DE910968C - Arrangement for checking the correct deletion of arithmetic units - Google Patents

Description

(WiGBI. P. 175)

ISSUED MAY 10, 1954

I 2867 IXb142m

Sindelfingen (Württ.)

In the case of the known calculating machines, in particular in the case of booking machines controlled by recording media, the offset is written algebraic sums automatically, whereupon the arithmetic units are deleted or returned to the basic position. These machines contain a device for group control through which a change in the sequence the group-wise ordered recording media determined and this accordingly the write process with subsequent deletion is initiated.

The machines work extremely precisely when performing the tasks set, and yet an incorrect circuit connection can be made on the switchboard by mistake or a connection is omitted, so that .the deletion of the arithmetic unit or a or several of its positions cannot take place. However, this leads to the implementation of the next invoice task with an incorrect result. An incomplete deletion of the arithmetic unit can also be caused by mechanical defects that occur rarely, e.g. B. Wear or inaccurate setting of some parts may be justified. The one required for bookings and invoices However, accuracy requires that an error in the deletion or resetting of the arithmetic unit

is displayed in order to be able to eliminate the cause of the error.

The arrangement according to the invention achieves this in that after the deletion of the Arithmetic unit a test device is effective, which the position of the returned to the basic position Elements of all arithmetic units determined and, if the reset is incomplete, at least a counter initiates a second machine game to repeat the writing of the totals, in which both the deferred and the not deferred arithmetic logic unit digits are written. With this second total notation, the not deleted positions of the arithmetic unit become easy recognizable, since a zero is written through all deleted positions in the arithmetic unit. To the Ensuring that the machine is working properly is ensured when a group change occurs »0 and the resultant writing of the sum Feeding of the recording media to a following group interrupted and only started again, after the arithmetic units have been deleted and all arithmetic unit wheels have been returned to their basic position. However, if even one position has not been deferred, the feed will be resumed the recording medium prevents the machine work from continuing and a signal is triggered, to indicate this error visually or acoustically.

The test device is under the direct control of the arithmetic unit wheels in its basic position, in which a contact device becomes effective, via which an at the end of the deletion process periodically triggered test pulse is conducted.

Further features of the invention emerge from the exemplary embodiment that is described in connection with a tabulating machine known per se is described with reference to the drawings. It shows Fig. Ι a partial view of one of the magnetically controlled clutches,

Fig. 2 is a view of the left side of the card sensing device,

Fig. 3 is a plan view of the drive connections ♦ 5 to the main shafts and their coupling connections,

4 shows a plan view of the drive of the transport rollers,

Fig. 5 is a right side view of the card sensing device;

Figures 6 and 7 are partial elevations of the two sensing stations and the card magazine and the stacker,

Fig. 8 shows a D up of the two sensing stations, 9 is a partial plan view of the entire card sensing system;

Fig. 10 is a partial elevation showing the rocker arms for reciprocating the sensing lever support;

Fig. II is a partial elevation view of the drive wheels and pen sensing devices;

12 is a view of the pen carrier lifting device;

13 is a detailed view of the sensing devices with the pins raised;

Figure 14 is a detailed view of the sensing devices with some countersunk and through the holes feeler pins kicked on the card,

Figure 15 is a detailed view of the sensing devices with selected ones passed through the holes Pins, of which the first three pins are already through the contact lever with regard to their Position are checked,

16 shows a record carrier;

17 shows a partial view of the card discarding container;

18 shows a counter with the start and stop magnets and the transfer contacts, 19 a counting wheel in the coupled position, FIGS. 20 a to 20 e the circuit diagram of the machine,

21 a to 21 d the timing diagram of the cam contacts,

Figures 22a and 22b are a side elevation of a location of the writing mechanism and the converter for converting the combined hole impulses that are sent out by the extraction device,

23 shows a side view of the drive for the shafts shown in FIGS. 22 a and 22 b.

The card evaluation device, which in connection with the group control device used in the embodiment of the machine according to the invention is known and will be not described in detail.

The recording media C (FIG. 16) are individually removed from a container and fed to two sensing stations arranged one behind the other, in which they are stopped and their encrypted perforations are electromechanically sensed. The two sensing stations are essentially the same and are referred to as upper and lower stations U and L, respectively, by means of which the group control is carried out in a known manner in order to check whether the successive recording media belong to the same or to different groups. The first sensing station U is known as a control station, while in the sensing station L the value perforations are sensed and the pulses triggered thereby are transmitted to counter and write control magnets. "O

Each sensing station contains a set of vertical sensing pins, one of which is an index point assigned to the card. The pins are usually held on hold until a card is inserted is the sensing position. Then the pins are lowered so that some of them go through holes in the Card can be kicked while the others remain raised over the unperforated parts of the card. Three contact levers work together with the heads of the pins in each column, which are divided into three groups, whose cam-shaped nose is guided over the heads of the seven associated pins. if a pin is lowered, the contact lever can move and close a contact. The contact levers are attached to a common frame that goes back and forth, which

times lowering the pens is moved over the pen carrier.

In the sensing station U there are three sets of contact levers, one each for the pins of one of the three zones of the card. The other station L contains an additional fourth contact lever set, which performs a sensing function in order to trigger the so-called late five-pulse. This arrangement is by design

ίο the arithmetic and printing works justified, the z. B. for the addition of a 9, request the distribution of one or more impulses over a period of time, which is greater than the one between encryption settings 5 and ο in the one used Seven-point wrench. Therefore it is provided that when adding a number greater than 5, two contact levers working together in sending out the pulses to introduce this number. This not only applies to the two left contact

ao lever (Fig. 6), which work together on one side of the sensing station, but all four Contact lever sets work together for the so-called earlier or late five-value values. at the introduction of the values work z. B. the first and second contact levers, the second and third and the third and fourth together. It follows that the contact lever of the outer The only purpose of sentences is to introduce either early or late values during the two sentences the inner or middle contact lever in cooperation with two sets of sensing pins one have a double task. Since the invention does not relate to the introduction of items, this is only generally described.

The equipment of the machine rests on a base plate to which the side frames 26, 27 (Fig. 4) are attached. Two foot pieces 28 and 29 (FIGS. 6 and 7), in which most of the lower feed rollers are mounted, are fastened between the side frames. The clutch magnet for the electromagnetic clutch is attached to another cross rail 33 (FIG. 1). Near the front end of the frames is a cross bar 35 (Fig. 1) which carries the contact members of the circuit breakers.

About the drive devices are two pivotable units, one of which is the Most of the sensing devices, the other the stacker drum and the receiving container wearing. These two units are stored so that the first is below the second, and if both are swiveled out of the working position, access to the inside of the card feeder is open, in order to be able to make adjustments, replacing parts or repairs. If the Parts are to be returned to the normal working position, first the frame of the filling device lowered and then swiveled the forklift frame over it and locked in the normal position.

The frame of the filling device contains two strong side plates 38 and 39 (FIGS. 2, 5) which are rotatable about pins 40 on the outside of the main frames 26 and 27. Springs 43 attached to pins 42 in the short ends of side plates 38 and 39 are not strong enough to swing the discharge device clockwise to the open position, but serve only as a counterweight to prevent the discharge device from falling back too quickly. The second end of the springs is hooked into the side frames 26 and 27 on pins 44. Auxiliary side frames 49 and 50 (FIGS. 2, 5) are attached to the side plates 38 and 39 in an electrically insulated manner by means of rivets 46 (FIGS. 8, 12) and insulating sleeves or insulating washers 47. The removal device is electrically isolated from the rest of the machine by means of the intermediate insulating layers 52 (FIG. 12) and 53 (FIG. 8) inserted between the frames 38 and 49 or 39 and 50. Suffice it to say at this point that the oscillating frame with the sensor device, that is to say with the sensor pins, the contact levers and the contacts actuated by them, lies directly above the card. Pivoting the device frees access to the card path and, if there is any fault in it, the inserted card can be removed or repairs can be made to the feeder devices without dismantling any parts.

Between the pivotable side plates 38 and 39 is a plate 55 (FIG. 7) mounted with an inclination angle of about 20 ^0, which forms the front wall of the card shoe M. The slot through which the cards removed from the stack run one after the other can be adjusted by means of a rail 56 arranged below the plate 55.

The bearings 61 and 62 of the shaft 63 of the card stacker are carried by side plates 58 and 59 which are fastened to the frame plates 26, 27 by means of screws 60 (Figs. 2, 5, 9). On the freely rotatable about the shaft 63 plates 65 and 66 (Fig. 5) by means of spacers 67 and 68 (Fig. 9) grooved rails 69 (Fig. 5) and 70 (Fig. 2) are attached, in which the movable card pressure plate 71 is performed. The pressure plate 71 rests on the uppermost surface of the stacked cards (FIG. 2) and is pushed slowly to the right along the inclined path determined by the grooves in the rails 69 and 70 as the cards continue to be stacked. A base plate 73 (FIG. 2), on which the cards rest with their lower edges, is attached to the underside of the running rails 69 and 70. The base plate 73 is attached at its left end (FIG. 6) to a cross rail 74 which connects the two side plates 65 and 66 for the purpose of stiffening the storage device.

The individual devices, mainly the 12a card transport and dispenser, are built in such a way that they are suitable for installation in various types of machines, namely in any machine that is controlled by recording media. The one from the card feed shaft 109 clockwise

driven gear ι ίο (Fig. 3) engages in the Main drive shaft 112 fixed gear in a. A gear 113 attached to the shaft 112 within the frame 26 meshes with one Intermediate gear 114, which is located around a frame 26 attached bolt 115 rotates and with the gear

116 is engaged on the shaft 117. The wave

117 is mounted in the main side frame 26, 27 and carries at its left end outside the frame 27 three cams 118, 119 and 120 for controlling associated contacts. A clutch drum 125 which is freely rotatable on the shaft 117 is connected to the shaft 117 when a stop is actuated in order to release a card for transport after it has been scanned in the lower scanning station L. So when a card is released for stacking, not only is the stop lowered, but the stacker drum is driven by the clutch via a gearbox in order to deposit the card in a manner to be described below. A gear 126 (FIG. 3) is connected to the clutch drum 125 and meshes with a gear 127 fastened to a shaft. A gear 129 seated at the right end of the shaft 128 meshes with an intermediate gear 130, to which a smaller gear 13.1 is connected. The two gears 130, 131 rotate loosely around a bolt 132 in the side frame 26, and the gear 131 (see also FIG. 5) meshes with a gear 134 attached to the shaft 63 of the forklift drum SD rotated clockwise so far that it can pick up a card and place it on the stacker plate 73 during one revolution of the clutch drum 125.

The shaft 112 carries a freely rotatable clutch drum 140, by means of which the stop for stopping the card in the upper sensing station U is controlled in a manner similar to how the stop in the sensing station L is monitored by the clutch drum 125. Two complementary cams 142 and 143 (FIG. 3) are connected to the clutch drum 140, by means of which the card knife is moved back and forth in order to individually guide the recording media out of the storage container. A third cam connected to the clutch drum effects a control via a card lever which will be described later. In addition, a gear 144 attached to the clutch drum via a gear pair 146, 147 rotatable on the pin 148 and a gear 149 drive the shaft 150, which carries cams for opening and closing the cam contacts P, which monitor the general working conditions of the machine.

On the shafts 112 and 117, two further coupling elements 153 and 156, respectively, are fastened in a freely rotatable manner, which control the raising and lowering of the sensing pin carriers. A cam 154 is fixedly connected to the coupling spool 153 and raises and lowers the pen carrier in the upper sensing station U with each revolution of the coupling. The cam 157 connected to the other clutch drum 156 raises and lowers the pen carrier in the lower sensing station L with each revolution of the clutch.

Two more on main drive shaft 112 Outside the right main side frame 26 attached cams 162 and 163 (Fig. 3) are used for horizontal movement of a frame that carries the contact lever, which over the heads of the raised or lowered feeler pins slide to sense their setting.

In Fig. 4 is a plan view of the drive of the transport rollers which transport the cards one after the other from right to left from the container to the stacker. The gear 111 on the shaft 112 meshes with a gear 165 (FIG. 4) which is connected to a gear 166 by a hub 167 which is loosely rotatable on a pin 168. This gear wheel meshes with two gear wheels 170 and 171, of which the first is the shaft 173 with the rollers 174, 175 and via the gear wheels 172 and 184 the shaft 178 with the upper rollers 176, 177 of the first pair of rollers immediately in front of the card holder M drives (Fig. 5). The gear wheel 171 transmits the drive to all transport rollers on the left, which guide the card to the stacker.

The shaft 173 (FIG. 4) is journalled in the main side frames 26 and 27, while the shaft 178 rotates in arms 179 and 180 which are pivotable about pins 181 and 182 in the side frames 26 and 27 and are thus influenced by springs 183 be that the transport rollers 176 and 177 are pulled against the rollers 174 and 175 and can grasp the card. The rollers 174 to 177 guide the card removed from the container to a first pair of sliding rollers 191, 192 by which it is guided against the first stop. After the card leaves the container M and the first set of rollers, it is advanced through six sets of rollers in succession before it is gripped by the stacker drum. The upper rollers are pressed by springs against the lower rollers of these six roller sets, which are carried by the shafts 190, 193 to 197. The shaft 190 of the first lower rollers 191, 192 is driven by the gear 166 via the gear 171 and rotates like the other five shafts 193, 194, 195, 196 and 197 (Fig. 4) loosely in bearings in the two main side frames 26 and 27. To these shafts, gears 199, 201, 203, 205 and 207 are attached, which are driven by intermediate gears 200, 202, 204, 206 and 208, which rotate loosely on pins in the frame plate 27. The shafts 193 to 197 carry the lower pairs of rollers 211 and 212, 213 and 214, 215 and 216, 217 and 218 or 219 and 220. The upper rollers are supported by pivotable arms 223 (FIG. 11) and lightly counteracted by weak springs the card lying between the rollers is pressed, so that a frictional contact is created which can advance the card, but does not exert any significant force on a card when it is held by a stop.

The cards are inserted into the container M upside down and with the lower edge as the leading edge. The end wall 55 fixes the starting position of the cards, and two guide rails 235 (FIG. 5) attached to the wall 55 serve to fix the cards laterally in the container. The lower part of the container contains a plate 236 (FIG. 7) which is secured between the main side frames 26 and 27. A carriage 243 is guided in suitable grooves in this plate 236 (FIGS. 7, 9), to which a block 246 carrying the adjustable map cutters 245 is attached. The bottom of the container M is inclined at 20 ⁰ to the base so that it forms an angle of 90 ⁰ to the end wall 55 DES container. The undersides of the carriages 243 are designed as toothed racks that mesh with a corresponding toothed sector 265 or 267 that sit on the shaft 266. The arm 270 fastened to the shaft 266 is connected by a link 271 (FIG. 1) and the pin 272 to a lever 273 rotatable about the shaft 274, the rollers 275 and 276 of which cooperate with the cams 142 and 143 fastened to the clutch drum 140 . When the clutch is engaged to lower the first stop for feeding cards, the cams 142, 143 rotate and pivot the lever 273 clockwise, and via the link 271 the two sectors 265 and 267 are rotated counterclockwise to advance the carriages 242 and 243 and the associated knives 245. This pushes the bottom card through the slot of the container M until it is gripped by the first set of guide rollers 174-177. The slot or card neck is determined by the adjustable, already mentioned plate 56 and a roller 279 (whose axis is parallel to the lower edge of the plate 56. The plate 56 is attached to a cross rail 280, which is arranged independently of the end wall 55 and removably so that it and plate 56 can be quickly removed if any cards are stuck in the neck of the card.

The roller 279 (FIG. 7), which determines the base area of the card neck, rotates in a plate 281 which is guided in ribs 282 (FIG. 9) of the magazine casting body 236 and is adjustably fastened by screws 283. The card led out of the magazine M is grasped by the first pair of rollers 174 to 176 and is passed on between two guide plates 285, 286 (FIG. 7). The guide plates 285 and 286 have cutouts through which the guide rollers can pass for cooperation, and are attached to the plate 281 or the cast body 236 and inclined at an angle of 20 ° relative to the horizontal card path through the sensing device. A card lever 298 (Fig. 2,7) mounted on a shaft 299 is normally held in a position in which the sliding block 300 is at the upper end of the lever

. located below the card track. During operation of the machine, the lever 298 can move counterclockwise as a result of a recess in a cam 250 (FIG. 2) of the coupling 140 and the shoe 300 can rotate through an opening in the guide plate 286 into the card path when it is not off a card which is on the way from the container M to the first sensing station is prevented from doing so. The axle 299 protrudes beyond the left frame 27 (FIG. 2) and carries an arm 251 which keeps a contact 252 closed. If the lever 298 is not depressed by a card, the lever 251 opens the contact 252 to cause the machine to stop.

As it passes through the machine, the card is stopped both in the sensing station U and in the station L in order to be evaluated by the sensing pens. Since the two devices for stopping the cards are the same, the description of the device in station U is sufficient. The devices contain a stop rail 311 (FIG. 6) or 310 (FIG. 7). They work independently and are fixed in separate castings 312 (FIGS. 7, 12) which are arranged between the main side frames 26 and 27 and serve as: bearings for the axles and shafts for raising and lowering the stop rails or stops 310 and 311. ¹ of the castings and the plates 315 and 316 (Fig. 6, 7 and 9) fixed, on which rests the card when it is evaluated in the two Abfühlstationen are. The plate 315 (Fig. 7) of the sensing station U is perforated corresponding to the possible counting point locations of the three card zones, and the holes are opposite the sensing pins. The plate 315 has a shoulder 317 (FIG. 9) to create a special slot which is outside the regular hole field of the card. The perforations in this approach 317 are only used to determine the presence or absence of a card that will never be punched in this column. The other plate 316 has a similarly perforated extension 318 for control purposes.

The casting 312 (FIG. 12) contains a U-shaped part 321 (FIG. 12) with three webs, of which the webs 324 and 326 can be seen in FIG. These ridges are cut out to make room for the shafts 190 and 193 of the lower feed rollers, but extend directly under the guide plates 315, 316 (Figures 6, 7) which support the cards in the sensing position.

In eyelets 329 (Fig. 6, 9) of the castings, an axis 330 is mounted with two arms 331, which means Pin 334 is articulated to the downwardly projecting arms 335 of the stop rails 310 and 311, respectively are. The lower end of arms 335 is hingedly connected to arms 337 by pins 336, which are attached to an axle 338. iao This lever system is used to set the stop rail 310 raised and lowered in an almost vertical path. By a spring 337 a attached to the arm 337 and a pin in the casting 321 'is attached, the arm 337 is clockwise with the Axis 338 pivoted and the associated with it

Retaining rail 310 is normally held in its upper position in which it is in the card path. The lowering of the stop rail 310 is controlled by a cam 141 (FIG. 3) of the coupling 140. An arm 342 attached to the axis 338 follows the movement of the cam by means of its roller 343 and is pivoted counterclockwise when it rotates against the action of the spring 337 a and the stop rail is pulled downwards. The axis 338 is mounted in corresponding extensions of the U-shaped part 321 of the casting 312 (FIG. 12) and is secured by adjusting rings 345, 346. The stopping device in the sensing station L is of the same type, and the movement of the stopping rail 311 is controlled by a cam 141 'of the coupling 125. Since the two clutches 140 and 125 and also the clutches 153 and 156 for controlling the raising and lowering of the sensing pins of both sensing stations U and L are identical in structure and effect ¹ , it is sufficient to describe only the coupling for controlling the Adhalteschiene3io. The clutches 140 and 125 are the control magnets FG and RG, the

a5 clutches 153, 156 assigned to the magnets FP and RP , respectively.

The cross rail 33 (FIG. 1) fastened between the side plates 26, 27 carries a coupling frame 350 in which a shaft 353 is mounted. This shaft 353 carries the release and return elements of the clutch 140, which is controlled by the magnet FG attached to a bracket 356. The anchor 358 * is around a tenon

357 rotatable, and its rotation is controlled by a Limit stop 359. The top of the anchor

358 is located in the movement path of a projection 360 at the end of a release lever 361, which is rotatable about the axis 353 and with its hook-shaped left end 362 engages the short arm of a coupling pawl 363. The pawl 363 is rotatably attached to a clutch disc 365 of the clutch 140 by a pin 364. A spring 367 is attached between an extension 366 of the clutch disk 365 and the clutch pawl 363, which pulls the tooth of the pawl into a notch in the drive disk 368 seated on the shaft 112 when the magnet FG is excited and its armature 358 attracts. The lever 361 can therefore rotate clockwise around the shaft 353 under the action of a spring 370 and releases the pawl 363 so that its tooth is brought into engagement with the drive disk 368 under the action of the spring 367. The clutch 140 is thereby connected to the shaft 112 to make one revolution. A lever 373 rotatable on the shaft 353 overlaps the release lever 361 with a shoulder 374 and is connected by a spring 379 to a lever 375 which is also rotatable on the shaft 353 and whose roller 376 follows the movement of a cam 377. The cam 377 pivots the lever 375 counterclockwise around the shaft 353, so that the spring 379 pulls the arm 373 and, through the projection 374, the release lever 361 down and brings the hook 362 into the path of movement of the short arm of the pawl 363 (around this The lever 373 is designed so that its free end snaps behind a projection 380 of the clutch disc 365 which corresponds to the short arm of the pawl 363 when it is stopped by the hook 362 in order to prevent reverse rotation due to the recoil impede.

The roller 376 of the lever 375 is by a spring 382 attached to its short arm against the Cam 377 pressed. When moving the release lever 361 into the basic position, the extension 360 pivots a toggle lever that can be rotated about a pin 385 in order to loosen the possibly sticking anchor from the cores. It is noted that one long card guide rail 390 near and attached to the right side frame 26 (Fig. 11, 12), in the groove of which the card by the inclined upper castors 226 is printed so that the card with its right side edge in the Groove is guided.

As already mentioned, the upper part of the filling device is carried by arms 38 and 39 which are rotatable about pins 40 (FIGS. 2, 5) in the main side frames 26 and 27. On the arms 38 and 39, plates 49 and 50, respectively, are insulated, which support the pin frame 395, in which all sensing and evaluation parts are accommodated. The plate 50 is attached to the arm 39 by rivets 46 and the frame 395 is suspended from this plate by means of bolts 396. The other side (Fig. 5) of the frame is attached to the other arm 38 in a similar manner by means of the plate 49. The frame 395 (Fig. 7) carries six sets of pins 398. Each set contains sixty rows of seven pins for evaluating the six looh zones in two cards at the U and L stations. The pins are arranged in separate groups in the two stations, and their holders are lowered and raised separately to allow them to pass through the perforations of the cards and raise them again in accordance with the intermittent movement of the card. The frame 395 also carries seven sets of contact levers 400 which slide over the heads 397 of the pins 398 to detect the pins that have passed through holes in the card and thereby to close contacts to emit hole pulses. In the station U three sets of sixty cotitakt levers 400 are provided, of which one lever interacts with the heads 397 of the seven pins 398 of a row of pins. Four sets of sixty contact levers 400 each are arranged in station L , of which the two outer sets of levers work together with only one associated set of pins and the contact levers of the two inner sets of levers with two pin teeth each work together in order to effect the impulse of late five sensing. The frame 395 also carries seven sets of contact rails 407, one of which is associated with a contact lever 400 in order to transmit the electrical impulse that occurs in the

Rotation of the contact lever against the contact rail is triggered. In both stations U and L , a special row of pins with the associated contact levers and contact rails is provided for zone B , which cooperates with the unperforated card edge in order to determine the presence of cards.

The side walls 410 and 411 (FIG. 11) of the frame 395, which extend approximately from the container M to the stacker drum SD (FIG. 9), are made up of three U-shaped parts, an end part 413 (FIG. 7), a middle part 414 and the other end portion 415 (Fig. 6) are held together. Between the parts are two openings through which the pen sets reach down to the two cards in the two sensing stations U and L. There are four cam plates on the upper surfaces of these parts. 416, 417, 418 and 419 (Fig. 6 and 7) attached, on which the ends of the contact levers 400 slide, ao when these turn guided beyond the associated pin sets.

Two plates 421 and 422 (FIGS. 6, 7) are attached to the underside of the frame 395, the former containing three longitudinal openings for the pins of the station U and the latter openings for the pins of the station L. A perforated guide plate 423 (FIGS. 6, 7) for guiding the pins 398 of the station U is attached to the top of the plate 421. A card guide plate 424 (FIG. 7) attached to the lower surface of plate 421 is bent upwardly near guide 285 and extends to a similar guide plate 425 (FIG. 6) attached to plate 422 in sensing station L. Both sheets 424 and 425 contain holes through which the tapered ends 399 of pins 398 can freely pass to contact the card surface. The metal sheets are used to guide the card and not to guide the pins. A perforated plate 426 (FIG. 6) for guiding the pins 398 of the station L is attached to the top of the plate 422.

On the underside of the plate 421 (FIG. 12), two cylindrical sleeves 428 are attached, in each of which a piston 429 slides in order to raise and lower the pins 398. Each piston 429 carries a spacer washer 430 to which the lifting plate 431 is attached, the pin sets of the station U protruding through the three recesses. The pins 398 rest with the underside of the heads 397 on a thin plate 433, which is fastened to the main plate 431, and are lowered into and out of the card holes as the lifting plate moves up and down. An insulating sleeve 435 is fastened in a bore at the end of the piston 429 by means of a pin which protrudes from the piston on both sides and serves to hold a stop ring 437 against which a spring 438 presses, which is supported on the lower end of the piston guide 428. A metallic protective plate 440 is attached to the end face of the insulating sleeve 435, with which the piston rests on a roller 441 at the end of an arm 442 which is attached to the shaft 443 mounted in the main side frame. The spring 438 tries to lower the piston 429 from its normal position, in which it is raised, with the lifting plate. Since the pins 398 and the associated contact levers 400 are live in order to keep the sensing pulses alive, the entire frame 395 must be isolated from the other parts of the machine. For this purpose, insulating sleeves 435 and the insulating plates are provided, which electrically isolate the main frame 395 from the oscillating arms mounted in the main frame.

The second piston 429 attached to the right side of the lifting plate 431 rests on a roller 445 of the arm 446, which is also attached to the shaft 443. This causes the lifting plate 431 with the pins to be evenly lowered and raised by the pistons attached to both sides. By guiding the pistons in the long cylindrical sleeves 428, a parallel guidance of the lifting plate 431 is ensured. An arm 448 fastened in the middle of the shaft 443 interacts with the control cam 154 of the coupling 153 through its roller 449. The cam 154 is designed to hold the pens up until a card is stopped in the sensing station / 7 and as it rotates a low peripheral portion of the cam causes the roller 449 to lower and the two arms 442 and 446 clockwise are pivoted, whereby the pistons 429 with the lifting plate 431 and the pins of the sensing station U are lowered under the action of the springs 438. The tapered ends of the pins 398 then either rest on the upper surface of the card (FIG. 13) or pass through its holes in order to prepare the triggering of the pulses by the contact levers 400 cooperating with the pin heads in this position.

A similar device for lowering the pins 398 of the second sensing station L contains a lifting plate 451 (FIG. 6) to which a perforated plate 433 is attached. The sensing pins 398 protruding through these holes rest with their heads 397 on the plate 433. Two pistons 453, which are guided in cylindrical sleeves 454, are attached to the lifting plate 451. These pistons and their guides are similar to pistons 428 and guides 429 in station U.

The control device for the pin drive device of the station L differs somewhat from the drive device in the sensing station U. An arm 458 is attached to a sleeve 456 (FIG. 10) enclosing the shaft 457, its roller with the cam 157 (FIG. 3) of the Coupling 156 cooperates. The effective times of the cam 157 can be found in the timing diagram (FIG. 21a). Two arms 461 and 4.62 attached to the sleeve 456 have rollers 463 (FIG. 6) at their free ends, against which the pistons 453 are pressed by springs. The lowering and raising of the sensing pens of station L is done in the same way as described for station U. The cam 157 is shaped so that it controls the movement of the two arms 461, 462 counterclockwise and the lowering of the pistons with the stroke

plate allows after a card has come to a standstill in station L.

Before describing the device for the horizontal displacement of the contact lever 400 for Triggering of the sensing pulses under the control of the lowered pins are intended to move the various positions the contact lever are considered. Fig. 13 shows the contact lever 400 in normal Position opposite the assigned seven pins

ίο 398 a number, which are also in the basic position when lifting plate 431 is raised. The contact lever 400 rests with the cam end piece 402 on the head 397 of the first pin 398 from the left, so that the contact button 404 has no Has contact with the contact rail 407.

When the pins 398 are lowered against the card and meet unpunched spots, you have the heads of these pens, e.g. B. the first two pins in Fig. 14, lowered a little, but the rotation of the Contact lever 400 around the pin 401 in the opposite Clockwise is not enough to bring the contact button 404 to the contact bar 407 in To bring touch. However, one or more pins 398 have passed through a hole (Fig. 15), the head 397 is lowered sufficiently and the contact lever 400 so far against it turned clockwise so that the contact button 404 comes into contact with the contact bar 407. This contact is made when the contact lever is shifted by each sensing pin 398 of the series, which entered through a card hole, at different times Trigger impulses to control the arithmetic unit, writing unit, etc. Because of this, the contact lever 400 moves horizontally to the right, so that the cam part 402 successively from slides left to right over the pen heads. When the cam end 402 is on a lowered pin hits, the contact button 404 is raised enough to make contact with the contact bar 407 to come and complete a circuit that will be sustained if even a pin was lowered. The contact contact 'with the contact rail 407 is repeated, albeit the next pin is lowered. In this way, any of the seven possible impulses can be triggered for any desired combination when the contact lever 400 moves uniformly to the right will. All seven sets or rows of contact levers 400 are used in a common frame simultaneous movement arranged over the heads of the pins. Each row contains sixty contact levers with the exception of the two contact levers that work together with the pins of the two i? as shown by the special openings 317 and 318 (FIG. 9).

The frame carrying the contact lever (Fig. 11, 12) contains two L-shaped rails 465 and 466, on which seven comb rails 467 (Fig. 7) protruding transversely through the machine by means of screws 468 are attached, each of which carries a number of contact levers. All comb rails 467 are the same and how As Fig. 12 shows, the ends of the ridges 467 are tapered while the central portion is larger Has cross-section in order to be able to store and guide the contact levers properly. From the enlarged Views (Figs. 13, 14 and 15) it can be seen that the comb bar 467 is provided with slots 470, in which each contact lever 400 is guided and is rotatably mounted on the common axis 401. In suitable holes in the comb rails 467 inserted small compression springs 471 press against the horizontal arm of the contact lever 400 to hold their cam end 402 against the heads 397 of the pins 398. The horizontal Arms of the contact lever are guided in slots of an additional comb plate 472, which is attached to the underside of the comb rail 467 is attached. Against an upwardly extending nose 473 of the Comb bar 467 is supported by the contact lever with its edge 474 to prevent its rotation during to limit the assembly. On the frame rails

465 and 466 are each by means of bolts 478 (Fig. 11) two rollers 479 attached. The two bolts 478 attached in the right rail 465 are something longer than the one on the other side and have two semicircular guide washers 480 (Fig. 11), which protrude over the right rollers to connect to the large frame 395. At four rails 482, 483, 484 and 485 (Fig. 11) are attached to the inside of the side plates 410 and 411, between which the rollers 479 during the horizontal reciprocating movement of the contact lever frame to run. Projections on the lower rails 482 and 484 limit lateral movement of the rollers 479, and the guide washers 480 protrude into the groove 486 (FIG. 11) on the underside the upper rail 483 to guide the contact lever frame during its longitudinal movement.

On the outside of the side straps 465 resp.

466 are U-shaped by means of screws 490 and 491, respectively Yokes 488 or 489 attached (Fig. 12), the legs 492 (Fig. 8, 2) of which are bent outwards, between which a roller 496 or 498 passes when the frame of the sensing device is lowered, to align the carrier of the contact lever. On the inside of the legs of yokes 488 and 489, fiber disks 493 (Fig. 8) are attached to to electrically isolate the sensing frame from rollers 496, 498 or from the machine. the Rollers 496 and 498 are rotatably attached to the free ends of levers 495 and 497 (Fig. 2, 10), which sit at the right or left end of the shaft 457. Two on the right and left side panels Enclosed protective plates 499 and 500 attached to the main sensing frame and protruding downward the rollers and yokes, so that their contact by the operator is prevented.

The shaft 457 and the two arms 495, 497 receive their oscillating movement through the complementary Cams 162 and 163 (Fig. 3, 5), which are connected to the main drive wheel ι π. A The three-armed lever 502 (FIG. 5), which is adjustable in relation to the lever 495, is on the hub of the lever 495 freely rotatable and carries two rollers 503 and 504, the former with the outer

Cam 162 and roller 504 cooperate with inner cam 163. The third arm of the Lever 502 is provided with a slot 505 (Fig. 10) which is at a small angle from the-, The center line of the lever 495 with respect to the shaft 457 differs. In the lever 495 is also a Slot 506 is provided which is at the same angle but in the opposite sense from the center line is inclined. A set screw 507 inserted into the slot 506 of the lever 495 protrudes with the square head 508 into slot 505 and can be fixed by tightening the nut in any position will. When the adjusting screw 507 is displaced in the slot 506, the Lever 502 is adjusted relative to the lever 495 and can be in the desired position against the lever 495 can be clamped by tightening the nut. A screw 509 is used for further fastening, which protrudes through an arcuate slot 510 (Fig. 10) in a short extension of the arm 495 and the Lever 495 jams after lever 502 has been adjusted against it. For further adjustment the movement of the contact lever frame is an adjustable clamping device between the two cams 162 and 163 and the gear in provided, which is the same as the adjusting device between levers 495 and 502. The cams 162, 163 are connected by a hub 520 which is loosely rotatable on the hub of the main drive wheel in FIG.

The cams are connected to the wheel 111 by means of a set screw 517 (Fig. 5) connected by slots 515 and 516 of the cam 162 and the wheel 111 protrudes (Fig. 11). These slots 515 and 516 are in the radial angular adjustment different, so that a rotation of the cams against the wheel 111 is possible is when the set screw is displaced in the slots. Rectangular head 518 of the Adjusting screw 517 protrudes into slot 515 and is against the side surface when the nut is tightened of the gear 111 pressed in order to prevent further adjustment of the cams after they have been set. A bolt 519 is used to further secure the set cams arcuate slot in the gear protruding into the cam 162 is screwed. It is noticed that the movement of the contact lever frame is independent of the engagement of the clutch and occurs continuously as long as the card guiding and sensing device is in operation. Other electrical Controls therefore determine when the triggered by the oscillating movement of the contact lever Impulses take effect. The cams 162, 163 for controlling the movement of the crank support frame are designed so that all seven rows of contact levers 400 from left to right after the pins 398 have been lowered through the holes in the card. These Movement is synchronized with the adjustment movement of the registration devices, and that of the Movement of the contact lever 400 generated pulses have a value that corresponds to the degree of rotation of the Cam 162 and 163 corresponds. The rotation of the cams and the generation of the pulses are in Timing diagram (Fig. 21a) is shown, which also shows the relationship between the pulses and the others Displays controls for storage.

Each contact lever 400 is assigned a contact rail 407, against which the button 404 is pressed when the contact lever rotates counterclockwise during its displacement via a lowered pin. Corresponding to the assumption of a card with sixty columns, six rows of sixty contact rails 407 each and two special contact rails are provided for the B-zone .

The invention is not limited to a sixty-column card. Rather, the number of pins and contact rails corresponds to the number of columns on the card and is z. B. for an eighty column card eighty pins and contact levers. The contact bars are divided into two sets of three rows each corresponding to the two sensing stations U and L , and each set of the contact bars insulated from one another is combined into a package. Two separate holders carry the contact rails 407 of station U and station L. Since these are the same, the description of one holder is sufficient. Three contact rails 407 are attached to the sides of an insulating sheet 409 in such a way that their lower horizontal edge protrudes below the lower edge of the insulating sheet and lies in the plane of movement of the button 404 of the associated contact lever 400. The lines that lead to the switchboard of the machine are clamped to the shoulders 408 of the contact rails 407. The ends 522 and 524, respectively, of the insulating sheets 409 (FIG. 7) rest on rails 532 and 533 and are held at the appropriate distances from one another by combs 530, 531. The rails 532, 533 and the combs 530, 531 are fastened by screws 529 (Figs. 6, 7, 8, 10) to a frame 527 in the sensing station U and to a frame 528 in the sensing station L, respectively. These frames are attached to side walls 410 and 411 by screws 526. For stiffening and distancing the middle part of the insulating sheets 409, a comb rail 536 is provided, in the slots of which the upper edges of the sheets 409 lie. The comb rail 536 is inserted into grooves 535 of the frame 527 or 528.

Since the truck can be swiveled out of its position above the sensing unit, the lead wires can easily be attached to the ends 408 of the contact rails 407. as well the contact rails can also be removed to check their contact surfaces, if necessary. Since the whole sensing system forms a unit, it is possible to use the contact rails, to remove and close the contact lever and the pin carrier separately in the order mentioned check. iao

When a card leaves the second station L (Fig. 6) it is conveyed between the two plates 316 and 425 and over an upwardly curved guide plate 559 secured between the side frames 26 and 27 against the stacker. The end of the guide 559 is corresponding to that

The circumference of the stacker drum SD is curved, so that the card is partially advanced over the drum circumferential surface. It has already been described that the shaft 63 of the stacker drum (Fig. 3) is driven via the gears 126, 127, 129, 130, 131 and 134 and the drum executes half a revolution when the reverse locking clutch is released when the clutch for the Drive of the lock 311 in the sensing station L is engaged. The stacker drum SD consists of three parts, namely the right and left end parts. 560, 562 (Fig. 9) and a central connecting part 561. All three parts are attached to each other and on the shaft-63. Near the periphery and offset from one another by 180 °, two slide rods 563 are mounted in the end parts of the drum, each of which carries two card clamping frames 564. These frames 564 are located near the ends of the rods and protrude through openings 565 in the drum in order to be able to grasp the cards.

Each frame is roughly triangular. The corner 566 contains a bore to encircle the slide bar 563, the second corner has a recess 567 (Fig. 6) by means of which the clamping frame is slidably supported on the drive shaft 63, and the third corner forms a base 568 for the Card edge. The card is clamped against the base 568 by spring tongues 569 which are attached to an arm 570 which is rotatable on the rod 563 between the two end arms 566 (FIG. 9) of the frame. The spring tongues 569 are attached to the arm 570 by a ferrule 573, and a spring 574 attempts to pull the tongues against the pad 568. At the right end of the rods 563 (FIG. 17) an arm 571 is attached, which carries a roller 572 at its free end. The two rollers 572 cooperate with cams 577 and 578 which are adjustably mounted near the right hand end of the shaft 63 within the plate 65 to which the stacker frame is connected. The cams 577 and 578 are shaped to hold the arms 571 and rods 563 in a position in which the spring tabs 569 normally urge the card against the drum. By raising the cams 577, 578, the arms 571 and the rods 563 are rotated clockwise at corresponding times (FIG. 6) in order to lift the spring tongues 569 from the so-on position 568. One of the two positions in which these parts are separated to allow the edge of the card to enter is shown in FIG. In this position, the card coming from the sensing station L is pushed between the support 568 and the spring tongues 569, whereupon the arms 570 are rotated counterclockwise by the springs 574 during the further rotation of the drum and the card between the spring tongues and the supports 568 is held. Since two arms 570 are arranged on each rod 563 and each of these arms has two spring tongues 569, the card is clamped to the forklift drum by four tongues and, when it is rotated by a little more than 180 °, it is transported into an almost vertical position 2um the forklift frame 71. The base plate 73 of the card holder Tagt in an annular recess 579 in the central part 561 and thus in the path of the card edge. As soon as the edge of the card hits the plate 73 as the drum rotates, the card is released from the drum and deposited in the container.

The drive shaft 713 (Fig. 18) for the arithmetic unit is driven by a suitable gear so that it performs one revolution in each machine cycle. For each point of the arithmetic unit, a wheel 714 is attached to the shaft 713, which wheel meshes with a toothed wheel 717 of the adding clutch (FIG. 19). A clutch disc 715 is connected to the gear wheel 717 and sits freely rotatably on the axle 716. A disk 720, also freely rotatable on the axis 716, is provided with ten teeth 720a, which the tooth 721 α of a clutch lever 721 can put in order to lock the disk 720 against its counterclockwise rotation. On the side of the disc 720 is a rotatable on the axis 716 adding wheel 724 with ten notches 7240 on the end face. The wheel 724 can assume any of ten rotational positions corresponding to the values ο, ι to 9. In the division of rotation achieved, the wheel 724 is aligned and stopped in accordance with the center of the value position by a locking lever 725 engaging under the action of a spring in the notch 724a. A transfer cam 726 is attached to the side of the wheel 724 and a pin 727 of the wheel 724 protrudes through an opening in the disc 720 and carries a rotatable clutch pawl 730. A spring 731 brings the tooth of the pawl 730 into engagement with the clutch disc 715, when the disk 720 is released to rotate. In Fig. 18, the clutch lever 721 is shown in the locking position, in which its tooth 721 α the rotation of the disc

720 counterclockwise prevents. The clutch disk 730 is therefore out of engagement with the clutch disk 715 and is held in this position by the interaction of its pin 730 with the cam edge 720 b of the disk 720. As soon as the tooth 721 α of the clutch lever is rotated out of the path of the tooth 720 a of the disk 720, the spring 731 brings the clutch pawl 730 into engagement with the clutch disk 715, and during this movement of the pawl 730 its pin 730 slides along the cam edge 720 b and rotates the disc 720 counterclockwise until the previously locked tooth 720 is located to the right of the tooth 721 a of the lever 721. The clutch is now engaged and, as FIG. 19 shows, the registration wheel 724 is coupled to the drive 715, 717 for rotation. Due to the interaction of the pin 730 b of the coupling pawl 730 with the cam edge 720 &, the disc 720! Is carried along when the registration wheel rotates.

When the clutch lever 721 is in its basic position returns, abuts a tooth 720 a of

Disk 720 against tooth 721 α, and disk 720 is stopped. The registration wheel 724 and the pawl 730 continue to rotate, however, and the cam edge 720 b of the disc 720 lifts the pin 730 b so that the pawl 730 disengages from the clutch disc 715 and the registration wheel is disengaged from the drive. The registration wheel is stopped and aligned in the new value position by lever 725. A spring-loaded pawl 735 secures the lever 721 in both of its positions. The short arm of the coupling lever 721 is articulated to the common armature 736 of the feed magnet AM and the holding magnet SM . The excitation of the magnet AM moves the armature 736 clockwise to pivot the lever 721 in the reverse direction, and the excitation of the magnet SM moves the armature 736 counterclockwise to rotate the lever 721 back to the home position.

When the registration wheel 724 is in one of the positions ο, ι to 8, the cam 726 holds a transfer lever 737 rotatable about the pin 738 in the position shown in FIG Contact elements 740 and 741 occupies. As soon as the wheel 724 comes into its new position, a tooth of the lever 737 falls into a notch 726 α of the cam 726, and the contact spring 739 comes into contact with the contact element 741. When the wheel 724 rotates from the nine to zero position, it rises an elevation 726 b of the cam 726 to the lever 737, and the contact spring 739 comes into contact with the contact element 740. During this movement of the lever 737, the arm 742 connected to it is rotated and a spring-loaded pawl 743 prevents it from rotating backward. The contact connection between spring 739 and member 740 is maintained until a pin 744 in wheel 714 reaches an arm 745 connected to pawl 743 and rotates the pawl to release lever 742. To mechanically disengage the registration wheel 724 there are three

+5 pins 751, 752 and 753 on one side of the wheel 714 is provided, which during the rotation of the wheel 714 successively under the clutch lever 721 must be passed. If the lever 721 is pivoted from its basic position at this point in time, if it is returned to the basic position either by the pin 751, 752 or 753, as Fig. 18 shows. Pins 751, 752 and 753 are at certain points of the machine game effective, which are shown in the diagram of Fig. 21a.

The calculator described has an electrical device for taking sums. Since this is known, its description is dispensed with and a schematic representation in connection with the circuit diagram (Fig. 20d, 20e) of the machine is sufficient. A brush 663 is connected to each counting wheel and connects a contact segment 661 corresponding to the set value in every position of the counting wheel. The contact segments 661 corresponding to the same numerical values are connected to one another by wires or contact rails 664. Digit pulses of the values 5, 3, ι, ο are transmitted to the segments 661 by means of the cam contacts CR 97 to CR 106, and the selected pulses 5, 3, i, 0 are transmitted to a pulse converter and in converted to the decimal digit value.

The machine contains a writing mechanism to record both the imported line items and their totals, which are inserted into a counter to write. As will be described later the values of the extraction point set in the counters not as decimal values, but as Combination values obtained according to a selected combination key, which are obtained by a converter can be converted into decimal numbers.

The shaft 822 (Fig. 22b, 23) makes one revolution in each machine game and drives the shaft 109 of the card feed device with the interposition of a clutch. The card feed clutch is known and is controlled by the magnet CF (Fig. 20 a). The conversion means will now be described by which the encrypted digit values transmitted under the control of the extraction device are converted into the decimal value in order to select the appropriate digit type for printing the sum. The cams 800 A, 800 B, 800 C and 800 D (Fig. 22 b), the drive of which will be described later, each make one revolution in each machine cycle. These cams are designed differently, and the times of action of the particular cam parts are shown schematically in the time diagram (FIG. 21 b). Each cam has 100 projections, the height of which is indicated by three dotted circles for cam 800 A. These different cam heights are referred to as low, medium and high in the remainder of the description. The cams 800 A, 800 B, 800 C and 800 D are shaped as rollers in order to be able to work together with several bodies at the same time. Each cam 800 is assigned a locking member 810 which, when raised to a height determined by the cam parts middle or high, releases a release lever 863 to move to the left (FIG. 22 b). In the normal lower position (corresponding to the low cam part) the locking member 810 prevents displacement of the release lever 863. Each member 810 slides in a slot 801 of a guide block 802 and is guided by a rod 804 which comprises a guide slot 803 of the locking member 810. A pawl 806 is rotatably arranged on a shaft 805 carried by the block 802, and a compression spring 807 provided between this and the locking member 810 holds the pawl 806 and the locking member 810 in the position of FIG. 22b or the locking member 810 against the associated cam 800 pressed. Each locking member 810 has a nose 808, which together with a shoulder 809 of the release lever 863

works. The release lever 863 slides with its right end (Fig. 22 a) in a guide slot the support plate 811, and its left end (Fig. 22 b) is articulated to an arm 813, its nose 818 is pressed against the end face of a cam 825 by a compression spring 814 will. As soon as the release lever 863 is released by the locking members 810 and the nose 818 of the arm 813 a notch of the cam 825 is opposite, the release lever moves after left to trigger the mechanical impulse that moves the trigger arm 867 and a Coupling takes effect to initiate the rotation of the character wheel.

It was mentioned that the nose 808 lies in front of your shoulder 809 of the release lever 863 and inhibits its movement to the left when the locking member 810 rests on the lower part of the cam 800. When the central height of the cam 810 becomes effective during the further rotation of the cam 810, the locking member 810 is moved upwards and the nose 808 is raised over the shoulder 809. The finger 812 of the locking member 810 slides on the end face of the locking pawl 806, so that a clockwise rotation of the locking member 810 under the action of the spring 807 is prevented. However, if the locking member 810 is brought to its highest position by the high cam part, the compression spring 807 can rotate the member 810 clockwise if at that time the pawl 806 was rotated counterclockwise as a result of the excitation of one of the magnets 861. The hook-shaped end of the finger 812 passes over the left end of the pawl 806, so that the downward movement of the locking member 810 is prevented. Thus, whenever the up portion of a cam has raised a locking member 810 to its highest position, that member will be latched after the locking pawl 806 is moved to the latching position. If the pawl has not been moved, the link 810 is not latched and, as the cam 800 rotates further, moves up and down in accordance with the following cam edge. The expensive effects of the cams 800 B ₁ 800 C and 800 D are similar to the effects of the cam 800 A ₁ just described, so that their description is unnecessary. The movement of the pawl 806 for locking the locking members 810, which are in their highest position, takes place under the control of the magnets 861 (FIG. 22 b). As soon as one of these magnets is excited and attracts its armature 815, it moves a slide 816 to the left, and its four lugs 817 turn the associated pawls 806 into the locking position in order to lock the locking members 810, which at this point in time are raised to the highest position are. When the magnet 861 is excited, the notch 820 a of a cam 820 (FIG. 22 a) rotating synchronously with the cams 800 lies opposite the arm 821 of a three-armed lever 824, so that the slide 816 can be moved to the left by the armature 815 .

Immediately thereafter, the cam part b swivels the lever 824 counterclockwise, and the arm 821 α returns the slide 816 and the armature 815 to the normal position if it sticks to the magnet core due to remanent magnetism or has not been reset by the spring 823. From the timing diagram (Fig. 21a, 21b) it can be seen that at the time of the transmission of the pulses 5, 3, ι, ο to the magnet 861 through cam contacts to be described one of the cams 800 the associated locking member 810 in its highest position has raised. If z. B. the 5-pulse is triggered, the high part of the cam 800 A comes into action. At the time when the 3-pulse is triggered, only the high part of the cam 800 B works. For all electrical pulses 5, 3, ι, ο this condition can be represented by the following table:

Impulses

5
3
ι
ο

Latched limbs_8io

8τοΒ 8ioC 810D

It can be seen that the members 810 individually or according to the key in predetermined Combinations are latched so that upon completion of the transmission of the electrical impulses 5, 3, ι, ο all or some of the links 810 latched are. The unlatched locking members 810 move in accordance with the following cam part of the corresponding cam down again.

The left-hand movement of the release lever 863 during the transmission of the pulses 5, 3, ι, ο is prevented by the concentric part 825 α of the cam 825 (FIG. 22 b). But if all four locking members 810 are either latched in their uppermost position or lifted so far that the lugs 808 are above the lugs 809, the release lever 863 can move to the left as soon as a notch 825 b of the cam 825 opposite the lug 818 of the lever arm 813 lies. The cam 825 is driven synchronously with the cams 800 and 820.

After one or more locking members 810 are latched in accordance with the pulses, the cams 800 A, 800 B, 800 C or 800 D raise and lower the remaining unlatched locking members 810 according to their various cam parts as they continue to rotate. The release lever 863 remains inhibited against its movement by one or more of the unlatched links until a point is reached in the machine game at which all the unlatched locking elements are simultaneously raised to the middle level. At this point in the machine game, the release lever 863 can therefore move to the left under the action of the spring 814 and under the control of the cam 825. If, for example, the pulses 5, 3, ο were triggered to represent the number 9, then the blocking elements 8io ^ 4, 810B and 810D are in the 75th degree of the machine according to the high cam positions of the corresponding cams 800.4, 800 B and 800 D

game (Fig. 21b) latched. The locking member 810 C , however, still prevents the release lever 863 from moving up to the 123rd degree of machine play, at which time the cam 800 C lifts the locking member 810 C through its central cam portion. At the same time, the notch 825 b marked with 5, 3, 0 is located opposite the nose 818 of the arm 813, the release lever 863 is now free and the spring 814 causes its movement to the left in order to actuate the release arm 867 and the type selection clutch for Engage the rotation of the type wheel 860 to select the number type 9. With the further rotation of the cam 825, the edge 825 c of the notch 825 b returns the lever arm 813 and the release lever 863 to the right without, however, disengaging the latched locking elements 810. In the 135th degree of machine play, a special cam part 825 d moves the release lever 863 to the right beyond the normal position. The lugs 809 abut the fingers 823 of the locking members 810 and unlatch them from the locking by the pawls 806. The springs 807 are compressed and the pawls 806 moved into the normal position. The movement of the release lever 863 to the right also pivots the unlatched links 810, but this remains ineffective.

In the same way as the impulses 5, 3, ο the coupling of the type wheel coupling for the Selection of the nine-type, the clutch is controlled by various combinations of impulses for the selection of the digit types according to the following table:

Digits Above- Latched 810 B ₁ 810 D Cam 800 type TOlLLclte
Impulses Links 810 810 B in middle height 9 5.3. O 8lO ^ 4, 810 C, 810 D 800 C 8th 5. 3 810.4, 810 C 800 C, 800 D 7th 5. ι. ο 8τοΑ, 810D 800 B 6th 5. ι 810.4, 810 D 800B, 800D 5 5. 0 8τοΑ, 800 B, 800 C 4th 3.0 · 810 B, 810 D 8ooA, 800 C 3 3 810 B 800.4, 800 C, 800 D 2 i, 0 810 C, 800A, 800B I. I. 810 C 800 A, 800B, 800D O O 8lOÖ 800 B

The middle heights of the cams 800 of the unlatched links 10 determine the time in which a mechanical impulse is transmitted. This mechanically transmitted to the release lever 863 Impulse causes the type wheel 860 to turn into the printing position corresponding to the selected type.

Every point of the printing unit is around the axis

866 rotatable lever with three arms 864, 865 and

867 assigned. A clutch roller 868 is attached to the shaft, running along its periphery Includes coupling notches 869. The roller 868 forms the driving coupling member and serves at the same time as a bearing for the clutch wheels 870, which is placed freely rotatably on the clutch roller 868 by means of the flange 872. Every print shop a clutch gear wheel 870 is assigned, which is used to secure the mutual spacing in slots 871 of the guide combs 873 and 874 are guided. Each clutch wheel 870 meshes with one Type wheel 860 and carries a rotatable coupling pawl 876, which is normally operated by the lever arm 867 is held in the position in which its tooth 877 is out of engagement with the notches 869 of the Clutch roller 868 is. When the lever arm 867 through the release lever 863 to different Times is moved, the tooth 877 of the clutch pawl 876 falls under the action of a spring 878 into a clutch notch 869 and causes the clutch wheel 870 and the type wheel to rotate 860.

22 a and 22 b show the establishment of a point of the printing unit, but contains the Machine a large number of such units for writing a plurality of digits of a sum. If after the assumption made the release lever 863 by the impulse, 3, 0 in the 123rd degree of the Machine game is adjusted to the printing of the number 9, the engagement of the takes place at this point in time The coupling pawl 876 and the type wheel 860 are turned until the number type 9 is in the print line got. The time at which the release lever 863 is actuated determines the amount of rotation of the character wheel 860 from the rest position, which is necessary to select a digit type. To When the selected type is pressed, the type wheel 860 continues to rotate until the free end of the coupling pawl 876 strikes against arm 867, which in the meantime is supported by compression spring 879 (FIG. 22 a) in its normal position has been reset. After disengaging the pawl 876, the type wheel 860 is ioo in the normal position.

Each type wheel 860 is carried by an arm 881 rotatable about an axis 882, the protrusion of which 884 is pulled against a cam disk 885 by a spring 889. This cam disc 885 is the driven part of a clutch. A clutch roller 886 is attached to the shaft 838, on which the clutch disks 885 are rotatably mounted. Each clutch disc 885 carries one rotatable clutch pawl 887, and the disks 885 are similar to the wheels 870 guided. A release lever 888 is assigned to each coupling pawl 887. When the clutch pawl 887 is released and engaged with a Notch of the clutch roller 886, the disk 885 is rotated clockwise. As soon as you cam 883 hits the projection 884, the arm 881 is against the action of the spring 889 about the axis 882 panned. The clutch is engaged when the magnet 861 is re-energized in every iao Place for the numeric writing by an impulse in the iV time of the machine game. In the Pivoting the arm 881 by the cam 883 turns the type wheel 860 against the usual Ink ribbon and the pressure roller 890 pressed around which the paper strip to be printed is guided.

When the arm 881 against the action of the spring 889 is swiveled, the type wheel on wheel 870 rolls clockwise, and that of the type wheel counterclockwise rotation imparted by gear 870 is canceled so that the type wheel practically comes to a standstill when pressing against the platen 890. The type touches the Roll at a right angle, applying forceful pressure to create a legible print. To The passage of the cam 883 of the disc 885 on the projection 884 pulls the spring 889 the Arm 881 and the character wheel return to their normal position, and the projection 884 is back on the concentric peripheral part of the clutch disc 885. Since the type selection clutch is still is engaged, the type wheel 860 continues to rotate after writing until the coupling pawl 876 butts against the release lever 867, which has meanwhile been reset, and thereby disengages from the Kuppao Lungswalze 868 is brought. The write clutch also remains for one complete revolution of the disk 885 effective, and their disengagement takes place when the coupling pawl 887 hits the release lever 888, which has since been reset. By one reverse rotation of the clutch wheel 870 to prevent when the pawl 876 hits the coupling arm 867, one is under the effect a spring standing pawl 896 is provided, the nose of which in the basic position of the clutch in a notch 897 of a plate 898 attached to each wheel 870 is sunk. Likewise prevented a pawl 891 in cooperation with the Notch 899 of the clutch disc 885 the reverse rotation when the pawl 887 hits the Lever 888.

Due to the electrical impulse in the iV section of the machine game, the magnet 861 is again excited and attracts its armature 815. The slide 816 thus moved can now pivot the lever 821 α to 824, since the third arm 821 is located opposite the part 820 c of the cam 820 at this time. The lever 888 now falls into a recess 826 in the arm 824, and the pawl 887 couples the cam disk 885 to its drive. The cam protrusion 883 meets the protrusion 884 at the time the selected digit type is in the writing position. During the first movement of the slide 816, however, the pawl 887 must not be released by the lever 888 or the write clutch must not be engaged. For this purpose, a cam 837 is provided, the raised part 837 α of which prevents the lever 888 from moving during this time. When the iV pulse is transmitted, the low cam portion 837 b is opposite the lever 888, and this can fall into the recess 826 of the lever arm 824 to release the clutch pawl 887. Then, the cam member raises 837 c the trip lever 888 back to the initial position to the disengagement of the clutch pawl to cause 887 after one complete revolution of the writing clutch. At the end of this revolution, a projection 820 d of the cam 820 moves the lever arm 824 again under the projection 835 of the clutch release arm 888, which has already been lifted into the position shown in FIG. 22 a. The cam projection 820 d also causes the slide 816 and the armature 815 to be returned to the basic position if the armature should stick to the magnetic core 861.

The pressure shaft 838 (Fig. 23) is driven by the drive shaft 822 via the gears 940, 941 so that that they rotate at a constant speed of 1V2 revolutions for each revolution of the Drive shaft 822 executes.

The shaft 839 of the type selection clutch makes 2 ¹ As revolutions in each machine cycle and is driven in a known manner at a different speed. After a rotation of a certain duration synchronized with the drive shaft, the speed of rotation of the shaft 839 with respect to the shaft 838 is reduced or increased in order to select the corresponding type of a selected type group of the alphabet. During the reduced rotational speed of the shaft 839, the types of the selected type group successively move into the printing position, and in the 330th degree of machine play, the selected type of this group is located opposite the platen. At this time, the cam 883 of the clutch disc 885 hits the protrusion 884 to press the selected type of digits against the platen 890.

The cams 800 A, 800 B, 800 C and 800 D, 820, 825, 837 and 887 are driven synchronously by the shaft 822 and each make one complete revolution in each machine cycle. The fixed to the shaft 822 gear 1040 (Fig. 23) drives via gears 1041 and 1042, the shaft 1043 of the cam 800 D, the cam 800 C sits directly on the shaft 822. The gear 1040 drives also through the gears 1044 ^un d 1045 the shaft 1046 of the cam 800 B. The gear 1045 drives via an intermediate gear 1047 ^{un (} i the gear 1048 the shaft 1049 of the cam 800 A. With the gear 1044 a gear 1050 is connected, which via the gears 1051 and 1052 die Drive shaft 1053, on which the cam 825 is seated. With the gearwheel 1050 meshes the gearwheel 1054, which is attached to the shaft 1055 of the cam 820. The gearwheel 1056, which is attached to the shaft 838, drives the shaft 858 via a gearwheel 1057, on which the cam 837. In this way, therefore, the cams 820, 825 and 837 are driven in synchronism with the cams 800yi, 800 B, ₃ 800 C and 800 D.

The main conductors 615 and 616 (FIGS. 20 a to 20 e) are connected to a suitable power source by means of a main switch. When the start button is pressed, its contact 617 (Fig. 20 a) creates a circuit from the main conductor 615 via the iao cam contact Ci? 6, the line 618, the excitation coil of a relay R 12 and the line 619 to the main conductor 616 closed. The relay R 12 closes its contact R 12 α and thereby its own holding circuit from the cam contact CR 5 via the line 620, the holding coil R 12 H and

the line 619 to the main conductor 616. The second contact R 12 b of the start relay R 12 closes the automatic start circuit from the main conductor 615, the stop button contact 624, the line 625, the now closed contact RE2 of the error relay RE, the relay R 13 and the line 619 to the main conductor 616. The relay R 13 creates a holding circuit from the main conductor 615 via the cam contact CR 4, the holding winding R 13 H and the line 619 to the main conductor 616 through the contact R 13 b. The relay R 13 closes the contact R 13 α and thus a circuit from the main conductor 615 via the cam contact CR 3, the line 028, the now closed contact MI 2-2, the relay R 14 and the line 619 to the main conductor 616. The relay R 14 closes through the contact R 14 α a holding circuit from the main circuit 615 via the cam contact CR2, the line 629, the holding winding R14H and the line 619 to

ao executive 616.

The relay R 14 closes the contact R 14 b in the excitation circuit of all clutch control magnets for the card guide, for controlling the front lock and for moving the card knife. The card feed is initiated by the excitation of the knife clutch magnet FG. The excitation circuit extending from the main circuit 615 via the line 630, the relay contact R 14b, conduit 631, the cam contact CR 125, the conduit 632, the coupling magnet FG and the line 633 shifts to the main circuit 616. By energization of the magnet FG the card knife first card in the first sensing station U. The card closes the contact 252 through the card lever 298 and thus a circuit from the main conductor 615 via the cam contact PC 2, the excitation winding of the relay R 4 and the line 619 to the main conductor 616. The relay R 4 is a holding circuit from the main conductor 615 via the cam contact PC 1, the contact R 4 a, its own holding winding R4-H and the line 619 to the main conductor 616. The relay R 4 therefore remains energized as long as cards are running through the machine.

By inserting the cards into the container M , a contact 296 is closed in a known manner and a control relay R 1 is energized. The excitation circuit runs from the main conductor 615 via the contact 296, the relay R 1 and the line 619 to the main conductor 616. The relay R 1 creates a holding circuit via the cam contact PC 3 through its holding contact Ria.

In addition to indicating that a card is entering the first sensing station, once the card is entering the second sensing station, control exercised by the card is maintained. This is done by a relay R 7, which is energized by the holding circuit of the relay R 4 and kept energized via the following machine play. The excitation circuit for the relay R 7 branches off from the contact R 4 a and runs through the cam contact CF 3, the excitation winding of the relay Ry and the line 619 to the main conductor 616. The holding circuit for relay R 7 is through the contact R 7 α and the Contact 581 made. The contact 581 is closed in a known manner near the end of the machine cycle when the stacker is in operation.

The relay R 13 remains after its excitation when pressing the start button due to the now closed contacts Rib, R 4b and R 7b, which are all in series with the relay contact Ri ^ b , excited as long as cards are available. The holding circuit runs from the main conductor 615 via the line 623, the stop button contact 624, the relay contact RE2, the relay contacts R 1 b, R4b, Ry b and R 13 b, the relay winding R 13 H and the line 619 to the main conductor 616 When relay R 13 is in operation, relay R 14 also remains energized. On closing of the relay contact R 4c and the clutch solenoid FP is energized to initiate the movement of the carrier Abfühlstifte. At the same time the contact 4a of the relay i? 4 closes a circuit from the main circuit 615 through the line 630, the contact R 14 b, the line 631, the cam contact CR 126 and the clutch control magnet CF for executive 616. The magnet CF couples the main drive shaft to the Drive shaft of the card guide, which also causes the rotation of the shaft of the cams for actuating the CF contacts. These contacts are therefore only operated when the clutch magnet CF is energized, while the cams controlling the contacts CR are driven directly by the main drive shaft.

The card is fed out of the second sensing station as soon as the clutch magnet RG for controlling the second lock 311 is excited. This magnet is under the control of the Relaisi? I, and normally the circuit for the excitation of the magnet RG to actuate the rear lock is closed by the contact R4c and runs from the main conductor 615 via the line 630, the contact Ä 14 b, the line 631, the contacts CR 125, R 4 ε, the line 642, the coupling magnet RG and the line 633 to the main conductor 616. As soon as the last card of the stack is led out of the second sensing station, the control by the relay R4, and no The circuit for exciting the magnet RG is routed via the now closed relay contact Ric , which bridges the relay contact R4e. Through the contact Ri c , the coupling magnet RG is kept energized for the last card pass, whereupon the contact R 14 b opens in order to terminate all actuations controlled by the coupling of the card guide. Simultaneously with the introduction of the card into the second sensing station L , the excitation of the coupling magnet RP for controlling the movement of the pen carrier of the sensing station L is required. The excitation of this magnet is under the joint control of the card lever relay R4 of the first station and the card lever relay R 7 of the second station. The excitation circuit

runs from the main conductor 615 via the line 630, the contact i? 14 b, the line 631, the contacts CP-125, R \ e, R "jc, the clutch control magnet RP and the line 633 to the main conductor 616. The machine according to the invention also includes the known automatic group control device, by means of which the total pressure and the zero setting of the arithmetic units are initiated. As is known, several columns of a field of the card are used to represent the group number. To simplify the circuit diagram, the group control circuits are only shown for three-digit group numbers, and of these again only the switching connections are shown one position for control at the upper sensing station and one at the lower sensing station is shown in Fig. 20b. From the socket 651 of the units position of the column belonging to the group control at the lower sensing station L , a plug connection is made to the socket 653 which is connected to the excitation winding of the relay RCι is connected Eicher way, a connecting cable 654 establishes the connection from the socket 651 of the units position in the upper filling station U to the control relay RC2 . The relays RC 1 and RC 2 receive electrical impulses 5, 3, 1.0 according to the combination perforations in the corresponding columns of the card and their sensing at the lower and upper sensing stations. The pulse circuit is the same for each station and runs for the lower station from the main conductor 615 via the cam contact Ci? 34, which is closed when the holes 5, 3, ι, ο of the card are sensed, the line 655, the contact rail 395 , the contact lever 400, the contact bar 407, the Buahseosi, the connecting cable 652, the socket 653 and the excitation winding of the relay RCι to the main conductor 615. Simultaneously with the excitation of the relay RC 1, the relay RC 2 is also excited when the sensed hole gap of the the following card contains the same perforation. The relays RCx or RC 2 are kept energized by circuits from the main conductor 615 via the cam contact CR 34, the line 655, the holding contacts RC α or RC 2a, the holding windings of the relays RCx or RC2 to the main conductor 616. When they are excited, the relays RCi and RC 2 switch their contacts RC 1 b and RC2 b , so that the circuit from the line 656 to the socket 657 remains open. However, an inequality of the perforations of the same card columns sensed causes the changeover of one of the fr contacts alone, so that a circuit from the main conductor 615 via the cam contact Ci? 34, the lines 655, 656, the for example now switched contact RC ι b and the non-switched contact RC2b to the socket 657 is closed. If three points are used for joint control, the plug connections must. 658 will be produced. This circuit is extended by a connecting line 659 to the field winding of the control relay MI ι, which is connected to the main conductor 616 by the line 660 (FIG. 20 c).

The group control of the known tabulating machines is divided into several control groups, which are referred to as sub, intermediate and main group control. For the sake of simplicity only the subgroup control for the purpose of taking totals is described here, on which the counter is reset.

When the relay MI 1 is energized, its contact MIi-I closes a holding circuit from the main conductor 616 via the line 66o, dieHaltewickluiig.M / 1 H, the contact MI1-1 and the cam contact CR 41 to the main conductor 615. The cam contact CR 41 holds that Relay MI ι excited up to the 335th degree of the machine game in which a group change has occurred. The relay MI ι closes the contact MI 1-3 (Fig. 20 c) and thereby a circuit from the main conductor 615 via the cam contact CR 43 and the relay MI2, which is a holding circuit through the contact MI2-1 through the winding MI2-H and the cam contact CR 42 produces. The cam contact CR 42 is bridged by the relay contact P 12-2 of a program control relay P12, so that when the cam contact CR 42 opens in the 315th degree of machine play in which the group change has occurred, the relay MI2 remains energized until finally the contact P 12-2 opens, as will be described later.

Since the cam contact CR 48 (Fig. 20 c) closes in the 305th degree of machine play before the cam contact CR 41 interrupts the excitation of the relay MI 1, a circuit is established from the main conductor 615 via the line 661, the cam contact CR 48, the relay contact MI1-4 still closed. and the relay Pi to the main conductor 616 is closed. The relay Pi maintains its excitation by a holding circuit via the contact P1-1, the cam contact CR 50 and the line 661 to the main conductor 615. Simultaneously with the holding winding P iH the relay CC ι connected in parallel is also energized and kept energized by the cam contact CR 50 up to the 288th degree of the next machine cycle, in which a sum is written and the arithmetic unit is reset to the zero position.

While the cam contact CR 3 (Fig. 20 a) closes to the winding i? 14-P of the relay again, the relay MI2 opens the contact MI 2-2 (Fig. 20 a), so that the relay i? I4 at the end of the machine cycle in which a group change has occurred when the cam- 11s contact CR 2 is de-energized.

In the machine game in which the group numbers have changed, the cam contact CR 58 (Fig. 20 c) closes a circuit from the main conductor 615 via the relay contact CC ii, the plug connection 665 and a relay STR to the main conductor 616 to control the pressure of the Initiate the sum and zeroing of the arithmetic unit. Through the cam contact CR 5 8, the relay 6Ti? kept excited up to the 295th degree of the next machine game in which the

Sum is written and the zeroing takes place.

At the end of the machine cycle in which a group change has occurred, the cam contact CR 119 (Fig. 20 c) closes a circuit via the now closed relay contact STR 2 and the relay S and keeps the relay energized up to the 275th degree of the following machine cycle, in which a sums and the

ίο reset.

The relay closes its contact SI and thus a circuit from the main conductor 615 via the cam contact Ci? 122, which is closed from the beginning to the 78th degree of the following total printing machine game, the now closed relay contact OTi? 1 and the relay LC to the main conductor 616. The relay LC switches its contacts LC-U to LCTH (Fig. 20d, 2oe), and the sums are written under the control

ao tion of the extraction device in connection with the pulse converter, which has already been described became. The converter forms the combined ones taken from the meter's removal device Lochi impulses in a single temporally different Digit pulse to select the corresponding digit type.

Each point of the removal device contains a number of digits contact segments 661 (Fig. 20 d, 20 e), a common contact bar 662 and a sensing brush 663, which is set according to the numerical value of the counter. The setting of the brushes 663 shown in FIGS. 20d and 20e corresponds, for example, to the sum 0044. The contact segments 661 with the same numerical values are connected to one another by lines 661. The lines 664 marked with the numbers 9 to ο are connected with the interposition of the cam contacts CR 97 to Ci? 106 connected to the pulse cam contact CB .

These cam contacts transmit pulses with the values 5, 3, ι, ο in combinations that are shown next to the contacts in FIG. 20d. Since the pulses triggered by the cam contacts CR 97 to CR 106 are effective in the same time sequence as the 5, 3, 1, o-pulses triggered by the contact CR 34 (FIG. 21c), the contact times are shown of the individual cam contacts CR 97 to CR 106 are omitted in the timing diagram. If z. If, for example, the brush 663 is set at one point of the removal device to the contact segment 661-9, digit pulses 5, 3, ο are transmitted by the cam contact Ci? 97. The cam contact CR 98 transmits the pulses 5, 3, the cam contact CR 99 the pulses 5, 1.0, etc. The pulse circuit runs, for example, for the units digit of the arithmetic unit, in which a 4 is set, from the main conductor 615 via the breaker contact CB, the Cam contact CR 102, the line 664-4, the contact segment 661-4, the brush 663, the common segment 662 and via the now closed relay contact STRU and the now converted relay contact LCL / to the socket 666. The sockets 666 of the individual points of the removal device are through connecting lines 667 are connected to sockets 668, to which the control magnets 861 of the converter are connected with the switching contacts of the relays PCC and RN in the basic position. It is noted that in the time from the beginning to the 90th degree of machine play, the relays LC and STR are energized and their contacts are closed or switched when the cam contacts CR 97 to Ci? 106 transmit the impulses S, 3, ο. The magnet 861 of the units position therefore receives the pulses 3, o, and the converter converts these pulse combinations into a pulse corresponding to the digit value 4 in the manner described, in order to engage the character wheel and turn it to position 4. In the same way, the sensed combination pulses 5, 3, ι, ο are transmitted to the converter at each point of the removal device and converted into a pulse corresponding to the numerical value and the type wheels are brought into the corresponding printing position. When all type wheels 860 (FIG. 22 a) are set, the total is written by transmitting a pulse at the iV time of the machine game.

In the 165th degree of machine play, the cam contact CR 17 (Fig. 20c) closes the circuit via the relay RN, which switches its contacts RNU, T, H, TH (Fig. 20e), so that a second pulse to the control magnet 861 of all positions of the converter is routed. This pulse runs from the main conductor 615 via the cam contact CR 80 and the now switched contacts U, T, H, TH of the relay i? IV to the corresponding control magnet 861 and on to the main conductor 615 prevents the writing of the zero in all positions to the left of the highest digit.

The counter is cleared in the last part of the machine game, in which the total is printed. It is controlled by electrical stop pulses generated by the converter at different times. The start pulses are sent to all start magnets AM of the counter in order to turn the counting wheel in the additive direction from its digit setting to the basic position in which the counting wheels of the machine described are in digit position 9. The stop pulses coming from the converter are timed in such a way that the nine's complement of the digit set in the counting wheel is added to set each counting wheel to 9. The stop pulses are preferably triggered under the control of the type wheel clutches, which in the manner already described. take effect under the control of the converter, so that simultaneously with the coupling of the character wheel clutch to rotate the character wheel up to a selected digit position, the stop pulse is also triggered and directed to the stop magnet. It is reminded

that the release lever 863 (Fig. 22 a, 22 b) of the converter is moved at different times of the machine game and therefore the type wheel starts rotating at different times. This is used to control character wheel contacts in order to transmit a stop pulse to the stop magnet SM at the same point in the counter. Immediately after the character wheel clutch is engaged and the clutch wheel 870 (Fig. 22 a.) Begins to rotate, the plate 898 attached to the clutch wheel 870 moves its inclined edge 670 the locking lever 896 clockwise so that its second arm 671 makes contact 672 closes. These contacts 672 assigned to each point of the writing unit therefore trigger different time pulses corresponding to the values ο to 9 (FIG. 21b).

Before describing the circuits for the transmission of the stop impulses, the impulse circuits for the excitation of the start magnets AM of all positions of the counter should first be described.

As already mentioned, the relay S (Fig. 20 c) is energized in the last part of the machine game in which a group change has occurred. »5 The cam contact CRiig maintains the excitation of this relay during the sums writing and resetting of the counter wheels up to the 275th degree. Therefore, when the cam contact CR 85 (Fig. 20 d) closes in the 140th degree of machine play, a circuit is created from the main conductor 615 via the now closed relay contact STR3 and the likewise closed contacts U, T, H, TH of the relay S to each of the starting magnets AM of the four digits of the meter and to the main 616 closed. All counting wheel clutches are therefore engaged, and each counting wheel that is not set to 9 is rotated by the complement of the number set in it in order to bring the counting wheel to position 9. 4.0 During the rotation of the counting wheels, stop impulses are sent to the stop magnets SM through a circuit to be described below. The relay PCC (Fig. 20c) is energized by closing the cam contact CR 15 in the 100th degree of each machine +5 machine play and kept energized up to the 315th degree. The relay PCC changes its contacts U, T, H, TH (Fig. 20e). The stop pulse circuit now runs from the main conductor 615 via the cam contact CR 82 (which is closed between the 116th and 273rd degree, in which time the type wheel contacts 672 are closed according to the start of the rotation of the coupling wheel 870), the corresponding contacts U, T, H and TH of the relay PCC, the connecting cables 667 between the sockets 668 and 666, the corresponding contacts U, T, H and TH of the now currentless relay LC and via the stop magnet SM to the main conductor 616. Since the total in the counter is assumed to be 0044 the brushes 663 of the units and tens of the removal device are on the contact segment 661-4, and the contacts 672 of these positions are closed in the 225th degree. The one from the cam | The start impulse triggered by contact CR 85 causes the counter wheel of the units digit to rotate by five steps from position 4 to position 9 until the stop magnet SM receives an impulse by closing the type wheel contact 672 at this point. In this way the counting wheel is stopped at the number position 9 !. The same takes place in the tens, in which a 4 is also set after acceptance. The zeros in the hundreds and thousands indicate that the entered sum 0044 is a positive or debit balance. The start impulse to the start magnets AM of these points initiates the rotation of the counting wheel by nine movement steps. The character wheel clutch is therefore effective for rotating the character wheel 860 in the counterclockwise direction at approximately the same point in time as the lever arm 881 with the character wheel 860 is pivoted as a result of the A 'pulse and the character wheel is rotated clockwise. This causes the writing of the number type o. The engagement of the character wheel clutch causes a late closure of the contact 672 to send a stop pulse to the magnet SM after the counter wheel has been moved nine steps and set to position 9.

If the counter wheel of the highest digit of the counter were at 9 (which corresponds to a negative or credit balance), then contact 672 closes to send a stop pulse in the 140th degree after engaging the type wheel clutch to select the nine type at the same time or a little before closing of the cam contact CR 85 to trigger the start pulse for the magnet AM. This prevents the clutch from engaging and the counting wheel remains in the nine position.

At the end of each machine game in which the counter is reset to the basic position, a test circuit is activated to determine whether the counting wheels have actually been reset to the number 9 position. If the machine is switched for total printing and resetting, this test circuit causes either the continuation of the card feed for processing the next group of cards or the interruption of the card feed if an error occurred when resetting the counter wheels. When the counting wheels are reset, the associated brush 663 is set to the contact segment 661-9 when the corresponding counting wheel is completely reset. In this position of the counting wheels, the transmission contacts 739 and (Fig. 18) of all counter positions are closed. Since these contacts 739, 741 (Fig. 20 d, 20 e) are connected in series, a circuit from the main conductor 615 via the cam contact CR 70 and the contacts 739, 741 to the relay SZB and to the main conductor 616 is closed towards the end of the machine game. The relay SZB is energized and provides a holding circuit through the contact SZB 1 via the coil H and the cam contact Ci? 73 ago, the one over most of the next

Machine play is maintained. The second contact SZB 2 of the relay SZB is in a circuit via a relay RE (Fig. 20 e), the excitation of which indicates an incomplete resetting of one or more counting wheels. This excitation circuit contains the cam contact Ci? y2 and the contact SCT 2 of a relay SCT (Fig. 20 c), which is energized simultaneously with the relay S and kept energized via the contact SCT 1 and the cam contact CR 74. When the cam contact CRy2 closes at the end of the machine cycle, the relay RE is energized as soon as any of the counting wheels has not been completely reset. The relay SZB remains de-energized in this case and its contact SZB 2 is closed, so that the circuit via the contacts SCT2, SZB2 and the relay RE to the main conductor 616 can be closed by the cam contact CR 72. When the relay RE is energized, it creates a holding circuit from the main conductor 616 via the relay coil H, the contact REi, the lines 673 and 625 (FIG. 20 a), the contact 624 of the stop button and the line 623 to the main conductor 615. The excitation of the relay RE does not take place when all digits of the counter are reset. The machine then continues to work and continues to feed and process the cards for the next group until another group change occurs. In order to continue with the card feed, if no errors were found, it is necessary that the relay MI2 is de-energized, which was kept energized by means of the relay contact P12-2 (Fig. 20c). The relay MI2 then closes the contact JW / 2-2 and through this the excitation circuit to the start relay R 14 (Fig. 20 a). During the total typing and resetting machine game, a circuit is generated from the main conductor 615 via the line 661, the relay contact MI 2-3 (Fig. 20c), the now closed contact P 1-3, the contact RE S in the normal position (da no error was found during the reset) and closed via contacts P 13-2 and CR 132 to relay P 12 and main conductor 616. A hold circuit for relay P 12 is established through contact P 12-1 and cam contact CR 46. The relay P 12 opens the contact P 12-2, so that the relay MI2 is de-energized when the cam contact CR 42 opens.

Numerous causes can prevent all counter wheels from being completely reset. Was z. For example, if you mistakenly omit the plug connection 667 in the units position, the normal start pulse is passed from the cam contact CR 85 to the start magnet AM at this position, but no pulse reaches the stop magnet SM of the units position. The brush 663 of the removal device is therefore rotated by the counter wheel into the position corresponding to the number 3, and the counter clutch is activated by the first mechanical! Release pin 752 disengaged. The units transfer device, known per se, which is used in the machine, adds a 1 in the units place and accordingly the brush 663 is set on the contact element 661-4. The contacts 739 to 741 of the ones place therefore remain open; the SZB relay is not energized and the SZB 2 relay contact remains closed. When the cam contact CR 72 closes in the 347th degree of machine play, the relay RE is therefore energized and can only be de-energized again by pressing the stop button.

The cam contact CR 133 (Fig. 20 c) closes in the 5th degree of the following machine game a circuit from the main conductor 615 via the line 661, the contact M 12-3, which is now in the rest position, which is switched or closed by the energized relay RE Contacts RE 5, RE4, cam contact Ci? 133, the contact P 14-2 and the relay P 13 to the main conductor 616. The holding circuit for the relay P 13 is closed by the contact P 13-1 and the cam contact CR 45 and maintained up to the 315th degree of the machine play following the sum , which can be referred to as intermediate idle clearance. When the cam contact Ci? 48 closes in the 305th degree of this intermediate idle play, a circuit is closed from the main conductor 615 via the now closed relay contact P 13-2 and the relay Pi to the main conductor 616 and the relay P 1 is energized and through the cam contact CR 50 kept excited. By energizing the relay P 1, a second total pressure and zeroing machine game is initiated in the same way as has already been described. In this machine game, assuming that the counting wheels of all digits of the arithmetic unit except for the ones digit have been set back to the nine, a total is written again with a 4 in the ones digit, since this counter wheel was not set to 9. This 4 indicates in writing that an error was made when resetting. The previously described reset test circuit is set up again, but remains ineffective because the relay RE is already energized and is kept energized. However, in order to prevent a repeated repetition or a third total pressure and reset machine play, ■ a relay P 14 is provided, which in the 273rd degree of the intermediate idle play when the cam contact Ci? 47 (Fig. 20 c) is closed by a circuit via the contacts P 12-3, PiSS, the line 674, the contact RE 3 and the excitation coil P 14.-P to the main conductor 616 is excited. A holding circuit is established from the main conductor 616 via the relay coil P 14-H, the relay contact P 14-1, the line 673 and the contact 624 of the stop button to the main conductor 615. The relay P 14 interrupts the pulse circuit via the relay P 13 through the contact / ⁵ 14-2 during the second summation typing and resetting machine game that follows the detection of an error, so that it cannot be set up again. A signal lamp SL connected in parallel to the holding winding of the relay RE (FIG. 20e) indicates the error by lighting up, and the second one

written sum shows the counting point in which the reset error occurred. In order to determine the reason for the error and to be able to correct it, the card feed is interrupted. When the relay RE is excited, its contact RE 2 (FIG. 20 a) is opened and the excitation circuit for the relay R 13 is interrupted. This therefore opens contact 7? 13 α, so that the relay R 14 can not be energized.

whose contact R 14b is in the excitation circuit of all clutch magnets FP, FG, RP, RG and CF. Therefore, none of the four clutches in the card feeder can be engaged, and since the magnet CF of the main clutch is not energized, the card feed remains interrupted. After the error has been eliminated, the holding circuit for the relays RE and P 14 is interrupted by pressing the stop button, and the machine can continue the card feed by pressing the start button and closing its contact 617.

Claims (4)

Patent claims: i. Arrangement for calculating machines, in which the arithmetic unit is automatically deleted after the sums have been written, with a device for removing the sum set in the arithmetic unit elements, characterized in that after the arithmetic unit has been deleted (counting wheels 724) a test device (contacts 739 to 741, relays SZB) becomes effective, which determines the position of the elements of all arithmetic units returned to the basic position and, if at least one counter is incompletely reset, initiates a second machine cycle to repeat the total writing (by means of relay RE, P 13), in which both the reset and the not reset arithmetic unit places corresponding digits are written. 2. Arrangement according to claim 1, characterized in that the counting wheels forming the arithmetic unit under the control of the removal device (661 to 663, contacts Ci? 97 to Ci? 106), the pressure control device (magnet 861, coupling wheels 870) and the extinguishing device (relay STR, PCC, Magnet SM, contacts 672) can be rotated further to the basic position via their position corresponding to the set sum. 3. Arrangement according to claim 1 and 2 in connection with controlled by recording media machines with a device for group control, characterized in that when the group number is changed, the supply of the recording media, for. B. punch cards, interrupted (by means of relay MI2, R 14) and only initiated again when the arithmetic unit is deleted after the total writing caused by the group change and all arithmetic unit wheels are returned to the basic position, while at least one arithmetic unit point is resumed if the reset is incomplete or not done the card feed is prevented (by relay i? £). 4. Arrangement according to claim 1 to 3, characterized in that when a faulty deletion of the arithmetic unit is detected, a signal, for. B. SL lamp, is triggered to display the error. In addition 9 sheets of drawings © 9517 4.54