DE887424C - Arrangement for comparing the information from recording media with different encryption - Google Patents

Description

(WiGBI. P. 175)

ISSUED AUGUST 24, 1953

/ 2op3 IXb 143 a

Sindelfingen (Württ.)

The task is to check information from recording media and to communicate with one another compare that differ in the type of encryption of their information. One is a pad z. B. a punch card, as used for punch card-controlled machines. The other one too The recording medium to be checked and compared is, for example, a punched tape whose Information is punched according to the five-digit Baudot or Telegraphy key. This is at telegraphic transmissions. Depending on the requirements, either the punched tape be punched for the reproduction of the same information under the control of a punch card, or the punching of the punch card is to reproduce the same information from the records of the Perforated tape emerged. This requires machines that are set up for both types of transmission are. In both machines, the created base, be it a perforated tape or an ao Punch cards, which reproduce the information of a guidance card, although these information in different Documents can also be reproduced in different encodings.

The hole testing arrangement according to the invention checks the correctness of the documents created in the hole

tape or in the punch card through an indirect comparison of the perforations in the punch tape with the holes in the card.

Given that the information in the Sample document and in the document created from it in different codes it is not possible to reproduce the information on the two documents - through a direct comparison for the presence of the same holes ίο. The object of the invention is in the creation of a test or comparison facility that records corresponding records, which are contained in the columns of two documents and the same information in different conclusions represent, checks for conformity.

In particular, it concerns the invention about scanning one of the documents, including its encrypted information and inserting it into the To transfer coding that corresponds to the reproduction of the other document.

Another feature of the invention is for an automatically operated hole inspection assembly in it, the corresponding columns of characters in two documents, the information in different Encryption included, to be checked and then automatically suspended with the check each time the information in the corresponding columns do not match.

According to a further idea of the invention, the two recording media are provided with records in different encodings then automatically each time by a column of characters in their sensing point passed on if the (test or comparison arrangements agree that the information in two corresponding columns.

The arrangement according to the invention advantageously includes one by that described above Test or comparison device controlled signal device that responds when a fault is detected, to interrupt the further testing of the machine.

The arrangement according to the invention is also set up in such a way that the test or comparison device and the means for the recording medium advance are then switched off each time or become ineffective if the sensing unit for the perforated tape has an inserted symbol for which no corresponding sign is present in the card. Characters inserted in this way are when using telegraphic punched strips, ■ used strip-controlled typewriters or to control other tape-driven writing machines. For this purpose, there are certain functional perforations required on the tape. This is, for example, the number switching, the letter switching, the carriage return, the line feed, etc., all of which are different functional works control of the printing or writing machine.

It is obvious that such information is not present in the punch cards, since these are for that purpose should serve to control booking engines. For this reason, the test work of the present Stop the machine if such signs are encountered.

A special embodiment of the arrangement according to the invention comprises a sensing unit for the punched cards into which the cards are inserted, to sequentially move to the columns with alphabetical and numerical records of the sensing undergo. The arrangement according to the invention also contains a sensing unit for the perforated strip, in which the gaps in the perforated strip are also successively opposed to the sensing means will.

The perforations on the perforated tape are encrypted using the so-called Baudot or telegraphy code. The punched tape sensing means selectively control groups of translator and distribution relays, with which 'the information in the Baudot key in corresponding information according to the Holler ith key for an immediate comparison with a setting under the control of the statistical map be recoded. The arrangement according to the invention also contains test circuits whose help compared the converted and translated character with the record of the card will. The test circuits are closed whenever there is a match in the records is present. In the event of a match, the machine automatically controls the perforated tape feed and at the same time move the punch card one column further.

Another one. The feature of the invention consists in the interruption of the test processes during sensing a key signal or the code, letters or numbers shift depending on the Character group (alphabet or number) to which the sensed data belongs, and depending on it on the condition of the circuits, so that an exact setting for checking such information comes about.

The arrangement according to the invention is characterized in that it automatically perforates Compares information in two documents in which the · representation of the information after two different key systems is made, and that the test procedures in automatic sequence take place without operator supervision. However, as soon as an error occurs, then the machine gives the operator something that is clearly recognizable Signal. By using this arrangement according to the invention, the accuracy of the machine product originally used as a sample or template to produce either a Check card or strip for punching. By using this machine according to the invention it is ensured that if the documents created are used again at a later date, exact results be achieved.

The invention is explained in more detail below with reference to the drawings for an exemplary embodiment. In the drawings is

Fig. Ι a plan view of the comparison arrangement, those in their upper part of the card sensing unit

and below shows the perforated tape sensing unit; both units are connected to the machine Cables connected;

Fig. 2 shows part of a punch card; from this card is the encryption of the perforations for Letters and numbers can be seen;

Fig. 3 shows part of a card whose perforations are to be checked, for example;

Fig. 4 is a. Part contains a perforated belt, the achricht a ίο X ^T in relation to the hole map different encryption; this should be compared with the recording on the card, checking the information in the corresponding card columns;

Fig. 5 is a part of a perforated strip, the key according to the Baudot system for special Shows characters, letters, numbers, punctuation marks and particular functions;

Fig. 6 is a cross section through the punch card sensing machine;

Fig. 7 is a section of the machine showing the coupling connection between the card carriage and the drive motor shows;

Fig. S is a section showing the indexing mechanism for the card trolley shows;

Fig. 9 is a section showing the jump magnet and the mechanism controlled by it for the Shows jumping of the cart;

Fig. 10 is a top plan view of the perforated tape sensing unit;

Figure 11 is a cross section taken along line 11-11 in Fig. 10;

Fig. 12 is a side elevation showing in detail the parts of the perforated tape sensing mechanism and some parts of the perforated tape feed mechanism shows;

Figs. 13 and 14 are partial views of various Elements of the perforated tape sensing unit in different work stages;

Fig. 15 is a timing chart of the cyclically operated Elements of the sensing unit;

Fig. 16 A, 16 B and 16 C when they are in the listed order are put together, the electrical circuit of the machine represent.

According to FIG. 1, the arrangement consists of two

Mechanically separated units: a card feed and sensing unit shown in the upper part of the drawing and a perforated belt sensing unit LbA shown in the lower part of FIG.

The cards to be filled or evaluated are inserted into the card magazine 10, from where they are individually passed through the card knife 11 to the left with their first column of cards to the sensing brushes 12 {Fig. 6) are introduced. In this position The card trolley, which contains a card pusher 13 and a front card guide 14, takes over, the card to be removed and pushes it step by step, controlled by the carriage guide mechanism, so that the columns of the card are sensed one after the other. The card slider 13 and the card stop 14 sit on the rack 15 of the card trolley (Fig. 1). The map knife 11 is arranged on the rack rail ιό. The rack 15 engages with its lower edge in a gear 17 (Fig. 1) and the rack 16 with its upper edge in a gear 18 (Fig. 7). This connection arises a movement of the card gripper 11 to the left (FIG. 1) and a movement of the card slide 13 with the card guide 14 to the right. At the beginning of the work game take the card knife and the card pusher is in the position shown in FIG.

At its extreme right end, the rack 16 is provided with a finger link 20 (Fig. 1), with which the rack 161 and the map knife 11 can be moved to the left in order to push a card from the magazine 10. The machine also contains, as will be described later, a power drive of the rack 16 to the left, which has the same effect as the manual movement through the phalanx 20.

In any case, the card pusher 13 has an opposite direction of movement. The parts are coordinated in such a way that when the card is advanced, the first column is up to the sensing brushes 12 'the card slide 13 to the right to has moved to engage the right edge of the punch card and now the further advance of the Card depending on the carriage stepping mechanism. A one-way clutch 21 (Fig. 7) enables the return controlled by a spring, not specifically shown the rail 16 and the edge gripper 11 after to the right.

The above-described mode of operation of the card guide is already known in the case of duplicating holes (cf. American patent specification J72, 186).

The motor 22 (FIG. 7) is arranged on the underside of the machine and is connected to a worm 24 (FIG. 6) via a shaft 23. The worm meshes with a worm wheel 24a which is seated on the shaft 246. At one end of this shaft a locking clutch 25 (Fig. 7) is provided. The gear wheel 26 is running loose on the shaft 24 b and meshing with the rack 16 on the shaft 24 b is located a disc 27 and on the disc 27, a clutch mechanism 28 that includes such a mounted pin 29 that a cooperation with a lever 30 is possible. This lever 30 ¹ can be controlled by the armature 31 of the magnet 32. When the machine is in the idle state, all parts assume the position shown in FIG. When the magnet 32 is excited, the lever 30 actuates the coupling mechanism and couples the disc 26 with the pawl 25 so that the gear 26 and the gear 2 <8 are driven clockwise and the rack ιό lead to the left. The clutch mechanism is arranged to remain engaged for one revolution. After completion of the rotation, the mechanism engages in a fixed member 33 which causes the parts to be disengaged. These sweep. so automatically with

Back to the position shown in FIG. 7 with the aid of a spring (not specifically shown). The machine Driving the rack 16 to the left has the same effect as driving the handle 20 by hand movement exercised, d. H. the card is advanced into the sensing position. It will then be dated there Detected slide 13, which takes over the further step-by-step feed. Following this runs the rack 16, without affecting the card feed and the slide 13, in its starting position return. This mode of operation comes from the arrangement of the one-way clutch 21 according to FIG. 7 conditions.

The armature 31 of the tripping magnet 32 also contains an arm 34 (FIG. 61), the free end of which with the middle contact spring of a contact set 35 and 36 has contact. With an excitement of the magnet 32, this arm 34 opens the contact 35 and closes the contact 36. By the locking lever 37 the contacts are held in this position. The side arm 38 of this angle lever is with a fixed on the gear 26 plate 29 in engagement. The intervention takes place at the end of the drive movement of the gear 26.

Contacts 36 are used to control excitation of the drive non-gate 22 is used. The tasks of these contacts and of contacts 35 will be explained in more detail in connection with the circuit.

As soon as the punch card has reached the sensing section above the brushes 10 (FIG. 6), the further advance of the card by the stepping mechanism controlled, which in turn works as a function of the magnet 40. When excited of the magnet 40 tilts the armature 41 in the clockwise direction. This takes the one on the pin shaft 43 arranged screw 42 against the tension of a spring 44 counterclockwise with. the Pin shaft 43 is pivoted with each feed step. Sitting on this pin at one end the arms 45 and 46 which spread out in opposite directions (Fig. 8). The arm

46 is equipped with a laterally guided pin which engages in an enlarged opening of the transport pawl 47, which is arranged on the shaft 43 so that it can easily be rotated. The opposite arm 45 is in engagement with the pawl 48 via a pin and slot connection.
When the shaft 43 deflects, the arm 46 lifts the pawl via the pin and slot connection

47 out of one of the incisions in the rod 15. At the same time, arm 45 brings the pawl 48 for engagement with the rack. In At this moment the spring 49 pushes the easily rotatable pawl 47 forward a little. this just enough to lift the pawl over the top of the next tooth. When lifting again the pawl slides the transport pawl 47 as a result of the movement of the rods 5 closest Tooth down until it reaches the end of the same and thereby locks the carriage. For the train the rod 15 to the right (Fig. 8) is the usual, but not particularly shown here drum spring intended. The structure of this arrangement of pawls and rack is known per se and should not be explained in further detail here. Sufficient for the present purposes it to know that for each actuation of the S'dhrittmagneten 40 the rack 1.5 a feed by a step or by a tooth learns and that thereby the card slide ί 3 as well as the front card guide 14 are taken. In this way, the card will be one too Step advanced if you consider the advance by one column of cards as a step.

The machine is provided with a normal jump rail 50 (Figs. 8 and 9). With this jump rail 50, those fields of the card which are not to be sensed and checked can be skipped. The jump rail 50 is inserted in the usual way on one side of the rack 15 of the indexing gear. It is provided with corresponding notches and cam surfaces that work together with the usual jump control lever 5 ¹ I, which has a beveled end 52. The end of de, s jump control lever 511 lies under the pawl 47 (Fig. 8), so that, after the lever 5.1 is guided to the left (Fig. 9), the beveled end of the rod is always gripped by the sliding surface of the rail when the elevated go part of the jump rail is at the same height. As a result, the end of the arm 51 and also the pawl 47 is raised. This leads to the release of the rack νζ and the card trolley. The jump control lever 511 then engages in the following incision in the jump rail 50, and the pawl 417 immediately interrupts the further movement of the rack. The task of the jump rail 50 is to jump over columns of punched card fields that are not to be sensed and also not to be checked. The right end of the jump control lift 5 ¹ I is provided with a slider 53, with which the free end of a lever 54 is guided. This lever forms a unit with the armature 55 of the jump magnet 56. The armature 55 is rotatable at the point 57. The excitation of the jump magnet 516 results in a lateral adjustment of the jump control lever 51 and the subsequent jump. When the magnet 56 is excited, the parts are returned to their normal position by the spring 58. Above the jump control lever 51 there is a pair of contacts 59 which are closed in the event of an engagement of the jump control lever 51 with the elevation of the jump rail 50. The purpose of this pair of contacts will be explained later in connection with the circuit.

Another means for the card advance can be controlled by the release magnet 60 (Fig. 6). The armature 61 of the magnet 60 is rotatable at the point 62. When the armature 61 is tightened, this presses free end of the finger lever 63 connected to the armature, a release button 64. The lower end the button 64 pulls the gear element 6: 6 in the event of its actuation via the angle lever 65 right (Fig. 6), which on its left side a

with the edge 68 of the plate 69 cooperating cam surface 67 includes. The link 66 is also under the jump control lever 51 (Fig. 9), so that when the part 66 moves to the right, the cam 67 associated with the edge 68 of the plate 69 causes the left end of the link to tilt upwards, which in turn causes the arm 511 moved upwards and the pawl 47 is lifted. As a result, the rack comes free and runs to the left without interruption. The engagement of the parts by friction keeps member 66 in its adjustment position, so that the stepping movement of the rack triggered by magnet 60 is not interrupted until the card has advanced completely, ie until the last column is brought into the sensing position. At this time, a corresponding protrusion of the rack engages a downward protrusion on the left side of link 66 and pulls the link back to the left to the position shown in FIG.

So, in a nutshell, the following results: After the card initially has a feed with their first column up to the sensing brushes 12 had received, the further column-wise feed is controlled by the step magnet 40. The The multi-column feed is controlled by the jump magnet 56 in cooperation with the jump rail 50. The complete release of the card from any position up to the last column position is triggered by the release magnet 60 controlled.

The sensing brushes 12 are shown in FIG. 6, namely, in their arrangement Fig. 6 shows twelve of these brushes side by side. For each of the usual twelve horizontal rows of metering points a brush is provided for the card. The sensing brushes 12 are in an insulated brush holder 90 housed, which is arranged so that when the brushes from the one shown in FIG Position vertically upwards, they touch the card and through the ones in the card Perforated electrical connections via the contact roller 91. The upward movement the brush Ί2 is driven by the sensing brush magnet 92 controlled. If this magnet is energized, then the brushes are generalized by one with 93 designated mechanism after just out. Such a mechanism is on known. This mechanism has the task of keeping the brushes in their lower position if no perforations are sensed to keep them that way from unnecessary wear and tear and protect against damage if the card is accidentally moved backwards. The anchor 94 of the magnet 92 opens a pair of contacts 95 when this magnet is excited and closes a pair of contacts 96. The functions of these contacts are explained in connection with the circuit.

In addition to the contacts already described, other contacts are also provided, In Fig. 8, a pair of contacts 145 is shown, which under the name over-travel contact or, last column contact is known. These contacts are made by an arm 146, which sits on the rack ί 5, closed. They are located so that when the carriage guide rack 15 is advanced into that position is, Λνο the last column of cards to the sensing brushes is opposite, the hook 146 closes the overstroke contacts 145.

In Fig. 8 contacts 149 are also shown, whose upper contact spring is switched by an arm 1150. This arm is around pin 43 loosely rotatable and has a lateral bulge which is located on the upper edge of the transport pawl 47 rests, so that when moving from one column to the other the associated lifting of the The pawl is transferred to the arm 150. This causes the contacts 149 to be lifted the latch open. Such contacts and the way they work are known per se and are called called vibrating cam contacts.

In Fig. 6, a card lever 157 is shown in the card path between the magazine and the Sensing position. When a card is fed from the magazine, it causes the deflection of the card lever 157 and thus the closure of the contact pair 156.

The card sensing unit is provided with a gap sensing of a known type. It can be seen from the _go Fig. Ι and ιό Β.

The brush holder of the column sensing device 1.65 sits on a protruding part 174 of the Card trolley. The sensing unit includes brushes 168, one of which is usually a conductive strip ί66 works together (see. Fig. 16 B). The other brushes work with separate ones Conductor segments' 167 together. In well-known -Wise the brushes connect 1168 one after the other during the column-wise forward movement of the card carriage, the contact segments 167 with the Contact strip 165.

Before the general operation of the machine and the Loehbandabfühlemheit is explained in connection with the circuit diagram, the various possible punching options in a column of the punch card C to be checked are discussed below. The card usually has twelve counting point positions in which numbers are represented by a hole in the corresponding number counting point position according to FIG. This card shows the number and alphabet key for punching numbers and letters. The card C shown in Fig. 3 has perforations, which as an example a message n DAR set _5. This card can be used in a machine according to the American patent specification 2 430 801 to control the perforation of the perforated strip shown in FIG. In the opposite case, the machine shown in American patent specification 2 430 8Ι0Ό can be used.

The alphabetic characters are represented by the combination of two perforations. One of these perforations is found in the sub-hole zones ι to 9 and the other in the so-called over-hole zone o, ii, 12 or o, X ₁ R. A fully

The following table contains a permanent overview for the encryption of the alphabet.

22-1 Table ι Z-i S. 0-2 A. R-2 J X-2 T 0-3 B. Ä-3 K X-3 U 0-4 C. R-4 L. Z-4 V 0-5 D. R-5 M. X-S W. 0-6 E. R-6 N X-6 X 0-7 F. R-7 O X-7 Y 0-8 G R-8 P. Z-S Z 0-9 H R-o Q Z-o I. R.

The punch card shown in FIG. 3 and provided for sensing contains perforations in columns 11, 2 and 3 corresponding to the number 123. In columns 5 to 13, the name Jon Jones is entered in coded cursive script. If the column ι of the punch card is under the sensing brushes for the purpose of testing, the corresponding column of the perforated strip is also in sensing position. If the perforations in the card and the perforated tape match, both recording media are automatically advanced by one column. This is repeated for the following columns. It does not matter whether the perforations contain numerical or alphabetical information. This is how the testing process takes place in the machine. However, before the electrical circuits that trigger this operation are described, the perforated tape sensing unit will first be shown below. 4 and 5 each show a telegraph perforated strip 225 with the guide perforation 226 and the text perforation 227. The perforated tape 225 runs from a feed roller 228 according to FIGS. 10 and 12 and passes under a guide roller 21219 via a perforated tape guide lever 230 between the separate blocks 231 and 232 through over a sprocket 233 and under a guide roller 234 through to the take-up roller 235. The sprocket 233 is provided with normal sprocket teeth Move in the direction indicated by the arrow. The sprout wheel sits on a shaft 237 which is held by a side plate 239 a and a toe plate 239 b . A ratchet wheel 238 is attached to the shaft 237. The ratchet wheel 238 is set in rotation step by step by a spring-actuated pawl 240 (Fig. Ί «ι) which is rotatably mounted on a cam lever 241. The cam lever 241 sits on a shaft 242 which is carried by the side and toe plates. A ratchet lever 243 is also arranged on the shaft 242, which, when triggered, allows a cam roller 244 arranged on the cam arm 241 to slide over the circumference of a continuously rotating cam 2145 and follow the cam outlines. The outlines of the cam 245 are designed so that the cam follower arm 241 and the pawl 240 rotate partially in the clockwise direction when the locking lever is released during the cam revolution. Spring 246 does this. Here, the pawl comes into a position above a tooth of the ratchet wheel, in which, when the cam elevation, the cam arm and the. Forcing the pawl in a counter-clockwise direction will move the ratchet wheel forward one step. The fixed plate 247, which sits on the side plate 239 a, is provided with a cam surface into which the free end of the pawl 240 engages when the pawl is urged in the counterclockwise direction. will. In this way, a positive drive connection between the pawl and ratchet wheel is created. Over-turning of the ratchet wheel is also prevented. The usual spring-operated locking lever 248 cooperates with a ratchet wheel 249 which sits on the shaft 237. It holds the shaft 237, the ratchet wheel 238 and the sprocket wheel 233 in the advanced position.

With the mechanism just described, the perforated tape 225 is used in every machine game advanced by one step so that the next row of holes then reaches the sensing elements. A sensing element is provided for each hole. This is the respective sensing pin 250 (FIG. 12) which has a recess 251. For each Each of these five sensing pins has a special passage in the U-shaped guide block 232. The pegs are attached so that each one of them is appropriately arranged with Contact means 352 can work together.

Five sets of contacts are provided for the present exemplary embodiment. from only three sentences are visible in FIG. 12. The remaining two sentences are behind. Everyone Kit contains an elongated leaf spring that plugs into the insulated end of the associated feeler pin intervenes. When the sensing pins of Fig. S are in the retracted position, so will these springs are pushed so far to the left that they open the contacts 252.

The mentioned recesses of the sensing pins also include an adjustable hook blade 253 seated on the shaft 254. The shaft 254 is mounted in the side plate 239 a. On it sits a three-armed lever 255, which has the shape of an inverted T, the left arm 255 a of the three-armed lever 255 is provided with a cam roller 256 as shown in FIG. 1: 1, which cooperates with the continuously rotating cam 2.57. The upstanding arm 255 & the inverted T-lever carries a locking lever 258 which is held in a counterclockwise direction by the spring 259 so that the stop 260 mounted on the pawl lever normally engages the upper end of the upward arm of the lever 255 (see also Figs. 13 and 14). The extreme end of the right arm 255 c on the lever 255 (Fig. 11) is normally pressed by the spring 361 against the upper edge of the locking

plate 262 pushed. This plate is seated on the induced armature 264 of the locking magnet 263. In this way, the reverse T-lever is held in the in Fig. Shown in normal position. Normally, the locking lever 243 is held in the raised or locked position as shown in the drawing. This is done by means of the rotatable locking lever 258. As a result, the perforated tape feeder pawl 240 remains in the uppermost position shown in FIG. When the inverted T-lever is in its normal position just described, the working cycles of the cams 245 and 257 do not have any controlling effects on the corresponding cam arms 241 or 255 a . In the aforementioned normal position of the inverted T-lever, the hook 253 is also moved to the left in the extreme position shown in FIG normal open position.

At the time of excitation of the blocking magnet 263, the armature of this magnet is attracted and the blocking plate 262 is pulled away from the arm .2: 55 c, so that the lever 255 is released. By the influence of the spring 261 it is printed in a clockwise direction (Fig. 13; and caused, firstly as a result of the retraction of the locking lever on arm 255 b the solution of the locking arm 243, secondly the solution of the arm 255 c, whereby an effective cooperation between the cam 257 and cam roller 256 and thirdly, due to the rotation of hook 1253, which is partly clockwise, the release of sensing pins 250.

When releasing the ratchet arm 243, the cam arm 241 makes during a working cycle of the Cam 245 a partial rotation first in a clockwise direction and then in the opposite direction Clockwise direction. This causes the ratchet wheel 238, the shaft 237, and the sprocket wheel 233 advanced by means of the pawl 240 so that the perforated tape is pushed forward by one step and the next row of holes with holes in front of the feeler pins.

Upon release of the sensing pins 250, the perforations are sensed by the pins. Here the spring-loaded pins penetrate through the perforations of the perforated strip and get into appropriately provided slots or openings in the block 231. They pass through the perforations penetrating pins hereby close the associated contacts 252. In this way groups of encrypted pulses in the circuits connected to contacts 252 become triggered for control purposes.

During a working cycle of the cam 257, the lever 255 rotates first in the clockwise direction and then in the counterclockwise direction. When the highest part of the cam 257 comes into effect, the lever 255 is pressed in the counterclockwise direction, in such a way that the arm 25'5c is lifted over the unlocked locking plate 262 (FIG. 14) and thereby the lever 255 in the normal position locks. During the working cycle of the cam 257 and the partial rotation of the lever 255 and the shaft 254 in the counterclockwise direction, the hook 253 is returned to its normal position. In the course of Rückfü'hrvorganges the recesses of the shifted Abfühlstifte 250 come to engage and retract from the perforations of the perforated belt, so that the pins themselves and the associated contacts return to their normal position ⁷ ^. The sensing pins ¹ and the contacts remain in this position as long as the lever 255 is held in the blocking position.

The continuation of the perforated strip described above must be prevented until the effective sensing of the perforated strip and the return of the pins is complete. In the present In the event of this, it is advantageous to stop the perforated tape feed until the sensing pins come back are locked in their normal position. Accordingly, the cams 245 and 257 are arranged so that that the raised part of 245 for the locking of the lever 255 takes effect before the cant of 257 the activation of the strip transport pawl 240 (see cam diagram in Fig. 15) accomplished. For this reason, the locking lever 258 is set up rotatably on the arm 255 ο. After the lever 255 has been returned to the normal position shown in FIG. 14 and before the elevation of the cam 245 comes into effect to move the ratchet arm 243 into its locking position to lift, the rotatable locking lever 258 strikes the end of the pawl arm 243 and is of there returned only by the spring 259 in the locking position when the latch arm 243 over the Lever 258 is lifted. In this way, the perforated tape transport process only takes place after the Sensing pins are withdrawn from the perforations of the perforated strip and are withdrawn in this Position are locked. It should also be noted that a rotatably mounted return lever 265 is provided which returns the locking plate 262 to its normal position with positive movement when the arm 255 c is raised.

10 and 11, the cams 245 and 257 are mounted on a shaft 266. A worm wheel 267, which meshes with a worm 268 continuously driven by the motor 269, is also seated on this shaft 266. In this manner, when the control magnet 263 is energized, the cams are continuously operated to control the sensing and tape transport operations. If necessary, the cams 270 and 271 attached to the shaft 266 are used to control the various circuits. These control the corresponding contacts Ci, C2 and C3. Furthermore, a corresponding friction drive is provided for the take-up roller 235. This contains a drive wheel 272 on the shaft 266, which is connected to the intermediate wheel 274 via a belt 273. This wheel

274 ^{rests on} the shaft 275, which also carries the wheel 276, which in turn is connected to the wheel 277 on the shaft 278 of the take-up roller by a belt 279.
According to FIG. 12, further circuit-controlling means in the form of contacts 280 are provided. These contacts open when the perforated tape feed to the sensing pins 250 has expired. A perforated tape guide lever and the angle lever 282 are seated on the shaft 281, which is mounted in the side plate 239 α contacts 280 opens. However, this movement does not occur if the feed of the perforated tape from the magazine roll 288 is not exhausted, since the perforated tape then runs over the guide lever 230 and thereby holds the guide arm and the pin 284 in the position shown in FIG. Furthermore, an arcuate and slotted perforated tape guide piece 285 is provided, with which the perforated tape presses on the sprocket 233. The perforated tape guide piece sits on the shaft 286, which is mounted in the side plate 239 α. In addition, a depending lever 287 is seated on the shaft 286 and engages in a spreading spring 288. The lever 287 can come into engagement with a pin 289 (on lever 282) whenever the guide piece 285 is lifted by hand, e.g. B. during the introduction of a new perforated tape. He then rotates the angle lever 282 and the perforated tape guide lever 230 in a counterclockwise direction and thus facilitates the insertion or removal of the perforated tape. In order to ensure the synchronous work of the elements described, the cam-controlled contacts Ci are provided in the circuit leading to the S expensive magnet 263. In this way it is ensured that regardless of the times at which the pulses are impressed on the circuit for the magnet 263, the magnet for the unlocking of the lever 255 is only energized at predetermined times during each revolution of the cams 245 and 257, such as this from the cam diagram of FIG. 15 emerges.

FIGS. 16 A, 16 B and 16 C show one another put together the circuit of an exemplary embodiment according to the invention, on the basis of which the operation of the individual units, which have already been described, below be explained.

It is assumed that the perforated tape 225 is properly inserted into the filling unit and that the first column of the punch card is in the sensing position. It is also assumed that 'the first part of the perforation in the perforated strip i, 2, 3 means John Jones , and that the order is correctly switched by the plug connection 302 from the column ι of the column sensing device 165 to the starting switch socket (Fig. 16B). The scanning and checking of the correspondence of the loc'hings between the punched tape (in the telegraph key) and the punched card start automatically when the first column of the card arrives at the scanning station.

Under the above-mentioned conditions and when the locking contacts 35 and the oscillating cam contacts 149 are closed, a circuit is established from the line 200 via the aforementioned locking contacts 35 (Fig. 16 B), via the oscillating cam contacts 149, the line 202, the sensing start relay i? 5, the relay contacts R 1 b, which are now closed, are closed via the contact segment 167 of column 1, via the brushes ¹ 168 and via the contact strip 166 to the line 203. In this way the mentioned relay is energized. It will be recalled that when a card is in the sensing position, the card lever contacts 156 (FIG. 16A) of the sensing unit are closed. This closes a circuit from line 200 via blocking contacts 35, line 201, via contacts 156 and relay Ri to line 203. The relay R 1 closes its holding contacts Ria in order to expand the holding circuit to the power 201. The relay R1 thus remains energized until the blocking contacts 35 open while the checked card is being ejected. At this time the relay contacts Rib are closed to enable the sensing start relay R 5 to be energized.

When the cyclically operated cam contacts C 3 (Fig. 16 A) are closed, a circuit is created from the line 201 via the cam contacts C 3, the now closed relay! Contacts R 5 a, the coil of the relay R 2 to the line 203. The holding circuit for this relay is formed back to the line 201 via the relay contacts R 2 α and the following, now closed relay contacts: R6c, i? 54a, R ^ a, R ¹ Sa, R7b; from there the current runs via the stop button contacts 305 and the perforated tape-controlled run-out contacts 280. This holding circuit is maintained until one of the normally closed contacts in the circuit opens.

At the end of each working cycle of the sensing unit, the cam contacts C 1 are closed. Since the contacts Kzb are also closed, a circuit is closed to the pawl magnet 263, which starts from the line 201 via the cam contacts C 1, the relay contacts R 2 b and the pawl magnet 263 to the line 203, so that the magnet is excited and the sensing elements 250 become effective. It should be mentioned that the said cam contacts C 1 are opened and closed during each working cycle in order to trigger an immediate excitation of the latch magnet 263. The timing of the sensing unit is coordinated so that. no working game, the same goes to an end before the card feeling for each column has ended.

It was assumed that the first three characters of the information punched in the litter was the

belong to numerical data group. As can be seen from FIG. 4, this information is encrypted Perforation number switching ahead. During the first working cycle of the sensing elements and on the sensing of the mentioned perforation number switching are now the i-, 2-, 4- and 5 contacts 252 closed.

When the cam contacts C 3 (FIG. 16 A) are closed, circuits are closed via the cor. Clocks 252 for selective excitation of the encoding relays Rg, Rio, Rn, R12 and / Y13. This takes place as a function of the respectively closed contacts 252, which are closed in accordance with the perforations of the perforated strip. The excitation circuit for the encoding relay runs from line 200 via locking contacts 35, line 201, cam contacts C 3, via the aforementioned sensing contacts 252 and via the encoding relays or converter relays Rg to R13 to line 203. In this way the said relays are energized. As can be seen from the middle part of FIG. 16A, these relays switch their corresponding contacts in the encoding circuit, so that the distribution relays R 14 to 14 44 optionally receive current. Correspondingly, when the number perforations are being sensed, the associated contacts R 9 a, Rioa, R 12 b and i? I3c are switched over in order to select a circuit to a distributor relay. This is closed when the cam contacts C 2 close. As can be seen from Fig. 15, the cam contacts Cz are closed at the time when the cam contacts C 3 are closed. The circuit runs from the line 200 via the locking contacts 35, line 201, cam contacts C 2, via the now switched contacts R 9 a, via the now switched contacts R ι ο α, the contacts 7? 11 a, the now switched contacts R 12 b and the now switched contacts R 13 c to the coil of the digit switching distribution relay R18 to the line 203. The aforementioned relay is energized. The holding current for this relay runs from the line 203 via the relay R 18, the corresponding holding contacts h, via the normally closed relay contacts R14α of the letter relay R 14 to the line 200. This holding circuit is maintained until the normally closed contacts Open R 14 α of the letter relay R 14.

From the lower part of FIG. 16A it can be seen that the contact group R 18 α to Ri8m inclusive is switched over by the excitation of the relay R 18 and that these contacts remain switched.

Since the holding circuit for relay R 2 (FIG. 16A) is still closed, relay contacts R 2 also remain closed. When the perforation digit changeover is sensed at the end of the work cycle of the perforated strip sensing unit, the contacts C 1 close again in order to transmit an impulse to the locking magnet 263. The perforated tape sensing unit then comes into operation for the second machine game and moves the perforated tape so that the next hole gap, which is the number 1 in the example of FIG. 4, lies on the sensing pins. Since 1 perforations in the hole positions 1, 2, 3 and 5 for displaying the digit, causes the closing of the equally designated Abiühlkontakte252 dieErregung the Umschlüsselungsrelais Rg, Rio, Rn and R 13 turn These relays their corresponding Umschlüsselungskontakte in the above-described Recoding circuit to. When contacts C 2 close, distribution relays R 16 are energized via the selected circuit. The relay R 16 closes its corresponding holding contacts h and is held via these contacts h, conductor 202, via the oscillating cam contacts 149, the locking contacts 35 and the line 200. This holding circuit remains in place until the oscillating cam contacts 149 open in the next card sensing passage. The relay R 16 closes its corresponding contacts R16 α and thereby creates a circuit from the line 200 via the locking contacts 35, the oscillating cam contacts 149, conductor 202, the relay contacts Ri6a, via the now switched contacts RiSh to the i-line of group 307, from there via the corresponding comparator relay 2? i £ 1 (FIG. 16 B), via the now closed contact 96 of the sensing brush magnet to be described later, via the normally closed relay contacts i? 48 α, the normally closed switching contacts 116 to line 203. The groups of comparator relays labeled RKi to RKg are optionally excited in accordance with ■ the numerical perforation of the perforated strip.

In summary, it should be noted that the digits are shown on the perforated strip in a combination or the Baudot telegraphy key, that they are recoded and finally are reproduced by setting a single comparator relay RK. As a result of this conversion, the numerical recordings shown in the perforated tape are converted into a relay setting that corresponds to the statistical key of the punched cards. ■

Before the electrical comparator or test circuits are explained and described, it should be pointed out that after each evaluation of a column of columns representing numbers or letters in the perforated strip, an optional 1 setting of the relay RK takes place. The armatures of these relays drop out again after use for the test if the distribution relays R 14 to R 44, through which the setting was controlled, drop out. In the example of FIG. 4, the hole column representing the number 2 is sensed as the next column. The conversion relays Rg, Rio and R 13 receive power. The distribution relay 2? 20 is excited via the Umschlüssdungsstromkreise and selects the comparator relay RK2 . This work cycle is then used for the following hole column of the hole

band, which represents the number 3 in the example, is repeated. 3 is represented by a perforation in the i position which, after being sensed, ultimately leads to the excitation of the comparator relay RK 3.

It has been explained that after one of the distribution relays R 14 to i? 44 has been energized, the holding current for that relay is maintained via the oscillating cam contacts 149. These contacts open when the trolley advances to the next column, which is triggered by circuits that are yet to be explained. This interrupts the holding current and the distribution relays R 14 to R 4.4. returned to the de-energized state. You are ready for subsequent excitement. The switching off of a distribution relay leads to the opening of the excitation circuit for the selected relay RK, whose armature then also drops out. Of course, relay R 18 remains energized as long as numeric characters are sensed. This excitation circuit runs via the contacts R 14a of the letter relay R 14, which keeps the contact group i? I8a to RiSm switched until the alphabetic characters are sensed. The contacts R 18 η remain open while the numerical data are being sensed, so that the excitation of the relays RKR ₁ RKX and RKo via the closure of the relay contacts for the energized distribution relay is prevented.

The optional excitation of the comparator relays RK has been explained for records representing several digits. It is not necessary to describe them for all digits. The relays excited for the remaining digits, which trigger the optional excitation of a comparator relay RK , can be taken from the following table 2:

Table 2

Punched

Number in

Perforated tape

I.
2

3
4th
5
6th

7th 8th

9
0

Aroused
Conversion relay

Rg, R 10, R 11, R 13

Rg, R 10, R 13

Rg

R xo, R 12

R 13 ■
Rg, R 11, R 13 Rg, R 10, R 11 R xo, R 11 R X2, R 13 22 10, R 11, R 13

Aroused Aroused Distributor Comparator relay relay Rt6 RKx R 20 RK 2 R 2g RK 3 R 35 RK 4 R44 RK 5 R 24 RK 6 R 17 RK 7 R 33 RK 8 R 42 RKg R 32 RKo

When following the circuit for the excitation of the comparator relay RK it can be seen that such a circuit runs through the contacts 96 which are now closed. From Figure 6 it can be seen that these contacts are closed when the sensing brush magnet 92 is energized. The circuit for the excitation of the magnet 92 in the cards sensing machine runs as follows: From the line 200 via the locking contacts 35 (Fig. 16 B), via the conductor 310, the now closed relay contacts R 47 a for the last column, via the Now as a result of the excitation of the card lever relay R 1 when the card enters the sensing section, the relay contacts Rib closed, via the normally closed relay contacts R 52 b, the sensing magnet 92, the controlled contacts 109, via the normally closed switching contacts 116 to the line 203. These contacts 109 close when the machine is set for card sensing. As a result of the excitation of the magnet 92, the brushes 12 are guided upwards into the contact position for sensing the first column of cards. At the same time, the contacts 96 close so that the comparator relays RK receive power.

In FIG. 16B the relays RC o to RCg and RCX, RCR represent the card-controlled comparator relays. These are selectively energized under the control of the card perforations, regardless of the position of the columns of the cards being scanned.

As a result of the excitation of the magnet 92, the brushes 12 come into contact with the card, so that when a brush 12 encounters a perforation, the corresponding comparator relay RC is energized.

The excitation circuit runs from the line 200 via the pawl contacts 35, via the oscillating cam contacts 149, via the usual contact roller 91, via a perforation in the sensed card column, via the corresponding brush 12, the corresponding comparator relay RC and via the now closed contacts 116 to the line 203. Since there is a perforation in the counting point 1 of the first sensed column in the example chosen, the comparator relay RC ι is energized.

The test circuits are shown in the upper part of FIG. 16C. The relay magnets RK contain sets of contacts which are specially designated by an additional index a, such as RK 9 a, RK 8 α, etc. The second and third sets of contacts are identified by the additional index b and c . The contacts controlled by the relay RC are also indicated in FIG. 16C. There are b, c, d and e contacts for each of the relays RC. For example, if the relay RC 9 is energized, it opens the contacts RC 9 b and closes the contacts RC gc. Also when energized, the relay RCg closes the nc contacts RC gd and opens the contacts RC ge. The fr and c contacts of the magnets RC are indicated next to the corresponding b and c contacts of the associated magnets RK. They are wired in such a way that normally a series circuit extends over the fr contacts of the two magnets RK and RC , which is identified by the same numerical designation. The lower test circuit begins with contacts RK 9 b and runs via contacts RC 9 b, RKSb, RCSb, RK 7 b, RC 7 b etc. via contacts RC 0 b to a so-called 0-9 test relay .R49. This series circuit is controlled by the RC and RK magnets ο up to and including 9. The RC and RK magnets X and R and their fr contacts control, as in the upper right corner of Fig. 16C

can be seen, a separate upper test circuit , which leads from the contacts RKXb via the contacts RC X b, RK R b, RC Rb to a second so-called Ä "i? -Prüfrelismagneten R 50 .
The c-contacts of any associated magnet pair RK and RC are wired so that it comprises a shunt circuit via the corresponding / 'with simultaneous excitation of the magnet RK and RC - close contacts. If, for example, the magnets RK 9 and RC 9 are excited, the series circuit runs from the contacts RK 9 c to the contacts RC 9 c and from there to the contacts RK 8 b and further, as described above, to the 0-9- Test magnet R 49. The second circuit for the Xi? Test relay R 50 runs in the same way with simultaneous excitation of the magnets RKX and RKR via the contacts RK Xc and RCXc. It is apparent that if any of the obtained magnet RC or RK at non-simultaneous excitation of the corresponding magnet or RC RK current, the circuit for the test magnet R49 and R 50 is not closed. If such a mismatch occurs, a circuit for the excitation of a fault relay R 6 is closed. Assuming the case that the magnet RK 9 is excited without the corresponding magnet RCg also being excited, a circuit is created from the contacts RK gc via the contacts RC ge to the magnet R6. If, conversely, the magnet RCg receives current without simultaneous excitation of the magnet RKg, a similar circuit is established from the contacts RKgh to the contacts RCgd and to the fault magnet R6 .

The same applies to the arrangements of the magnets RK and RC for the 11 and 12 or the X and i? Positions. If the magnet RKX receives current without the magnet RC X being excited at the same time, a circuit is created from the contacts RK X c via the contacts RC X e to the magnet R 6. If the magnet RCX is excited without the magnet RKX being excited at the same time, it runs a circuit from contacts RKXb via contacts RC X d to magnet R 6.

Briefly summarized, it can be said of the operation of the test or tuning circuits that they are controlled by the relay RK, which is optionally energized under the control of the conversion and conversion means. The test circuits are further controlled by the relays RC , which are optionally energized, controlled by the sensing means of the card. In the test and tuning circuits, there is a current path to the relays R 49 and R 50 when the corresponding magnets RK and RC are energized or when none of them is carrying current. If one of the magnets RK or RC is excited without the associated other magnet carrying current, the current path for magnet 49 or R 50 is interrupted and a current path to the fault magnet R 6 is present.
In the further course of the operation of the machine, when the first card column has a perforation and when the corresponding perforated strip column also contains a 1, the two magnets RK 1 and RC 1 are excited. A complete lower test circuit now runs from the line 200 via the jack contacts 35, conductor 310 (FIGS. 16B and 16C), via the contacts RK1 a, the fr contacts of the non-excited relays RK and RC to the contacts RK 1 c and the now switched contacts RC ι c, via the now closed contacts RKob and RC whether to the take-up coil of the relay Ä49, via the conductor 312, the contacts R 48 a, the contacts 116 to the line 203. A parallel circuit extends from the contacts RKi α (Fig. 16 C) via the fr contacts in the upper test circuit to the excitation coil of the relay R So and via the conductor 312, the contacts R 48 a (Fig. 16 B) and via the contacts 116 to the line 203. In this way by the sensing of a Loc'hung 1 in the card C and through the simultaneous sensing of a one performing holes on a perforated band, the excitation of the two test relays R 49 and i? 5o is achieved. For the sake of simplicity, the wiring to the excitation and holding coils of relays -R49 and i? 50 is shown separately in the circuit diagram. On the other hand, however, it is shown in FIGS. 16B and 16C which coil in the circuit is the pickup coil and which is the holding coil. Therefore, when the excitation coil of relay i? 49 receives power, it closes its contacts i? 49a (Fig. 16B), thereby creating a circuit across the holding coil, which is fed from line 200 via locking contacts 35, via conductor 310, to the Conductor 314, conductor 315, the holding coil of relay R 49, contacts R 49 a, contacts R 48 α and contacts 116 to lead 203. Similarly, the excitation coil of i? 50 closes contacts R 50 a to energize the hold coil of relay R 50 through a similar circuit. According to FIG. 16C, each of the relays /? 49, R 50 and i? 6 is provided with a fr contact pair, of which the contacts R 6 b are normally closed and the contacts 2? 49 b and R 50 b are both closed when both relays are energized. The simultaneous excitation of both relays is a measure of the correctness of the test process. A circuit is then closed from line 200 via jack contacts 35 (Fig. 16B), conductor 310, via contacts R 49fr, R50b, RGb, via stepping magnet 4 and via ejector relay R 56 to line 203. At the same time, the stepping relay magnet R 53 receives power via a shunt circuit. Although the contacts R 56 α now close, they cannot close the circuit in which they are in series because the contacts 145 in the last column are now open and, furthermore, as long as the contacts i? 53a (Fig. 16B) are closed, no circuit to relay R 54 is closed at this time since the circuit is held open by column sensing 165. The energization of the magnet 40 affects the indexing mechanism for advancing the card to the next column. Here, the stepping pawl (Fig. 8) instantly opens the contacts 149 (Fig. 16 B;. During the time in which this

Contacts 149 are closed, there is a circuit from the line 200 via the locking contacts 35, via the oscillating cam contacts 149, via the coil of the relay R 51 and via the contacts ir6 to the line 203. In this way, the relay coil R 51 is energized. If the oscillating cam contacts 149 are open, the relay magnet R 51 is de-energized. This closes the contacts R 51 a, so that the following current flow to the relay R 48 results: From the line 200 via the locking contacts 35, via the conductor 310, conductor 314, conductor 315, via the relay contacts R 51 a, the relay magnet R48 and via contacts 116 to line 203. The magnet R48 opens its contacts R 48 a to switch off the excitation circuits for the test magnets. R49 and R 50 .

During the stepping movement of the card trolley, the opening of the oscillating cam contacts 149 also opens the exciter circuit for the relays RK and RC . In addition, the holding circuit 202 for the selected distribution relays R 14 to R 44 is disconnected. The armature of the distribution relay now drop and open their α-contacts in the excitation circuit of the comparator relay RK. The functions described above are repeated when checking the card columns 2 and 3 of the card shown in FIG. 3 and the corresponding columns of the perforated strip shown in FIG. If it is now found that the columns corresponding to one another have the same information, the perforated tape is advanced to the next column. The punch card is advanced in the same way. After the card column, in which the number 3 is shown, has been sensed, the card moves into the advance position for column 4, but where there is no perforation in the card. The relays RC are not energized at this point. At the same time, the corresponding gap in the perforated strip 225 according to FIG. 4 is sensed. There is a perforation in key position 3, which means that the R11 encoding relay receives power. This switches the R1 1c contacts over, so that the contacts Riid continue to be switched over.

When the cam contacts C 2 are closed, a circuit is closed via the conversion circuit to the feed relay R 41 (FIG. 16 A). This closes the contacts R 41 fr and forms a circuit from the line 200 via the locking contacts 35, via the oscillating cam contacts 149, the conductor 202, the contacts R 41 fr, via the conductor 3116 (Fig. 16 A, 16 B and 16 C in that order) to conductor 311.

From there the circuit runs via the fr contacts of all RK and i? C relays to relay 2? 49 to excite, and via the fr contacts of the relays RKX and RKR and via the relays RC X and RCR to excite the test relay R 50. Both relays receive power provided that no punch holes are sensed in the corresponding column of the card. As a result of the current connections described above, the stepping magnet 40 is energized, and the card moves to the next column layer 5, where the letter / appears. The perforated tape also moves to the next column position in which the letter switching is recorded.

Since a perforation appears in each code layer to indicate the letter switching, the coding relays R 9 to R 13 are energized. They switch their contacts so that a current path to the letter relay R 14 (Fig. 16 A) closes within the encoding circuit. The relay R 14 closes its Ä-contacts for a holding circuit back to the conductor 202. The relay R 14 opens the contacts R 14a to open the holding circuit for the numeric switching relay R 18 and thus to close the contacts R 18 η. The relay contacts R 18 α to Ri8m are now returned to their normal position (Fig. 16 A below). When the machine senses the encrypted letter switching recording, none of the relays will be energized. The test circuit is therefore not closed either, since none of the α-contacts of the RK relay is closed (FIG. 16 C) and since no pulse is transmitted to the stepping magnet 40. Thus, the card carriage remains in the card column position 5 for the scanning of the first alphabet character /. However, the cam contacts C1 _go transmit a pulse to the latch magnet 263 to the hole band advance to the next column. The perforated tape sensing means now sense the column in which the alphabet character / is shown encoded by the perforations in the code layers 1, 2 and 4.

The test circuits for checking the alphabetical punchings in these card columns are set up as follows: It is assumed that the first letter / word John, which is punched in both the perforated tape column and in card column 5 of the punch card: is to be tested. The character / is shown in the perforated tape through the perforations in code layers 1, 2 and 4. The metering point positions X and ι are perforated in the map. Sensing the perforation in the card causes the relay magnets RCX and RC 1 to be excited. Sensing the perforations in the code layers 1, 2 and 4 of the perforated strip causes the Rg _1, R 10 and R 12 relays to be activated Relay contacts around, so that a current path for the excitation of the relay R 19 (Fig. 16A), which represents the setting of the letter / is formed. The relay R 19 closes its contacts and forms a holding circuit via these contacts, via the conductor 202, via the oscillating cam contacts 149, the locking contacts 35 to the line 200. The relay coil 19 closes its α-contacts and forms a circuit from the conductor 202 via the Contacts Riga, via line 1 of group 307, via the comparator relay RKi (Fig, 16B), via the now closed relay contacts 96, relay contacts R4 & a and contacts 116 to line 203. Distribution relay R 19 also closes its fr contacts, so

that now an additional circuit via the conductor 202, via the now closed relay contacts Ri8n, via the now closed contacts R 19 b and via the conductor 318 to the comparator relay RKX (Fig. 16 B) comes about. The remaining current path is the same as that just obtained for the comparator relay RK ι. At this point in time, the comparator relays RK 1 and RKX and the comparator relays RC1 and RCX are energized.

In general, the wiring arrangement of the a and 5 contacts of the distribution relay and the RK comparator relay corresponds to the information on the encryption table shown above. The comparator relays RK are then excited in combinations that correspond to the encryption. Each distribution relay belonging to an alphabetical character selects a comparator relay RK 1 to RKg through its α-contacts. Each of the distribution relays also selects a relay RKo, RKX and RK R according to the key through its ^ contacts.

In the example adopted, the magnets RC ι and RK 1 open their RC 1 b, RK 1 ö contacts (Fig. 16 C) in the lower test circuit, which is closed by the closure of the contacts RC1 c, RK1 c , so that the simultaneous closing of the contacts RK1 α forms a circuit via the test relay R 49. In the same way, the relays RCX, RKX in the upper test circuit open their contacts RC X b, RKXb in order to interrupt the circuit formed by the closing of the contacts RC Xc and RKXc , so that the simultaneous closing of the contacts RK Xa excites the second Test relay i? 5o comes about. The excitation of the two relays R 4g and R 50 leads to the formation of a circuit for the excitation of the stepping magnet, whereby the card carriage is fed until the next column is on the sensing brushes 12. Since the pulse circuit to the locking magnet 263 still exists, the contacts C 1 transmit a pulse to this magnet, whereby the perforated strip is advanced into the sensing position for the next column.

In cases in which the alphabet character to be tested consists of a combination of the perforation ο and any number perforation, the C-magnets concerned open the lower test circuit at two points. The contacts RC ο b open, and if, for example, the second perforation is in the 3 position, the contacts RC 3 b also open. The relevant contacts RK form the circuit again at these two points when the corresponding iC magnets are excited as a result of the sensing of the perforations in the perforated strip, which represent the same symbol. In this case, the first and second test relays are i? 49 and R 50 via the contacts and RKoα rxn ₁ O, excited. After the first column, containing an alphabet character, has been checked, the next corresponding columns of the perforated tape and the punch card follow. The further tests are carried out in the manner just described. Such work cycles are repeated until a point is reached at which the machine work proceeds differently. This is described in detail below.

It is evident from the foregoing that when the perforations in the sensed card columns match the characters shown in the corresponding perforated tape column, a C-magnet or C-magnets are excited. In addition, the corresponding iv magnet or ii magnets is excited. In the case of a blank column on the card and a space bar on the perforated tape, none of these magnets is excited. In both cases, the two test relays .K49 and R ζο, which control the advance of the card and the perforated strip in the sensing position for the following column, are excited. If, however, there is no match, ie if either a K or a C magnet is excited without the corresponding other magnet being excited at the same time, either only one or both relays R 49 and R So will not be excited, so that the stepper circuit cannot be closed and the fault circuit excites the fault relay R6 via the d or c contacts of the C magnets. When the field winding of this relay carries current, its contacts R 6 α close (Fig. 16 B). This means that the holding coil is excited and held in the same way as the holding coils of the magnets R 49 and R 50. At the same time, a lamp 171 lying parallel to the holding coil lights up and indicates to the operator that there is an error in the arrangement of the perforations the card or the perforations of the perforated tape is present. If an error is found, the checked column is not continued, but remains in the sensing position. The lamp 171 continues to burn so long. According to FIG. 16 A, the relay R 6 opens its relay contacts R6c and these in turn open the holding circuit for the i? 2 start-up relay. The relay R2. becomes de-energized and opens its contacts Rz b. This opens the pulse circuit to the pawl magnet 263 and the perforated strip is no longer continued.

The pressure against the finger piece 110 (FIG. 1) interrupts the holding circuit for the signal lamp 171 and the relay R6. By means of special connections, when the handle 110 is operated, the interrupter contacts 116 (FIG. 16 B) are opened and the circuits are returned to their initial state. After the operator of the machine has determined an error, he can start the test process again by pressing the start button shown in FIG. 16A. The start button closes its corresponding contacts for a pulse transmission via the C3 contacts to the start relay R 2 ·.

If, in the assumed example, the map column 14 shown in FIG. 3 is checked and with the corresponding perforated tape column, which contains an S, has been compared, then the card trolley receives a feed up to column 15, in the one

Perforation in meter point X, which is the only perforation in this column, triggers the trolley to jump. The perforated strip (FIG. 4) is also pushed forward into the next column position. This column contains the recording of digit switchover in hole letters. As a result of the perforated tape sensing, the relay R 18 is energized in the manner already described. This sets the test circuits for testing the following numerical information. It should be remembered that relay 2? 18 is set. The perforated tape is advanced to the next column position in order to sense the character & or the large alphabet character G. However, there is no advance of the card trolley, since this is not a test process. The card trolley remains in its old position for further sensing of the card column 15. When the card trolley is in the column position 15, perforations in the key positions 2, 4 and 5 are sensed, which represent the character &"or the capital G. The encoding relays, R12 and R12, are energized to switch their corresponding encoding contacts and thereby a To create a current path for the excitation of the distribution relay R 34, which belong to the characters G and & The relay R 34 closes its contacts α, so that a circuit results from the line 202 via the contacts R 34 a (FIG. 16A ) and via the switched contacts RiSc to relay R 7 (Fig. 16B). As soon as the card carriage has entered the position of the card column 15, it closes a circuit via the brush 168 of the column sensing with the contact 167. The circuit is therefore from the relay R 7 extended via the switching connection 320, via the contact points 167, via the brush 168 and via the contact strip 166 to the line 203. The relay Ry then closes its contacts and thus a circuit from line 200 via contacts Ry a, conductor 321, which can be seen from FIG. 16B and is connected to comparator relay RK X , and via sensing brush contacts 96, via relay contacts R 48 ,, contacts 116 to Line 203. As soon as the card trolley has reached the position corresponding to column 15, the brush 12 (Fig. 16 B) at point Z a circuit to relay RC X is established . This is done via the perforation in meter point X of the card, which closes circuits that have already been described for the excitation of other comparator relays. The excitation of the relay RC X takes place in the same machine aisle in which the characters G or & were sensed in the perforated belt.

The relay RK X closes the contacts RK Xa (Fig. 16 C) and thus the lower test circuit for the excitation of the relay R4g. The simultaneous excitation of the relays RK X and RC X - the upper test circuit for the excitation of the test relay i? 50 closed. The relay RK X also closes its contacts RK Xe (Fig. 16 C). This means that a shunt circuit also receives electricity. The shunt circuit runs from relay R 49 via conductor 322, via contacts RK Xe ₁ via conductor 323, relay R 52, conductor 324, conductor - 312 and back to the other side of relay i? 49 - relay R 52 closes the Contacts i? 52ß (Fig. 16C). The circuit thus closed for the holding coil of relay R 52 leads from line 203 via this holding coil of relay R 52, via contacts R 52 a, conductor 325, via the closed relay contacts R 51 α (the cause of the closure of these contacts is explained below still discussed), via the conductor 315, conductor 314, conductor 310 and via the interlocking contacts 35 to the line 200. From Fig. 16C it can be seen that the jump magnet 56 is connected to the holding coil of the relay R 52. This jump magnet is now live. It is assumed that in the current position of the card gap the spring rail is provided with an X-part which can engage in the lifting arm (FIG. 8). With the excitation of the jump magnet, the lifting arm 51 is switched. The card trolley is triggered and can now move without interruption as far as the X part of the jump rail extends.

Since both test relays R 49 and R 50 are energized during the test, the circuit for the stepping magnet40 closes. This magnet actuates the transport pawl 46 for triggering the carriage guide rails 15. The transport pawl opens the contacts 149, whereby the relay R 51 drops out. This closes the contact R 51 α of the holding circuit explained above for the holding coil of the relay Ä52 and the jump magnet 56. With the opening of the oscillating cam contacts, the upper and lower test circuits are also separated, with the result that the test relays R 49 and R 50 will be de-energized.

The relay R 52 now opens its contacts R 52 b (Fig. 16B below), so that the ¹ contacts of the discharge brush magnet fall off and the brushes are separated from the cards during the jumping process. The holding current for the holding coil of the relay R 52 keeps the relay contacts R $ 2ib and thus your circuit for the sensing brush magnet open. This ensures that the sensing brushes are kept away for the duration of the jumping. n ₀

The arrangement according to the invention contains special devices for the interruption of the perforated tape feed during the jump triggered by the character X in the card. These devices can be controlled by the relay Ry. The relay Ry is energized when the card carriage has reached the position corresponding to column 15 and when the characters G and & in the perforated strip are sensed.

From Fig. 16A it can be seen that the relay R 7 opens the contacts Ry b and in this way interrupts the holding circuit for the starting relay R 2. When the armature of the relay R 2 drops, the contacts R 2 b open and prevent the cam contacts C1 from transmitting further pulses to the locking magnet 263. The

The perforated tape feed is therefore interrupted until the card column 24 appears. In the example chosen, the X part of the jump rail enables a card trolley jump from column 15 to column 23. The card trolley is held in the position corresponding to column 24. The transport pawl 47 of the indexing mechanism then moves into its normal position (FIG. 8). In addition, the oscillating cam contacts 149 also return to their normal, closed position. This means that all circuits are now in the idle state again. The perforated tape feed starts again as soon as the card trolley has reached the position corresponding to column 24. A circuit is then closed from line 203 via column sensing 165 (FIG. 16B), which is now on column 24, and via switching connection 327 to one of the starting sockets. The further course of the circuit for the excitation of the Abf ühlanfangsrelais R 5 has already been described. The machine is now set and ready for further perforated tape sensing processes. Columns 24, 25 and 26 are checked in the manner already indicated. After checking the column 26, the perforated tape is advanced by one column step. In the column 26, the perforation 4 is included.

The card-sensing machine is provided with a jumping mechanism of a known type, in which the jumping through the elevated part of the jumping rail is triggered. This ^ embodiment differs from the X-ge controlled form of jumping. In the present machine, it is necessary that the feed of the perforated tape is interrupted when jumping over the card fields when the raised part of the jump rail 50 comes into engagement. Assuming that the map columns 15 to 23 are to be skipped under control of the elevated part of the jump rail, a circuit connection, not specifically shown, would be laid from column 14 of sensing 165 (Fig. 16 B) to one of the switching sockets, high rail part . A circuit to the relay i? S4 is then closed with this card column position. The relay i? 54 opens its contacts R 54 a and thereby causes the start-up relay R 2 to drop out, whereby the further perforated tape feed is interrupted. After checking column 14, the carriage moves into the position corresponding to column 15, where the control system starts through the high rail part and lets the card carriage jump to the column where the high rail part ends. The perforated tape feed is resumed via the switching connection 327 already described.

In order to determine whether all the work of the perforated tape and card sensing units is carried out in accordance, so-called column test circuits are provided. This can be used to determine whether the card trolley is in the correct column position after checking the details of a previous row of holes in the perforated strip. This is achieved through the use of an encrypted carriage return mark in the perforated tape. The carriage return mark always follows the last information in a row of information perforated in the perforated strip. The symbol must appear every time the card trolley has reached a predetermined position. In the case of the example, column 2y is this position of the cart, which has been determined in advance. In general, you choose the column that follows the last punched information column on the punch card.

When the perforation of the carriage return in the perforated strip is sensed, the 4-way sensing contacts 252 (Fig. 16 A) close and cause the R12 to be energized. When the cam contacts C 2 are closed, a circuit is made from the line 200 via the locking contacts 35, the conductor 201, via the aforementioned contacts C 2, via the normally closed contacts Rga, R lob, Rn d, R 12h (now switched), via the normal position contacts R 130 to the Ci? distribution relay i? 43 and to the line 203 are closed. For the relay holding 43 immediately comes g ₅ circuit via the contacts i k, via conductor ^202: about the swinging cam contacts 149, via the locking contacts 35 to the line 200 about. The closure of the Relaisikontakte R 43 a (Fig. 16B) allows the formation of a current g ₀ circle from the line 200 via the lock contacts 35, via the conductor 201, via the closed relay contacts R 43 a, via the relay coil R 55, about one of the switch sockets test last columni, via the switch connection 328, via gs the contact segment 167 for column 27, via the brushes 168 and via the contact 166 to the line 203. This energizes the relay Ä55 and a holding circuit from the line 200 via the Ver - 'locking contacts 35, the line 201 and via the contacts i? 55 α produced. It can be readily seen that the relay R 55 cannot receive any power at this point in time if the card carriage is in a position other than that which corresponds to column 27. After energizing relay Ä55, relay contacts R 55 b (Fig. 16B) close and contacts 7 - 55 c open for the following control:

After the carriage return character has been sensed, a line feed character follows (FIG. 4), no which, when sensed, causes the Rio encoding relay to be excited via the 2-way sensing contacts 252. When closing the cam contacts C 2 is a circuit from the line 200 via the lock contacts 35, the conductors 201, the contacts C2, which is now closed relay contacts Rg a, via the switched-over relay contacts R 10 b and from there via the normally closed contacts R1 1 c, Ri2J, .R131 to -LF distribution relay'S i? 37 and closed to line 203. This energizes relay R 37. The usual holding circuit leads for the distribution relay via contacts R 37 h. A circuit from the line 200 via the locking contacts 35 to the line 201 is. via the relay contacts i? 37 a (Fig. 16B), via the switched relay contacts

R 55 b and via the coil of relay R 4 to line 203. The holding circuit runs via the contacts R 4 d, via the oscillating cam contacts 149 and via the locking contacts 35 to the line 200.

The described holding circuit for the relay R 2 is interrupted by the opening of the contacts R4a (FIG. 16A). This in turn opens the circuit to the locking magnet 263, so that further sensing and feeding of the perforated strip is temporarily interrupted.

The closure of the relay contacts 4 c (Fig. 16B) is a circuit from the line 200 through the contacts R4c, via the conductor 329 (Fig. 16B, 16 C) and over the release magnet 60 to the line 203 into existence. As has already been described with reference to the figure, this release magnet releases the card carriage for an uninterrupted movement to the left up to the position that corresponds to the last column. When the relay contacts R 4 b (FIG. 16 B) are closed, the circuit from the line 200 via the conductor 330 to a connection side of the carriage guide magnet 40 (FIG. 16 C) and to the stepping magnet relay i? 53 is closed. The further course of the current leads from the other side of the two relays via the pick-up coil or excitation winding of the ejector relay R 56 to the line 203. The ejector relay R 56 controls the ejection of the cards.

The excitation winding of relay R 56 closes contacts R $ 6a. When the cards dare has reached the position corresponding to the last column, the contacts 145 close so that a circuit is established from the line 200 via the contacts 145 of the last column, the switch SW 2 and via the holding coil of the ejector relay R 56 to Line 203 forms. The holding circuit runs via the holding contacts R 56a and via the contacts 145 'back to the line 200. When the relay contacts R 56 α close, the relay R 47 in the last column also switches on the holding coil of the ejector relay R 56. The relay R 47 now switches the contacts R4ya (Fig. 16B) and thus opens the sensing circuit for the brush magnet. The brush magnet 92 and the brushes 12, which are now detected by the contact roller 91, fall off. At the same time, the contacts 95 close and the contacts 96 open. When the contacts 145 in the last column close, an electrical circuit comes from the line 200 via the "contacts 145", via the switch SW 2 to the ejector magnet 79 and finally to the line 203 conditions.

With the excitation of the ejector magnet, an ejector finger is actuated, 'which the front edge the card is detected and the card is swiveled into the card tray. This mechanism is known per se. It causes the contacts to close

84 for automatic start. These contacts are used to complete a circuit brought about by the line 200 via the contacts 145, via the contacts.84, via the tripping magnet 32 and via the contacts 95 to the line 203. The excitation of the trip magnet 32 causes the locking contacts 35 (FIG. 16B) to open and the Contacts 36. Here, the contacts 36 close a circuit from the line 200 via the contacts 36, via the conductor 331, the motor 22 (FIG. 16 C) and via the contacts 95 to the line 203. When the release magnet is actuated, the drive clutch is automatically engaged, so that by the work of the motor the next card from the magazine 10 into the sensing position is brought. Furthermore, the storage grippers are returned for the storage of the next card.

It has already been mentioned that the oscillating cam contacts 149 are opened when the card carriage makes a jump to the position of the last column, -and, as is known per se, are kept open until the card carriage is again in the position of the first Column is located. The opening of the cam contacts 149 leads to the interruption of the holding circuit to the distribution relay 2? 36 and to the column checking relay R 4. The machine is now returned to its normal position and set for automatic perforated tape sensing and card checking. This work begins, as already described. when the following card is in the position of the first column and the perforated tape moves to the first column of the next information.

If, as a result of the sensing of the line feed character, the card carriage would not be properly on memory 27, then a circuit would start from the line 201 via the contacts R 37 α (Fig. 16 B), via the normally closed contacts Ä55 c and via the coil of the Relay 2? 3 to line 203 close. In this case relay 2-3 is energized. The contacts Rz a (FIG. 16 A), which are in the holding circuit for the relay R 2 , would be opened, interrupt the holding circuit and prevent further excitation of the holding magnet 263.

From the upper part of Fig. 16 C it can be seen that the relay R 3 its contacts J? 3 fr closes, and that there is a circuit from the line 200 over the 'interlocking contacts 35, over the conductor 310, the relay contacts R ^ b, over the fault relay R 6, over the conductor 312, over the closed relay contacts R 48 α and over the contacts 116 to the line 203 establishes, whereby the relay R 6 is energized and the error lamp 171 lights up. From this it can be seen that if the perforated tape sensing and the position of the card carriage do not match, the further perforated tape sensing and supply are interrupted until this inconsistency is corrected by the operator. In order to be able to take the card out of the machine by hand when errors are found, the machine is provided with a release button 131 which, when pressed, closes its contacts 131 o- and 131 &> (FIG. 16 C) and thereby a circuit of the line 200 via the contacts 131 b - and the release magnet 60 for

Line 203 forms. There is also a parallel circuit. comes about, which leads from the line 200 via contacts 131a, via the carriage guide magnet 40 and via the ejector relay R 56 to the line 203. The magnet 40 and the ejector relay R 56 cause the card to be ejected in the manner described above.
For the purpose of the investigation, the perforated tape can be carried out from the perforated tape sensing unit by means of several successive perforated tape feed work cycles. Here, the perforated tape feed is triggered by pressing the start button (Fig. 16 A), whereby the relay R 2 is energized via a special circuit and the successive perforated tape feed processes are initiated. If an error is detected or if the associated columns in the perforated tape and the card do not match, the perforated tape can thus also be advanced for the purpose of the investigation.

Claims (7)

Patent claims: i. Arrangement for comparing the data on different recording media, in particular Punch cards and punched strips, contained information of different encryption, thereby characterized in that the encrypted information of a recording medium after their scanning into that corresponding to the encryption of the recording medium to be compared Key values are transferred. 2. Arrangement according to claim 1, characterized in that that the recording media to be compared automatically experience a feed by a column distance if after the Recoding of the information on a recording medium in the key of the information of the other recording medium the information of their to be compared and corresponding Columns match. 3. Arrangement according to claims 1 and 2, characterized in that the comparison process automatically suspends when the information of a recording medium with the re-encoded Details of the other recording medium do not match. 4. Arrangement according to claims 1 to 3, characterized by one of the comparison organs Controlled signaling device that is triggered if the information does not match and interrupts the further comparison process. 5. Arrangement according to claims 1 to 4, characterized in that the comparison organs and the device for the advance the recording medium to be compared become ineffective each time the sensing unit for the one recording medium, e.g. B. a telegraph strip, an inserted Function character senses, for a corresponding character in the other recording medium does not exist. 6. Arrangement according to claims 1 to 5, characterized in that the recoding the records of one recording medium in the key of the information of the other Recording medium is carried out with the help of a relay circuit. 7. Arrangement according to claims 1 to 6, characterized by the connection of a punch card testing machine with a punched tape testing machine, -that via an encoding device are controllable in the feed movements of their recording media. For this purpose 3 sheets of drawings I 5334 8.53