed to the printing station 35 so that the machine 20 can carry out the next printing operation. After the printing of a strip has been completed, it is finally rolled up on a take-up reel 41. During the printing process, the tension rollers 28 and 38 keep the strip 25 under tension, but allow the strip to move rapidly without tearing.

A typical section from the printing forme or transfer printing strip 25 is shown in detail in FIG. 13 shown. As you can see there, each individual section 43 of the transfer printing strip has several lines of information. In the present case, the information is addresses of magazine buyers or the like. A part of each strip section 43 also bears encrypted information relating to the individual customer or the respective person identified by the information 47 printed on the strip. Each section 43 can be provided with one, two, three or four key characters which can be aligned in any manner with the four lines of the printed information arranged on the strip. So one sees in FIG. 13 in the upper section 43 a key character 48 which lies in a line with the second line of the printed information. The other of the two strip sections 43 from FIG. 13 contains two key characters 48 which are on the second and fourth lines of the printed information. The key characters 48 are approximately the same size as a letter in the printed information. It is not necessary, however, that the key characters 48 be perfectly uniform in size and shape. If the strip 25 is produced on a conventional high performance facsimile printing machine, the openings 48 can be created by punching out a piece of strip which substantially corresponds to the largest character outline of the facsimile display system. The meaning of the key characters 48 depends on the type of selection or control process to be carried out. For example, they can relate to the time and duration of an order or they can deal with other, quite different questions, for example with the payment rates of the customer, orders from other publications or the like. In other applications, for example mail lists used in connection with insurance premiums , the information identified by the key characters 48 can actually relate to all variables that can be of any importance for controlling the operation of the transfer printing machine 20.

In the control device according to the invention, the drive wheel or pin wheel 33 belongs to a scanning device for "reading" the key characters 48 and forms part of it. Basically, the scanning device consists of a photocell unit 51 in which there are four individual photocells. The photocell unit 51 also includes optics with a lens 52 which focus light reflected from the strip 25 onto the photocells in the unit 51 . In the optics of the scanning device there is also one in FIG. A suitable mask 53, shown in FIG. 2, which serves to limit the illumination of the photocells to the light reflected from a relatively narrow band which extends across the strip 25. The light for the photocells of the photocell unit 51 comes from a pair of lamps 55 seated in a housing 54. The photocells are mounted in the housing 51 in such a way that each of the photocells only shows the output from one of the four print lines on the printing form strip 25 (see F i g. 13) receives reflected light.

The photoelectric sensing device of the scanning station of the printing machine 20 also includes a fifth photocell which is not accommodated in the main photocell unit 51. This additional sensing element is the photocell 56, which sits on an arm 57 next to a certain point on the end face of the drive wheel 33. An adjustable diaphragm 58 provided with a plurality of openings 59 is attached to the drive wheel 33. The angular distance between the openings 59 corresponds to the angular displacement of individual strip sections 43 around the circumference of the drive wheel 33. Since each pair of openings 42 delimits a single strip section 43 , the number of openings 59 in the illustrated arrangement corresponds to the number of pins 34 on the circumference of the Drive wheel. In Fig. 2, the openings 59 are aligned with the pins 34. However, the cover 58 is adjustably fastened to the drive wheel 33 , for example by means of a series of screws 61 which engage in elongated slots 62 in the cover. This type of fastening allows a precise setting of the slots 59 with respect to the pins 34 and thus an alignment of the slots with respect to the individual sections 43 of the printing form strip. As will be described in detail later, this adjustability is of great value in order to accurately synchronize the control device of the invention.

The photocell 56 is illuminated by a lamp 64 (FIG. 3) which is seated in a sleeve 65 in order to illuminate the photocell 56 through the aperture 58. The position of the lamp is best shown in FIG. 3 emerges. The sleeve 65 is carried by an adjustable arm 66 which allows both limited horizontal and limited vertical movement of the sleeve in order to illuminate the photocell 56 as best as possible through the openings in the aperture. Since any suitable, adjustable mounting can be used for the lamp or the lamp can also be fixedly mounted with adjustable mounting of the photocell 56 , the construction of the adjustable arm 66 is not shown in detail in the drawings.

The general structure and operation of the control system including photocell unit 51 and photocell 56 can best be understood with reference to FIG. 5, where the complete electrical circuit is shown as a block diagram. In this figure, the four photocells mounted in the main scanning unit 51 are denoted by reference numerals 71, 72, 73 and 74. The photocells used in this embodiment of the invention are of the photoelectrically conductive type. This means that the impedance of the photocell changes when illuminated from a normal, relatively high value to a value which results considerably when actuated or exposed to light. The cells 71 to 74 can consist of lead sulfide, cadmium sulfide, cadmium selenide or similar materials. As mentioned above, each cell receives the light reflected from a single line of letters on the strip 25. The photocell 71 is connected in series with a resistor 75 between a suitable source of operating potential and earth. The operating potential source is shown at B +. The photocell is coupled to a coincidence amplifier 81 via a suitable coupling capacitor 76. The capacitor is between the amplifier and the terminal 77 of the photocell unit. The photocells 72, 73 and 74 are connected to three additional coincidence amplifiers 82, 83 and 84 through similar circuits, respectively. The gate or timing photocell 56 is connected in series with a resistor 78 between a suitable source of operating potential, referred to herein as B - + -, and ground. In this circuit, the terminal 79 is connected to each of the four coincidence amplifiers 81 to 84 by means of suitable coupling circuits with a series capacitor 80 and a shunt resistor 86. In this way, each coincidence amplifier 81 to 84 is provided with two input circuits. The gate photo cell 56 is located in one of these input circuits, and the other of these input circuits contains one of the scanning photo cells 71 to 74 in each case.

To that in the block diagram of FIG. 5 further includes five nuclear magnetization circuits 91, 92, 93, 94 and 95. The output of the coincidence amplifier 81 is connected to both the nuclear magnetization circuit 91 and the magnetization circuit 95. The second coincidence amplifier 82 has an output circuit connected to the magnetizing circuit 92 and to the magnetizing circuit 95. The coincidence amplifiers 83 and 84 are similarly connected to the nuclear magnetizing circuits 93 and 94 and each to the fifth magnetizing circuit 95, respectively. In this way, each of the four magnetizing circuits 91 to 94 is provided with an input signal from one of the coincidence amplifiers 81 to 84 , while the nuclear magnetizing circuit 95 can be excited from any or all of the coincidence amplifiers.

The five nuclear magnetization circuits 91 to 95 are individually connected to five input terminals 101, 102, 103, 104 and 105 of a contact desk 106 . In addition to the input terminals 101 to 105, the contact desk 106 has five horizontal rows 111, 112, 113, 114 and 115 of pairs of terminals, each row containing ten pairs of terminals. The terminals of these rows are used to set the control program of the control device. This is explained in detail below in connection with FIGS. 4, 10 and 11 lower row of terminals -e ar! following executed will be, are they the common or grounding klerini2n des @ontr :: _ tp_tltstroml..reises. Je? E der f; le <nmn in de: Reil-e 111 is up to the crsiea eight and including this terminal pair of the series is electrically connected to a core logic circuit 121. The core logic circuit 121 is shown in detail in FIG. 4. Shown. For the viewer in FIG. 5, it is sufficient. to know that the first six pairs of terminals in row 111 of contact desk 106 are used. Input signals from the Kernmaaneti @ ierüii; s ;; rcn: @@reise.i 91 to 95 in the logical core circuits 121 in several different combinations, so that the logical core stream '@ rei- can perform any of several logical operations . For example, due to the connections on the contact desk 106, the core circuit 121 can be connected in such a way that it has an "and". "Or" or some other logical function. The output of the circuit 121 is fed back to the contact desk 106 to the ninth pair of terminals in the row 111 , in order to create a possibility of connecting the logic core circuit 121 to an adjustable time memory 131 as desired. The memory 131 is in turn connected to an output control circuit 141 which can be connected to an electrically operated control element, such as a relay, an actuating magnet, a counter or the like.

The individual rows of terminals 112 to 115 on the contact panel 106 are substantially similar to the initially set 111 described example, the terminal pairs of the series are individually 112 at a second logic core circuit 122 a! Igeschlossen, the row 113 is operatively connected to a logic circuit 123, and rows 114 and 115 are connected to core logic circuits 124 and 125, respectively. The core circuits 122 to 125 each have an output circuit which is routed back to the contact desk 106 and from the contact desk to individually adjustable time memories 132, 133, 134 and 135. The control system has four additional output circuits 142, 143, 144 and 145, which are each connected to the adjustable time memories 132, 1.33, 1.34 and 135. Each of the output circuits 142 to 145 can be connected in a suitable manner to an individual control device, such as a relay or the like, and can be used for this purpose. to control another function of the printing machine or an additional device that works with this machine.

To consider the operation of the control system of FIGS. 5 it is initially assumed that the photocells 56 and 71 are activated at the same time, to supply the coincidence amplifier 81 with two relatively short pulses. To the At the same time the amplifiers 82 to 84 from which the photocell 56 is contained will end A similar signal is supplied to the circuit. If these coincidence amplifiers, however No input signal is supplied from the photocells 72 to 74, they generate Coincidence amplifier no pronounced signals. The coincidence amplifiers 81 to 84 are so constructed that they emit distinct output signals only when if they are actuated by synchronous input pulses. One of those impulses must from the gate or time photocell 56 and the other from a particular one Sense or scan photo cells 74 are running out. With the structure described above of the scanning photo cell unit 51 and using black characters such as the key characters 48, on the printing form strip 25 (see FIG. 13), the scanning or sensing photo cells 71 to 74 normally illuminated to a considerable extent and then form in that Sense circuit has a relatively low impedance. However, if any of the key characters 48 in the reflection path of one of the scanning photo cells, for example cell 71 jelü_t ji, daaa the impedance of the photocell jumps up. and that leads to that the coincidence amplifier 81 is supplied with a negative going pulse. Such Of course, impulses are also sent to the coincidence amplifier 81 when scanning pressure points on the printing forme 25, for example the address information 47 (see FIG. 13). However, these pulses are usually much shorter than the desired key signals and usually of considerably smaller amplitude than the printed information 47 do not include such large non-reflective areas as the key signs 48.

The photocell 56 is normally covered by the aperture 58 (see FIGS. 2 and 3) and is therefore generally not illuminated by the lamp 64. However, when the photocell 56 is in alignment with one of the apertures 59 it will be illuminated so that its impedance will drop well below its normal or unlit value. When this happens, a negative going pulse appears at terminal 79 and is fed to coincidence amplifiers 81-84. In the arrangement described, the photocell circuits are so constructed that the scanning photocells 71 to 74 and the gate photocell 56 supply the coincidence amplifiers with any negative-going impulses. Such an arrangement is recommended, but depending on the structure of the coincidence amplifier, it does not necessarily have to be made.

As discussed above, the coincidence - #; - solid; he 81 produces a usable output signal only if input signals from the photocells 56 and 71 are fed to it at the same time. It is therefore possible to prevent all of the signals fed to the amplifier as normal print text passing by the photocell 71 from actuating the control device by simply ensuring that the photocell 56 cannot be actuated at the same time. As in Fig. 13, the key characters 48 on the printing form strip 45 do not lie directly next to the printed information 47. Rather, a free space is left in each case between the address information and the key characters. The diaphragm 58 can thus be adjusted in order to bring about the desired coincidence between the scanning of the narrow strip parts on which the key characters 48 are located and the actuation of the photocell 56 by lighting through the diaphragm openings 59. The gate photocell 56 thus represents an effective and reliable means of distinguishing between the key characters 48 and the printed indications 47 and prevents any actuation of the control device when scanning printed indications. Are the output signals from the coincidence amplifiers 81 to 84 as mentioned above, to 91 produce five different outputs from the nuclear magnetization circuits to 95 wt. The arrangement of the fifth magnetizing circuit 95, which is actuated whenever any of the coincidence amplifiers 81 to 84 gives an output signal, provides for a much greater operational flexibility of the logic control device than would otherwise be possible. This aspect of the invention will be discussed in detail hereinafter, particularly in connection with FIGS. 4, 10 and 11. For the consideration of the F i g. 5, it is sufficient to note that the creation of the Kumulativ- or multi-line signal does substantially simpler of the magnetizing circuit 95 to realize a number of different logic functions in the operation of the logic core circuits 121 to 125.

On the contact panel 106 the terminals are connected between the input terminals 101 to 105, 111 placed 116 numerous compounds to 115 of the kernel logic circuits and the additional terminals to each of the logical core circuits 121 to 124 in accordance with a particular desired combination or a series of combinations to program key characters of the printing form strip used in the transfer printer to control a specific machine function or a function related to it. By establishing certain connections on the contact desk 106 , for example, the core logic circuit 121 can be put into such a state that it only emits an output signal when the one photocell 71 scans a control character. In modification of the compounds, however, the kernel logic circuit can also be placed in a state where it generates a suitable output signal when scanning any desired combination of control characters by any of the photocells 71 to 74. In other words, appropriate connections on the contact desk 106 allow the logic circuits 121 to perform any desired logic function based on any combination of key characters. The output signal from this circuit is input into the time memory 131 and is used to control a function of the printing machine or an additional device.

If necessary, the circuits 131 and 141 can be used to control the imprint at the printing station 35 (see FIG. 1) of the machine 20 . Obviously, this control cannot take place at the same time as the scan, since the scan point is a considerable distance away from the printing station. This means that the respectively scanned strip section 43 does not coincide with the strip section located in the printing station 35. In the machine shown, a strip section is scanned approximately six working cycles of the machine before the point in time when the same strip section reaches the printing station. The time memory 131 must therefore store the output signal from the logic core circuit 121 until the printing form strip has been advanced through the machine by six working cycles. On the other hand, a longer or shorter delay time may be desirable in certain cases. For example, in certain applications it may be necessary to give the machine operator an audible warning signal immediately prior to the point in time when a particular strip section reaches the printing station 35 so that the operator can interrupt machine operation or make any control settings on the machine. In this case, the time memory must become effective after a smaller number of work cycles in order to input a suitable control signal into the output circuit 141. The in F i g. The preferred time memory shown in FIG. 9 allows the delay time to be set to any number of machine work cycles within a certain range, in this case within ten machine work cycles. With this feature of the invention, the control device according to FIG. 5 control a large number of machine operations or auxiliary devices connected to the machine without having to make any structural changes in the control device. In any case, however, the accuracy of the timing of the controlled processes is not impaired.

F i g. 6 illustrates a typical circuit for the coincidence amplifier 81 of FIG. 5 and also contains the operating circuit of the scanning photocell 71. Since the coincidence amplifiers 81 to 84 are essentially similar, the circuit shown in FIG. 6 apply as an example for each of these circuits.

Like F i g. 6 shows, the amplifier circuit 81 contains an amplifier input stage with a triode part 151 which has a cathode 152, a control electrode 153 and an anode 154 . The control electrode 153 is connected to the photocell 71 through an input circuit including a capacitor 76 and an input resistor 155. The resistor 155 is fed back to a suitable operating potential source C-. The cathode 152 is grounded and the anode 154 is connected to a potential source E + via a load resistor 156. The triode part 151 is therefore switched into a very simple amplifier circuit.

In the next stage of the circuit 81 there is a second Triodeentei1157 with a cathode 158, a control electrode 159 and an anode 161. The input circuit of this stage of the amplifier 81 includes a capacitor 162, which is between the anode 154 of the triode part 151 and the control electrode 159 of the Triode part 157 is switched on. The input circuit also includes an input resistor 163 connected to a potentiometer 164. The potentiometer 164 is connected in series with a bias resistor 165 between an operating potential source D- and earth. A diode 166 is located parallel to the input resistor 163. The cathode 158 of this amplifier stage is grounded. The anode 161 of the triode part 157 is connected via a load resistor 167 to the middle terminal 168 of a voltage divider with two resistors 169 and 171. The voltage divider lies between the voltage source E + and earth.

The anode 161 in the amplifier triode 157 is connected to the control electrode 173 of a triode part 174 via a capacitor 172 . The triode part 174 forms one half of a coincidence amplifier, to which a further triode part 175 belongs. The input circuit of the triode part 174 also includes an input resistor 176, which lies between the control electrode 173 and the voltage source E +.

The cathodes 178 and 179 of the triode parts 174 and 175 are grounded, respectively. The anodes 182 and 183 are connected to one another and to a load resistor 184 . This is due to the agent terminal 185 of a voltage divider with two in series between the voltage source E + and ground down resistors 186 and 187. The control electrode 181 of the second Triodent rope 175 is connected to the operating circuit of the photocell 56 and runs, more specifically, through the capacitor 80 back to the photocell circuit. Looking at FIG. 5 it can be seen that the input circuit of the triode part 175 is very similar to that of the triode part 174 , the resistor 86 forming the input resistance for this second triode part. The output circuit for amplifier 81 includes a coupling capacitor 188 connected to anodes 182 and 183 and nuclear magnetization circuits 91 and 95 . In order to prevent feedback from the other coincidence amplifiers 82 to 84 , a diode 181 is preferably connected in series in the input circuit to the nuclear magnetization circuit 95.

As stated above, the photocell 71 operates by reducing the light reflected by the printing form strip 25 onto the photocell, this light originating from the lamps 55 (see FIGS. 1 and 2). The photocell 56, on the other hand, works with direct lighting from the lamp 64 through the aperture 58 (see FIGS. 2 and 3). Accordingly, the output from photocell 71 is usually much weaker than that from photocell 56. This is because, to some extent, light from sources other than lamp 55 is also present and prevents the photocell 71 from being completely interrupted and further that the key characters 48 are not completely reliable in excluding the light from the lamps 55 from reflection. For this reason, sufficient amplification is required in order to bring the pulse signals from photocell 71 to approximately the same amplitude level as the pulses from photocell 56 . This is done with the first two stages of the amplifier 81, in which the triode stages 151 and 157 are located. These two stages of the amplifier 81 are therefore primarily used to amplify the output signals from the photocell 71 to approximately the same amplitude level as the signals from the cell 56. In a typical machine, all such voltage sources as B +, C-, D- and E + have been created by rectifying a suitable AC power source, such as a common 60 Hz source. The bias and input circuit for the triode part 115 provides an effective means of compensating for the 60 Hz oscillation and other noises otherwise contained in the output signal from the amplifier stage 151. In this way, by using the amplifier 151, 157, no extraneous or undesired pulse signals are introduced into the coincidence amplifier stage 174, 175 . Normally, and when there are no input signals, the two triode parts 174 and 175 of the amplifier 81 are kept in the conductive state, the control electrodes 173 and 181 each being kept at a relatively high positive potential with respect to the cathodes 178 and 179. A negative pulse signal applied to the control electrode 173 from the amplifier 157 tends to decrease the conduction in the triode part 174 considerably. The triode part 175 remains conductive, however, and there is little or no change in the operating potential at the anodes 182 and 183. On the other hand, if the control electrode 173 and the control electrode 181 of the triode part 175 are simultaneously supplied with negative pulses, then the conductivity in both Triode parts considerably reduced, and this leads to the fact that both anodes 182 and 183, based on their normal operating potential, are positively excited. In other words, a negative pulse applied to one of the two control electrodes 173 and 181 of the coincidence amplifier only causes a pronounced amplifier output signal, in this case a positive pulse, if a corresponding input pulse is applied to the other of the two control electrodes. Accordingly, the output signal applied to circuits 91 and 95 appears only when input signals from both the gate photocell and the scanning photocell 71 are available.

F i g. 7 schematically illustrates the nuclear magnetization circuit 91. However, this circuit is very similar to the remaining nuclear magnetization circuits 92 to 95 (see FIG. 5) and can therefore be substituted for any of these nuclear magnetization circuits.

To the nuclear magnetization circuit 91 of FIG. 7 includes a thyratron 191 with a cathode 192, a control electrode 193, a shield electrode 194 and an anode 195. The input circuit connected to the control electrode 193 contains a shunt capacitor 196, a series resistor 197 and an input resistor 198, the latter being connected to a potential source F- of negative polarity is returned. The anode 195 is connected to the operating potential source E + via a suitable resistor 199 and is shunted to earth via a capacitor 201. The shield electrode 194 is grounded. The cathode circuit of the thyratron 191 contains a resistor 202 which is connected in series with an input winding 203 which is seated on a synchronization memory designed as a magnetic core 204. The cathode circuit is grounded. A diode 205 is shunted to the series circuit consisting of resistor 202 and winding 203. The core 204 is a conventional magnetic core with a preferably substantially rectangular hysteresis characteristic and, as will be explained in more detail below, serves as a synchronization and timing element in the magnetization circuit 91.

In addition to its input winding 203, the core 204 has a reading or interrogation winding 205 ' and an output winding 206. The output winding 206 is in series with a resistor 210 and the control electrode 208 of a second thyratron 207. This is sometimes referred to as a pulse generator tyratron. The input circuit of the pulse generator tyratron is fed back to the operating potential source F- of negative polarity. The shield electrode 209 of the pulse generator tyratron 207 is connected to the cathode 211 and this is in series with a resistor 212 of the output circuit of the thyratron. Since it is the magnetization stage 91 that is shown in FIG. 7, the output resistor 212 is connected to the contact desk terminal 101 in this case. The remaining stages of the magnetizing circuits 92 to 95 are each connected to the remaining contact terminals 102 to 105, as shown in FIG. 5 is shown. The anode 213 of the thyratron 207 is connected to the operating potential source E + via a resistor 214 and is grounded by a series circuit with a capacitor 215 and an inductance 216.

The reading or interrogation coil 205 of the sync core 204 is connected in series with corresponding windings in each of the circuits 92-95, wherein a terminal of the down windings in series is grounded. Like F i g. 7 shows, the other terminal of the interrogation winding circuit is connected to a cam-operated switch 218 which is actuated by a cam 219 which is located in the printing press 20 and which makes one complete revolution during each cycle of the press. The construction and location of switch 218 and similar switches described below are not shown in the drawings, as any cam switch or similar device is suitable for this purpose.

The switch 218 is connected to the operating potential source EI- via a capacitor storage circuit with a series resistor 221 and a shunt circuit with a resistor 222 and a capacitor 223. The shunt circuit is grounded.

As stated above, the initial control signal from the coincidence amplifier 81 in any case consists of a pulse of positive polarity. Normally thyratron 191 is kept non-conductive, but the pulse from circuit 81 is of sufficient amplitude to trigger the thyratron and render it conductive. When the thyratron conducts, the current flowing through the winding 203 changes the magnetic state of the synchronization core 204 and thus stores in the core the fact that an initial control signal has been received from the circuit 81.

In order to read data from core 204 , switch 218 is briefly closed so that capacitor 223 is discharged and an interrogation pulse is supplied to winding 205 and the corresponding interrogation windings of the synchronization cores in the other nuclear magnetization circuits 92 to 95 (see FIG. 5) will. If the magnetic state of the core 204 has been changed by actuation of the initial stage of the circuit 91 , then energization of the interrogation coil 204 causes the magnetic state of the core to be reversed back to its original state. An output pulse is generated in the winding 206. This output pulse is of positive polarity and puts the thyratron 207 in the conductive state, whereby it generates an actuation signal in the anode-cathode circuit of the thyratron 207. This actuation signal is fed to the contact desk terminal 101 and can be used to actuate any of the core logic circuits 121 to 125 in the manner described below. It should be noted that all of the synchronization memories such as core 204 in the core magnetization circuits are scanned at the same time. This ensures that the actuation signal pulses from the magnetizing circuits 91 to 95 are fed to the contact desk 106 and from there to the core logic circuits 121 to 125 at the same time. The effect of this simultaneous actuation of all of the nuclear magnetizing circuits is that any deviations in the timing of the signals supplied to the magnetizing circuits by the coincidence amplifiers 81 to 84 are compensated for. Such deviations can be caused by the fact that the key characters 48 on the printing form strip are offset in a direction running parallel to the printing lines 47 (see FIG. 13). The circuit shown allows the actuation signal pulses to be synchronized within a microsecond. This is the case despite the much larger fluctuations that occur in the timing of the sampling and gate signals.

F i g. 4 illustrates the logic storage element 121 and the circuit which connects this storage unit to the individual terminals of the row 111 of the contact desk 106. As shown here, each terminal of the first six terminal pairs of the row 111 is connected to a special input winding of the storage element 121. The memory element 121 itself is preferably a conventional magnetic memory core with approximately right-angled hysteresis characteristics, which can be adjusted between two stable magnetic states. The individual coupling elements or windings of the core connected to the first six pairs of terminals are designed so that the actuation signals from any of the circuits 91-95, when applied to any of the core windings, are insufficient to control the magnetic state of the core change. Rather, the excitation of two windings is required in each case in order to change the magnetic state of the core. In other words, the number of turns in each of the windings is such that the 121 by an output signal from any of the circuits 91 to 95 supplied ampere-turns slightly more than half as large as that required to change the magnetic state of the core ampere the core. The winding connected to the seventh pair of terminals in row 111 is an interrogation winding.

F i g. 4 also shows the terminal row 116. As you can see, this terminal row of the contact desk is grounded. In addition, the eighth pair of terminals in each of the terminal rows 111 to 115 is grounded. The ninth pair of terminals in row 111 is connected to one another and, via a diode 225, is also connected to one of the terminals in the seventh pair of terminals. The terminals of the tenth pair of terminals, on the other hand, are connected to one another, and one of these terminals is, as will be described below in connection with FIG. 9, connected to the time memory 131. The connections of the contact desk terminals 111 are exemplary of the connections of the terminals in rows 112 to 115 . The first six pairs of terminals of series 111 provide an effective means for changing the logical function of the magnetic core 121 by change of the input windings of the core supplied operation signals. The seventh clamp pair forms an output circuit for the logic core 121. The eighth pair of terminals is only intended for preparing suitable Ground connections, and the ninth and tenth pairs of terminals form adjustable devices for coupling the logic cores with the time memories 131 to 135.

The core 121 also has an interrogation winding 226, one end of which is connected to the voltage source E -? - through a resistor 227 and is returned to ground via a series circuit comprising a resistor 228 and a storage capacitor 229. The other end of the reading or interrogation winding 226 is connected to a switch 231 which interacts with the time memories of the control device and is shown in detail in FIG. 9 is shown. With regard to the mode of operation of the logic core circuits 121, it is sufficient to determine that the switch 231 can be closed periodically in order to discharge the capacitor 229 through the winding 226 and thus initiate an interrogation process. The other logic core circuits of the control device are equipped with similar query circuits.

For the consideration of the mode of operation of the in F i g. 4 with the logic core 121 and part of the contact desk 106, assume a typical simple connection of the logic core, as it is shown in dashed lines in FIG. 4 is indicated. The input terminal 103 is connected to one of the general or grounding terminals through the third pair of terminals in row 111. Similarly, the input terminal 105 is connected to the input winding, which is common to the fifth pair of terminals in the series 111, and then grounded. In the illustrated arrangement, the current flow which is required to transfer the core 121 from the normal or inoperative state to the actuated or registered state is from the top row of terminals 111 to the bottom row. That is in Fig. 4 indicated by the symbols -I- and -. The input terminals 103 and 105 are switched for a positive registration or recording process.

If the in F i g. 4 are shown in dashed lines, the input of a registration or actuation signal to any of the input terminals 101, 102 or 104 does not affect the operation of the core 121, since these terminals are not connected to the core or otherwise Interaction are coupled. If an output signal is available from any of the circuits 91, 92 or 94, however, a signal is also available from the magnetizing circuit 95 which produces an actuation signal whenever any of the other magnetizing circuits is actuated. This is earlier in connection with FIG. 5 has been described. However, an input signal applied only to terminal 105 will not result in a change in the magnetic state of core 121 since, as described above, the circuit is designed so that by energizing any of the windings connected to the first six pairs of terminals for the core only a little more than half of the ampere-turns required to change the magnetic state of the core is applied. On the other hand, the core 121 is changed from the normal magnetic state to the operated or registered state at any time when operating signals from the circuits 93 and 95 are inputted to the terminals 103 and 105 at the same time. However, this always happens when an output pulse from the circuit 93 is available, since the circuit 95 always develops an actuation pulse at the same time as it.

During each machine work cycle, the switch 231 is briefly closed in order to supply the winding 226 with an interrogation pulse. If necessary, this happens after the registration has been completed. When the core 121 is in its normal, non-registering state, the input of the interrogation pulse to the winding 226 does not significantly affect the magnetic state of the core and does not produce an effective control signal in the winding connected to the seventh pair of terminals. If, on the other hand, the magnetic state of the core 121 has previously been changed by the simultaneous input of input signals through the terminals 103 and 105 , then the interrogation by energizing the winding 226 returns the core 121 to its original magnetic state and generates a considerable output pulse in the Output winding 232. This assumes, however, that the output winding is fed back to one of the terminals of the eighth pair and therefore forms a complete output circuit. The control signal can be fed to the timing memory 131, and this is done by establishing a connection between the ninth and tenth pairs of terminals of the row 111.

Since the input windings for core 121 each have half the amperage required to change the magnetic state of the core, complete blocking can be achieved by passing any "but" signals in the opposite direction through an input winding of the Kernes from - to -h sends. The reversed polarized signal then cancels a recording signal sent in the normal direction through the core and prevents a change in the state of the logic core 121. The control signals from the core terminate in the two seventh and ninth pairs of terminals 111 of the desk for an efficient and simple means to provide the output pulse from any one of the cores 121-125 to any one of the five timing memories 131-135 (Fig. 5). As the illustration in FIG. 4 shows that any one of the logic cores can be connected to the contact desk in order to supply the time register 131 with an output signal. The illustrated contact panel arrangement also makes it possible to bypass the series diode 225 in the output of the core 121 to provide a convenient means of blocking the output of any of the logic cores by actuating any of the other cores.

F i g. Figure 10 shows a typical contact desk arrangement for performing five different functions. This means that this contact desk arrangement has the effect that five different output signals fed to the five time memories 131 to 135 are created. The row 111 of the contact pairs of the contact desk is, as above in connection with FIG. 4, switched in such a way that it provides for the actuation of the first time memory 131 in order to control a first function in response to the scanning of a character in the third line of the four printed lines on the printing form. The second row of terminal pairs 112 is connected in such a way that it actuates the second time memory 132 (see FIG. 5) whenever characters appear in lines 1 and 2 of the control characters of the printing form strip. Like F i g. 10 shows, the third row 113 of the contact desk is connected in such a way that it controls a third function associated with the time memory 133 when a character appears in the third line of the printing form strip, except when a character appears in the fourth line. This means that the connections in this case are the same as for the terminal row 111 , only that the input terminal 104 is connected in the opposite sense to the fourth terminal pair of the row 113 and in response to a signal occurring when a character is scanned in the fourth line of the strip provides for a cordon.

The connections of the fourth row of terminals are made in such a way that a fourth function associated with the time memory 134 is triggered in response to output signals which are characteristic of characters in lines 1, 2, 3 and 4 of the strip. Each of the input terminals 101 to 104 is connected to the first four pairs of terminals in row 114 in the positive sense. The fifth input terminal 105 is, however, connected in the opposite direction and returned in the opposite direction through the windings connected to the fifth and sixth terminal pairs of the row 114. In order to apply the required for the connected to the terminal block 114 logical ampere core must therefore be energized 101 to 104 all four input terminals.

On the other hand, the connections of the terminal row 115 are again different. In this case, characters appearing in one of lines 1 and 2 activate the logic core connected to terminal 115, provided that no control characters appear in lines 3 and 4.

F i g. 11 gives another example of the multitude of control functions that can be achieved by simply changing the connections on the contact desk 106 . In this case, input signals appearing at the input terminal 101 or 102 , which indicate the occurrence of control characters in the first or second line of the printing form strip, optionally form means for controlling a first function by the first time memory 131 supplied output signals. However, an input signal must also appear at terminal 105. A second function controlled by the time memory 132 can be triggered by characters appearing in the first or second line of the printing form strip, unless characters appear in both the first and the second line. This means that the contact desk is now switched in such a way that the output of the logic core 123 connected to the terminal row 113 blocks the output of the logic core 122 connected to the contact desk terminals 112. Finally, characters appearing in the first and fourth lines, which generate input signals at terminals 101 and 104 , trigger a fourth function assigned to the time memory 134 connected to the terminal row 114. In addition, the last row of terminals 115 is connected in such a way that this fourth function is also controlled by the logic core 125 which controls the fourth function assigned to the time memory 134. In other words, the output side of the contact desk comprising the ninth and tenth row of terminals is connected in such a way that both the output signals of the logic cores 124 and those of the logic cores 125 control the fourth time memory 134. The time memory 135 is in the FIG. 11 is not used.

Looking at FIG. 10 and 11 it can be seen that the control device according to the invention enables at least five different machine operations or other functions to be controlled in accordance with actually any desired logical arrangement, which relates to the scanning of characters by means of cells 71 to 74 (FIG. 5 ) in the four positions available on the printing forme strip 25 (see FIG. 13). Control is based on the four corresponding input signals that appear at terminals 101 to 104 and the "generic" signal that appears at terminal 105. The special control signal at terminal 105 can be used for addition to or subtraction from the operation for the signal pulses at the terminals 101 to 104 to provide a complete blocking control on the touch panel.

F i g. 9 illustrates blending into the individual, the adjustable time memory 130 for each of the time memory is typically 132 to 135 and is substantially similar to these. The time memory 131 has eight output terminals 241 to 248, which range from delay 0 to the greatest possible delay of the memory. In the present case, the time memory has seven memories or delay stages. As shown by the movable contact 249, each of the output terminals 241 to 248 can be connected to the output control circuit 141. The output circuit of the memory 131 contains a series diode 251. The first or 0-delay output terminal 241 is connected directly to the tenth terminal of the terminal row 111 of the contact desk 106 (see FIGS. 4 and 10) via a resistor 252, and when it is connected to When connected to contact 249, it enables any functions to be controlled immediately after an output signal has occurred from a core logic circuit connected to this terminal on the contact desk. When scanning a certain combination of control characters, it may be necessary, for example, to put some additional device into operation that introduces a special proof sheet into the printing station of the machine. This additional feed operation can require the same time that is necessary to feed the scanned section of the transfer printing strip to the printing station. Under these circumstances, the output terminal 241 emits an instantaneous control signal in order to actuate the additional device.

The input circuit including resistor 252 is also in series with a resistor 253 and an input winding 254 located on a first core 255. This circuit is grounded. The core 255 has an interrogation winding 256 and an output winding 257 in addition to the input winding 254. The core 255 is only one of two cores in the first stage of the time memory 131. The second core 258 has an input winding 259, an interrogation winding 261 and an output winding 262. The output winding 257 of the core 255 is connected in a series circuit comprising a diode 263, a resistor 264 and the input winding 259 of the core 258. The two ends of the series circuit are grounded. A second diode 265 is connected between ground and the general terminal 266 of resistor 264 and diode 263. The output winding 262 of the core 258 is connected between the second output terminal 242 and ground, thus completing the first stage of the time memory.

The second stage of the timing memory contains a pair of cores 267 and 268. The output winding 262 of the first stage core 258 is connected to the input winding 269 of the second stage core 267 by a circuit substantially similar to that used in the windings 257 and 259 connects. Similarly, output winding 271 of core 267 is connected to input winding 272 of second core 268 of this stage by a similar circuit. The input core 267 of the second stage has an interrogation or readout winding 273, while the core 268 carries an interrogation winding 274 and an output winding 275. The output winding 275 is connected to the third output terminal 243 of the time memory and also to the input winding of the next stage of the memory. It can thus be seen that the seven storage stages of memory 131 are very similar to one another, and each of these storage stages is connected to one of the output terminals 242-248.

All interrogation windings such as windings 256 and 273 in the lower or input group of cores of the time memory 131 are connected in series with one another in an advance circuit 278. A terminal 277 of this series circuit 278 is connected to the potential source E + via a resistor 279 and also grounded via a storage circuit with a resistor 281 and a capacitor 282. The other terminal 283 of the advance circuit 278 is connected to a normally closed switch 284 controlled by a curve 285. A diode 286 is connected in series between the terminal 283 and the switch 284. The other side of switch 284 is returned to ground through a pair of relay contacts 287. The switch 284 is closed for a relatively short period of time during each machine work cycle. This will be discussed in more detail below.

The interrogation windings such as windings 261 and 274 of the upper core group are similarly connected in series with one another and form a second advance circuit 288. One end of this second advance circuit 288 is connected to terminal 277, and the other terminal 289 of this series circuit is via a diode 291 connected to the normally open switch 231. The other side of switch 231 is also returned to ground via relay contacts 287. Switch 231 is coupled to switch 284 for actuation through curve 285. If desired, a single pole two-way switch can be used in place of the two switches 231 and 284.

To understand the mode of operation of the in F i g. 9, the sequence in which the operating circuits of the memory are operated must first be considered. This sequence is discussed in detail below in connection with FIG. 12 described. It should be noted, however, that during a first machine work cycle the first operation to take place in the time memory 131 is the input of a signal pulse into the interrogation or advance circuit 278. This is done while the switches 231, 284 are in their normal positions, by relatively briefly closing the relay contact 287 in the manner described below. If, at this point in time, none of the cores in the bottom row, which includes cores 255 and 267 , have any indication registered, then this initial actuation of advance circuit 278 will not cause any change in the operating state of any part of the timing memory.

Subsequently and during the same work cycle, a control signal can be received from terminal 111, column 10, of contact desk 106 . This signal is applied to winding 254 and changes the magnetic state of core 255 from normal to actuated or registered. In this way, a first indication is stored in the first stage of the time memory 131. However, the time memory does not yet develop an output signal, since the output terminal 243, to which the output circuit contact 249 is connected, is effectively isolated from the first stage of the time memory. In the illustrated arrangement, the interrogation of the core logic circuit or circuits connected to the timing memory 131 is effected by actuating the curve 285 which closes the normally open switch 231. Switch 231 closes when switch 284 opens. When switch 231 is closed, relay contacts 287 are closed and provide a reset signal to the logic cores and also to reset or advance line 288 of the time memory. This signal sets the core 258 to its original or unactuated magnetic state, preparing the core for subsequent information registration. Resetting the core 258 can also produce an output signal in the coil 262 if an indication has previously been registered in the core, and this signal current also flows through the coil 269 and changes the magnetic state of the core 267 from the original state to an actuated one or registration status. The registered indication is thus transmitted from the core 258 to the first core 267 of the second level of the time memory. An output signal can be developed at terminal 242; however, it is not used because this terminal is not connected to output contact 249 of the time memory. This work sequence is repeated during the second machine work cycle. Thus, at an early point in time of the second machine work cycle, the relay contacts 287 are closed and give the advance circuit 278 a reset or advance signal. In this case, the reset circuit resets the core 255 to its original magnetic state, thereby generating an output signal in the output coil 257. The output signal from the coil 257 is effectively transmitted to the input coil 259 of the core 258 , so that the previously registered in the core 255 Specification is now transferred to the core 258 .

During the further course of the further work cycle, the curve 285 opens the switch 284 and closes the switch 231. The relay contacts 287 are closed again and input a reset signal into the advance or reset circuit 288. At the same time, the logic core circuits are queried and a further piece of information can be registered in the coil 255 , or no information needs to be registered in the first core 255 during this second working cycle, depending on the actuation of the control circuits preceding the time memory in the control device to become. The core 268 is restored to its original magnetic state or set again and an output pulse is generated in the output winding 275 of this core. If the core 258 has previously been switched from its original to the actuated magnetic state, that core will also be returned to its original state. The output signal occurring in coil 275 of core 268 excites the input coil of core 292 and registers the first part of the data therein. Similarly, any indication registered in core 258 is transmitted to core 267. In this case, however, assuming that the core 268 has previously been converted from its original to its actuated magnetic state, the output signal generated in the coil 275 is transmitted through the adjustable contact 249 and the associated circuit to the output circuit 141 of the control device . Since the output of the time memory is taken from terminal 243 , any further change in the remaining stages of the memory is of no importance for the operation of the output circuit 141 of the control device. If, on the other hand, the adjustable contact 249 is connected to one of the following output terminals, for example terminal 248, then the process described above continues until an output signal appears at the output terminal.

F i g. 8 shows in detail a preferred embodiment of the output circuit 141 of the control device according to FIG. 5. This circuit 142 may apply to 145 of the control device as an example for any other of the output circuits. All of these circuits are constructed similarly to that in FIG. 8 shown. In this connection it should be mentioned that it is not essential to use any specific number of the combinations 131, 141 formed from a time memory and an output circuit of the control device. In the present embodiment, five such combinations are shown. However, the number can be changed according to the needs of the machine or the machines to which the control device belongs. In addition, it is also not important that the number of combinations formed from a time memory and an output circuit of the control device corresponds to the number of logical core circuits. As namely above in connection with FIG. 11, namely two logic core circuits can be used to control a time memory, and this can be continued by assigning additional core circuits to a single time memory. As can also be seen from the above treatment of the contact desk 106 and its mode of operation, a single logical core circuit can moreover control many time memories and the output circuits of the control device assigned to them.

The control device output circuit 141 shown in FIG. 8, a thyratron 301 has a cathode 302, a control electrode 303, a shield electrode 304 and an anode 305. The control electrode 303 of the thyratron 301 is coupled to the time memory 131 by an input circuit including a capacitor 306 and a bias resistor 307. The bias resistor 307 is fed back to the negative potential source F-. The input impedance has a resistor 308 and a blocking capacitor 309 which are connected in series with one another and are grounded. Cathode 302 and shield electrode 304 are both grounded.

The output circuit of the thyratron 301 includes a load resistor 311 which is connected to the anode 305 of the thyratron and is in series with the actuating coil 312 of a relay 313. A capacitor 310 is preferably placed in parallel with the relay coil 312, and a resistor 314 is connected in series with the capacitor. The anode circuit of the thyratron 301 is connected to the voltage source E + via a normally closed switch 315 actuated by a curve 316. Like F i g. 8, the cam switch 315 also serves to control the operation of the other output circuits 142-145 of the control device. It is connected in these circuits in the same way as in circuit 141 .

Cam operated switch 315 is a single pole, two way switch. The normally open terminal 317 of the switch is in series with a resistor 318 and the actuating coil 319 of a relay 321. The other terminal of the coil 319 is grounded. The contacts 287 of the relay 321 are used in the manner described above to control the operation of the time memories 131 (see FIG. 9). Another actuation circuit for the relay coil 319 is formed by a cam actuated switch 322 (actuated by a cam 323) which connects the resistor 318 back to the voltage source E-1-. Switch 322 is a normally open single pole two way switch.

The structure of the relay 313 is not essential to the present invention. In the illustrated embodiment, the relay is equipped with normally open contacts 324 and normally closed contacts 325 . These are used to connect an output circuit 326 to a suitable AC power source. This circuit arrangement includes a switch 327 for setting the relay to energize or de-energize either a pressure control device or other control device. Any desired arrangement of relay contacts and control circuitry can be used in conjunction with relay 313 without departing from the scope of the present invention.

The operation of the output circuit 141 of the control device is very simple since it acts mainly as a controlled excitation circuit for the relay 313. Thus, during any machine work cycle, a control signal can be input from the time memory 131 into the control electrode of the thyratron 301 and thereby ignite the thyratron. When the thyratron becomes conductive, the relay coil 312 is energized, actuates the relay 313 and effectively controls any machine function or related processes. In the next working cycle of the machine and before the next interrogation of the time memory, the switch 315 is actuated by the curve 316 in order to open the anode circuit of the thyratron. This de-excites the tube until another excitation signal arrives from time memory 131. This can be the case either during this or during a subsequent work cycle of the machine.

For a better understanding of the operation of the control device the F i g. 5 and the related circuits and facilities that in Figs. 4 and 6 to 11 is shown in FIG. 12 a time table is drawn. This shows in detail a typical work sequence during a certain machine work cycle. It should be noted that the order given there is not necessarily to be adhered to needs, rather, F i g. 12 just an example of a practical and effective timing.

In the time table of FIG. 12, the movement of the pressure plate 44 of the printing press is shown by the line denoted by 331. The entire machine work cycle can be subdivided into 360 degrees of angular motion, for example in relation to the control shaft for the numerous cam-controlled switches. You can see that the downward movement of the pressure plate starts about 20 ° after the start of the work cycle. The actual printing process in FIG. The machine illustrated in FIG. 1 takes place between approximately 165 and 245 °. The advance of the strip 25 begins at about 40 ° and ends at 165 ° before the start of the printing process.

The first of the control switches to be actuated is switch 315 from FIG. B. As in Fig. As shown in FIG. 12, the switch 315 is moved from its normally closed position to its other position, where it touches the contact 317, during a period of time corresponding to approximately 20 ° of a machine working cycle. The start is at 40 °. During this period of time, denoted by 332 , the anode circuit of the thyratron 301 of the output circuit 141 of the control device (FIG. 8) is opened. The thyratron becomes non-conductive and is prepared for a subsequent control process which takes place in response to a signal given by the time memory 131. At the same time, an excitation circuit is established from potential source E-1- through switch 315, resistor 318, and relay coil 319 to ground. The relay 321 is accordingly energized, closes the contacts 287 and energizes the advance circuit 278 of the time memory 131 (see FIG. 9) effectively. During the period 332 (FIG. 12), therefore, the output circuit 141 of the control device is effectively de-energized and the lower core row of the time memory is reset, with any information stored therein being transferred to the upper core row of the time memory 131 . Each of the other output circuits 142 to 145 of the control device is de-energized at the same time, and an indication is advanced by half a step in the time memories 132 to 135.

Thereafter and after the switch 315 has returned to its normal position in FIG. In the position shown in FIG. 8, the switch 218 in the interrogation circuit for the nuclear magnetization circuit 91 (FIG. 7) is switched from its normal, open position to its closed position. The memory or synchronization core 204 is reset and emits an actuation signal to the contact desk terminal 101 , provided that the core 204 had previously been transferred from its normal to its actuated magnetic state for registration. The same process takes place in nuclear magnetization circuits 92 through 95, all of which are coupled to switch 218 in the same way as circuit 91. In Fig. 12 it is shown that the actuation of the switch 218 takes place in the period between 130 and 1.90 ° of the machine work cycle. This is indicated by reference number 333 . At about 150 ° of the machine work cycle, the curve 285 actuates the switches 231 and 284 (FIG. 9), the switch 284 being opened and the switch 231 being closed; as indicated by reference numeral 334 of FIG. 12 indicated, this switching process takes up to about 210 °. Shortly afterwards, as indicated by the reference number 335 , the switch 332 is actuated (see FIG. 8) in order to energize the relay 321 for the second time. Accordingly, the reset circuit 288 of the control timing memory 131 is energized, resetting each of the cores in the upper row of the timing memory and transferring any indication stored therein to the cores of the lower row. The same reset process naturally also takes place in the other time memories 132 to 135 . In addition, during this portion of the machine work cycle, any information present in the timing memory stages associated with output circuits 141 through 145 is effectively read and used to energize the output circuits in the manner described above. Like F i g. 12, switch 332 is preferably returned to its normal open position before switches 231 and 284 are returned to their normal operating position. The switches are therefore always operated with no load. F i g. 12 also shows the timing of the scanning process required to operate the entire control device. As shown, the gate photocell 56 is intended to be illuminated during the portion of the strip movement at a time that does not coincide with the actuation of switch 315 or switches 231 and 284.

As can be seen from the foregoing description, in a transfer printer such as printing press 20 , the control system of the present invention effectively controls several different machine functions in accordance with relatively simple key characters 48 (see Figs. 1 and 13), the key characters being those of the Transfer printers used printing types of printing forme 25 can be very similar. Control can be in accordance with virtually any logical function desired. This mobility is achieved through the combination of the contact desk 106 with the series of associated logic cores 121-125 . The use of a separate signal channel connected to the contact desk carrying a signal indicating the scanning of types in any of the key position positions, such as that of The core magnetization circuit 95 (see FIG. 5) is of great advantage for expanding the scope of logic functions which can be conveniently used on the contact desk 106. A complete compensation of fluctuations in the position of the key character is achieved by using an adjustable diaphragm 58 for the gate photocell 56 and also by using the synchronization storage stages in each of the nuclear magnetization circuits 91 to 95. The adjustable time memories according to the invention, such as the memory 131, enable the control system to be used in connection with control processes which, after the scanning process, require the initiation of any one of several time periods. These periods of time are measured in entire machine work cycles.

Claims (5)

Claims: 1. Control device for controlling the individual units of a printing machine for the production of impressions from changing printing forms, which carry key characters arranged in several lines, which can be read by signal transmitters responding to the key characters, with which the control of a specific individual unit are coupled to control elements, characterized in that at least two of the signal generators (91 to 95) excited by the key markings (48) of the printing formes (43 ) are combined with the electrical control element (121 to 125) to form a logic circuit. 2. Control device according to claim 1, characterized by an additional signal generator (95) which responds when reading a key character (48) in any of the lines in addition to the signal generator assigned to the line, with all signals emitted by the signal generators approximately equal to one another in amplitude and the control elements (121 to 125) become effective each time they are inputted with two actuating signals which are added together. 3. Control device according to claim 1 or 2, characterized in that each Control element through separate connections that can be made and locked as required (F i g.10, 11) can be coupled to each of the signal generators. 4. Control device according to claim 3, characterized in that the control elements (121 to 125) are memory elements which can be converted from a normal state into a memory state. 5. Control device according to claim 4, characterized in that each of the control elements (121 to 125) is a magnetic core storage element with a plurality of input windings (1 to 6) and an output winding (232, 7), which from a normal magnetic state to an actuated magnetic The state can be converted if two magnetically adding signals are input into the input windings, wherein means (262, 231) are furthermore provided to supply the magnetic core memory elements (121 to 125) with an interrogation signal, in response to which in the output windings (232, 7 ) of the magnetic core storage elements control signals are generated which indicate the magnetic state of the cores. Considered publications: German Patent Specifications Nos. 535 358, 558 781, 746 412, 971537; French Patent No. 1162 233; U.S. Patent No. 2,770,186.