DE1153197B - Adding machine - Google Patents

Description

The main patent relates to a calculating machine with counters that can be incremented by electrical impulses which are supplied by a scanning device containing a contact bank, further comprising a by the buttons actuated switching device, through the certain contacts of the scanning device are switched so that when scanning a connection between a voltage source and a Counter is established, whereby a group of contacts for all digits at the same time, the number of which corresponds to the key pressed in the respective position can be switched through; also the den Contact groups assigned to the respective locations then all in sequence one after the other through the scanning device be connected to the associated counters and a carry that has arisen in one place is fed to the counter of the next higher position before the contact group assigned to this position is connected to the associated meter.

The subject of the main patent is therefore a calculating machine with a full keyboard and a multi-digit keyboard Register consisting of counters that can be incremented by electrical impulses, with the values in parallel can be entered into the keyboard and inserted one after the other into the counter in places. The present The invention now relates to a development of the subject matter of the main patent, such that when actuated a multiplier key, the values stored in the counters can be shifted by one place and that a number of working cycles of the machine corresponding to the number of operating cycles of the multiplier key actuated is triggered, during which the counter is supplied with the values entered on the keyboard will. These features are only claimed in combination with the features of the main patent.

In the case of a calculating machine which is further developed in the manner claimed, multiplications can thus be carried out can be carried out in a manner known per se by placing the multiplicand on the keyboard and then one after the other the multiplier keys corresponding to the individual digits of the multiplier presses.

The invention will now be based on an exemplary embodiment in conjunction with the drawing explained. It means

Fig. 1 is a circuit diagram of a calculating machine according to the invention,

FIG. 2 shows a schematic representation of one of the glow counting or step switching tubes used in FIG. 1 with the most essential circuit elements required for operation,

Addendum to patent 1,086,921

Applicant:
Bell Punch Company Limited, London

Representative: Dr.-Ing. E. Sommerfeld

and Dr. D. v. Bezold, patent attorneys,

Munich 23, Dunantstr. 6th

Claimed priority:

Great Britain 6 September to 22 November 1956
and July 3, 1957 (No. 27 383, No. 35 797 and No. 21105)

Norbert KiIz, Vernon Watkins Sparrow,
Christopher Frederick Webb and Robert Wilburn,

London,
have been named as inventors

Fig. 3 is a top plan view, partly in section to a calculating machine according to the invention; Fig. 4 is a partially sectioned side view the machine shown in Fig. 3 and

Figures 5 to 12 are partial views of the machine shown in Figures 3 and 4 showing more details.
The embodiment of the invention described below is a desktop calculating machine with a full keyboard comprising twelve rows of keys.

Fig. 1 shows the circuit diagram of this machine. The rows of keys each contain nine keys which are designed so that when they are actuated, an associated first pair of contacts is closed and an associated second pair of contacts is opened. The contact pairs are referred to below as S and K contact pairs and are distinguished by two index numbers. The upper index indicates the key row to which the contact pair belongs, and the lower index the number of the key in the

309 668/264

apt number. The contact pairs S \ and K \ are therefore the contact pairs of the first key in the third row of keys.

The nine contact pairs of a key

and divisions effective and not of interest here. The slip ring _{segments O 9} to Z ₉ are each connected to summing devices or counters O ₁₀ to Z ₁₀ , which are gradually increased by electrical pulses

series existing. Contact groups are in a 5 can be advanced and each via one

own diode O ₁₁ to Z ₁₁ or another electronic directional conductor with a busbar / are connected.

Before the contact group O ₀ to O ₈ and the

more precisely to be described way connected with nine contact pieces, the printed circuit or
can be designed as contact pieces embedded in a suitable material or in any-. ^ «« * ^^^^^^^ ^ ₀ ^ ^ _{8 Uii} vi. uwu ^ s "- in another suitable way in the form of a circular slip ring segment O ₉ , but not necessarily on an end face of a contact plate at the same height as this is a net. Contact piece pair EE is arranged, which is so the ■ the assigned the first row of keys contact it by a revolving brush F ¹ overlined pieces are labeled O ₀ to O _8, which may be of the permanently in operation, rotates the second row, the designations P ₀ to P ₈ and so on to 15 and the individual contact pairs with each other or those for Z ₀ to Z _8. In the present machine, which contains contact pieces with the associated slip rings, twelve rows of keys and is able to bridge over for calculations in the ments. The already mentioned decimal system is intended, a desired brush F is so arranged that they zugeord- during a number of emer certain row of keys zugeord- rotation via the contact pieces O ₀ to Z ₈ and nine Contact pieces by actuating a 20 the slip ring segments O ₉ to H strokes and thereby key can be selected in this row of keys. How the individual contact pieces with the associated many contact pieces are selected depends on the slip ring segments being shorted. The brush F administrates whether the machine binds to addition or multiplication also binds the contact pieces A with the addition or subtraction or division is set. In the associated slip ring segments O ₉ to H and the first case is the number of selected or 25 pairs of contact pieces BB ₁ and CC ₁ . Through-connected contact pieces equal to the value The contact pieces C, B, which are arranged in front of the individual of the actuated key, while in the second case the groups O ₀ -O ₈ to Z ₀ -Z ₈ , are the number of selected contact pieces equal to that of a trigger electrode T. \ of a tube T ₉ or with the complement of nine of a cathode Tj of a tube T ₃ corresponding to the key, where number is. On the subtraction and division, the contact _{pieces C 1} , B ₁ , which are not discussed in more detail before the corresponding, should be used here. corresponding slip ring segments O ₉ to Z ₉ are on

The contact pairs S \ to Sl of the first key-a positive potential M are connected, row are all connected in parallel. The contact The contact pieces A are equipped with an anode T]

Pairs K \ to Kl are connected in series and connected to a tube T ₄ . The tubes T ₃ , T ₄ are also connected in series with the parallel 35 connected as a two-stage carry memory. One of the contacts S ₁ ¹ to S \. the contacts EE is equipped with a device for

The first contact piece O _{0 is connected} to the first key generation of a single pulse, which contact pieces assigned to the row _{contains a capacitor i7 4} , which is normally the contact of the contact pair S \. connected; which have a movable contact U ₁ and a resting contact piece O ₁ to O ₈ each between the contact U _{2 of} a switch U with a power supply two of the contact pairs K \ to Kl, so that the source for charging the capacitor is connected

is. When the movable contact U _{1 is switched} from the contact U ₂ to the contact U _s , the capacitor is connected to the mentioned contact E , 45 so that when the contact pair EE is bridged by the brush F ^1, a positive pulse is sent to a release electrode TJ of a tube T ₁ got.

The contact pieces O ₀ to Z ₈ and the associated slip ring segments O ₉ to H are circular and

stationary contact CS1 of the changeover switch CS _{4 is} arranged concentrically on a contact plate. Who are bound. Brush F is concentric to the contact pieces and

The arrangement described above applies to all of the slip ring segments mounted so that they are at the twelve rows of keys that the machine contains. Turn the contact pieces O _n to Z _{11 one after the other}

Each contact piece group is an ₉ to H extending parallel to it with the associated slip ring segments O slip ring segment O bridges ₉ to Z ₉ assigned 55th In the drawing, this arrangement is net. Between two adjacent groups, each shown in a straight line for the sake of simplicity, so that nine contact pieces O ₀ -O ₈ to Z ₀ -Z ₈ are each one revolution of a brush of a movement from the three contact pieces C, B and A on the right. The end of Fig. 1 corresponds to the left end. Contact pieces C, B are contact pieces C ₁ or B ₁ if the brush F ¹ bridges the contacts EE

assigned, which are arranged in front of the respective Schleifringegmen- 60 and the movable contact U _{1 of} the switch U on th O ₉ to Z ₉ , if you apply resting contact U ₃ in Fig. 1, the capacitor goes from right to left, namely in the direction of Z7 ₄ through contacts CS? and CSl a two-way in which the contact arrangement is swept over by a switch CS ₅ to a trigger electrode T \ of a brush F while the contact tube T _{1 is} connected, to which a positive piece A is fed at the same height as the front 65 pulse will. The tube T ₁ is interconnected with one end (that is to say the right end in FIG. 1) of the associated tube T ₂ , which in the idle state has slip ring segments O ₉ to Z ₉ . That also carries electricity. A cathode T \ of the tube T ₁ is connected to the illustrated contact piece D is only connected during subtractions of a cathode 1% of the tube T ₂

so the contact piece O ₁ lies between the contact pairs K \ and K \ , while the contact piece O _{8 is connected} between the contact pairs K \ and K \ .

The contact pair Kl is connected to a stationary contact CS \ of a single-pole changeover switch CS ₄ , while one contact of the parallel-connected contact pairs S \ to Sl is connected to another

the anodes Γ 'and 71 of the tubes T ₁ , T ₂ are coupled via a capacitor U. The tubes T ₁ , T ₂ are connected so that only one of the two tubes is conducting and the other is blocked.

When the movable contact CS \ is in contact with the stationary contact CS'i, the anode T \ of the tube T _{1 is} connected to all S- contact pairs of the various rows of keys via the changeover switch C5 _4. If, on the other hand, the movable contact CSl of the switch CS _t rests on the resting contact CSl , the anode Γι of the tube T _{1 is} directly connected to the j £ -Kontaktpaaren of the various rows of keys.

_{The contact pieces O 0} to Z ₈ assigned to the rows of keys are normally at zero potential. When the brush F bridges the contact pairs C, C ₁ and B, B ₁ , a positive potential of M is successively applied to a release electrode T \ of a tube T ₉ and the cathode T \ of the tube T ₃ . The voltage applied to the cathodes of the tubes T ₁ , T 1, T _3, T ₄ and T ₉ is, for example, -300VoIt, as is indicated in FIG. The anode T \ of the tube T ₁ and the anode T _{1 of} the tube T ₁ are connected to anode resistors T \ and T \ , which are dimensioned so that a potential of about -150VoIt is applied to the contact pieces connected to them when the Conduct tubes T ₁ and T ₁ .

With the slip ring segment H that is associated with none of the rows of keys, a counter ₁ is H (accumulator) is connected, which serves to O if appropriate record from the contact piece ΛΙ between the contact piece groups Z ₀ to Z ₈ and O _{0 8} a carry, the occurs in counter Z ₁₀ .

In front of the contact pieces EE (that is to say on the right in FIG. 1) there is a pair of contacts GG; one of these contacts is connected to the positive pole of the voltage source, the other with a trigger electrode of the tube T. Tl.

If the machine is in operation, but no key has yet been pressed, the tubes T ₂ and T ₉ carry current, which is indicated by hatching, while the tubes T ₁ , T ₃ , T _{i are} blocked. The tubes T ₁ and T ₂ are connected so that one of the two tubes is always conducting and the other is blocked.

The machine is constructed in such a way that a motor that drives the moving parts is automatically switched on when adding or subtracting after pressing a corrected key in a row of keys. The contacts U ₁ , U _{3 are} closed by the motor and the capacitor U _{i is} thereby connected to one contact piece E.

When the brush F ¹ is rotated by the motor, it bridges the contact pieces EE, and as a result, a positive pulse reaches the readout electrode Γ} of the tube T ₁ via the contacts CS ?, CSl of the switch CS ₃ , so that this tube is conductive and the tube 7 " _{a is} blocked. The potential at the anode T] of the tube T ₁ is, depending on the position of the switch CS _4, either applied directly to the S or -K contact pieces of the various rows of keys, as has already been mentioned.

As the brush continues to run, the brush F bridges the contacts CC ₁ and then the contacts BB _v. As a result, a transfer memory is reset, as is explained in more detail in the main patent.

When the brush F slides over the contact pieces O _n to O ₈ , which belong to the first row of keys, the associated slip ring _{segment O 9} is supplied with the potential at the various contact pieces in the form of a pulse. The pulses pass from the slip ring segment O ₉ to the counter O ₁₀ , so that the latter finally registers a number which corresponds to the value of the actuated button in the first row of buttons.

When turning further, the brush F bridges the contacts CC ₁ , which are in front of the contacts P ₀ to P ₈ assigned to the second row of keys ίο. As a result, a pulse reaches the triggering electrode T% of the tube T ₉ , which remains conductive or is switched to the conductive state, depending on whether a transfer is to be carried out or not. If a carry has to be made, T _{4 is turned on} and T _{3 is} blocked. When the brush bridges the contact pieces B, B ₁ which precede the second contact group P ₀ to P ₈ , the tube T \ remains blocked, as in the case of the first contact group. When the brush then slides over those contact pieces of the second group P ₀ to P ₈ at which there is a potential from the anode T \ of the tube T ₁ , a corresponding number of pulses reaches the counter P _{10 via the slip ring segment P 9} , which causes the latter is advanced by an amount that corresponds to the value of the key operated in the second row of keys. The processes described are repeated for the contact piece groups of the other rows of keys.

When the brush F has made one complete revolution, it bridges the contacts GG, as a result of which a positive voltage is applied to the triggering electrode T 1 of the tube T ₂ , by means of which the tube T _{2 is} conductive and the tube T _{1 is} blocked.

If a counter assigned to a row of keys is incremented beyond the largest possible numerical value for which it is designed, a unit is transferred to the counter in the next higher row. For this purpose, a two-stage transfer memory is provided, which interacts with the mentioned contact pieces A , which are arranged at the same height as the front ends of the individual slip ring segments and carry a potential when the counter assigned to a row of keys has reached its maximum capacity and the following counter Carry must be supplied. The arrangement is made so that the contact pieces A lying between adjacent rows of keys assigned contact piece groups are connected to voltage when a counter has reached its maximum capacity.

In the calculating machine shown in FIG. 1, it is assumed that the counters are designed for the decimal system. When a counter switches from 9 to 0, a pulse is fed from this counter via a diode or the like to a busbar / from which it arrives at the triggering electrode T \ of the tube T _n , so that it becomes conductive. When turning further, the brush F bridges the contacts BB ₁ , whereby a positive voltage from the terminal M reaches the cathode Tl of the tube T ₃ , whereby the latter is blocked and the tube T _{4 is} conductive. The tubes Τ. _λ , T ₄ are connected together in such a way that the tube T _x becomes conductive when the tube T _{3 is} blocked, while these tubes do not influence each other under other conditions. So if a meter sends a pulse to the busbar /, J conducts ₄ , and is connected to the contact ^, which belongs to the slip ring segment of the next higher row of keys

a potential, and a unit is added to the counter of the next higher position before the brush F begins to scan the key-controlled contact pieces of the next higher row. While the tube T ₄ is conducting, the tube T _{9 is} blocked.

After a transfer has been carried out and the contacts of the next higher row have been scanned, the tube T ₄ is blocked in that the tube T ₉ becomes conductive by bridging the contacts CC, which are between the aforementioned contact group and the next contact group.

When turning further, the brush F then bridges the contacts BB ₁ , and the tube C ₃ is made ready to receive a new transfer pulse, which could also occur when the brush F slides over the first contact of the next higher contact group. The tube T ₁ only becomes conductive after the tube T _{3 has} been made conductive by a transfer pulse from the busbar and has subsequently been blocked again by a pulse via the contacts BB ₁ to its cathode. The tubes T ₃ , T _t thus represent a two-stage carry memory that is common to all counters.

As mentioned, when a key is pressed in the row of keys, the corresponding pair of S contacts is closed and the pair of iC contacts is opened. If the third key is pressed in the first row of keys, the contacts S \ are closed and the contacts K \ are opened. When the moving contact CS! of the switch CS ₄ on the contact! is applied, after bridging the contacts EE by the brush F, a potential comes from the anode Ti of the tube T ₃ via the third contact pair S \ and the contact pairs K \, Kl, Kl to the contact pieces O, O ₁ , O ₃ , so that three pulses are fed to the slip ring segment O ₉ and from this to the counter O ₁ ″ when the brush F slides over the contact piece group assigned to the first row of keys. If the counter O _{10 was} initially 0, it will then register the value 3.

The other position of the switch CS _i applies to subtractions and divisions, which are of no interest here.

The tube T _{9 of} the carry memory can optionally be omitted, while the circuit arrangement as shown in FIG. 1 remains otherwise. Such a circuit arrangement ensures that the tube T ₃ is ready again to receive the next pulse in the shortest possible time after receiving a pulse from the busbar 7, since the first pulse has been taken over _{by the tube J 4.} The tube T ₉ is used to keep the tube Γ _{Λ locked.} The transfer device described thus enables a unit to be transferred from any counter to the counter of the next higher position with only two or three electron tubes.

The present calculating machine contains a number of gas-filled step-up switching tubes with several cold cathodes, as shown for example in FIG. The present machine, based on the Base of the decimal system works, contains tubes with ten cathodes.

Between a common anode and a cathode of the ten L \ to L \ L of the counter tube shown in Fig. 2, a glow discharge can be maintained. The glow discharge can be switched from one cathode to the next by a pulse. If you assign the decimal digits from 0 to 9 to the cathodes, a desired decimal digit can be stored in such a tube by igniting a certain cathode.

The mode of operation of such glow counting tubes is described in the main patent.

The basic mechanical structure and the ίο mode of operation of the machine are detailed in the main patent and can be understood with reference to FIGS. 3 to 12, in which the same reference numerals as used in the main patent. So much for the machine at hand from the machine of the main patent differs, it will be explained in more detail below.

In order to be able to carry out a multiplication with the present machine, a movable contact L ¹ ? A switch L ^{10 is switched} to a fixed contact L ¹ ″. This connects a step-by-step switch tube L to a contact piece G and, in addition, switches the trigger electrode T _{2 of} the tube T ₂ into a circuit with the cathode No. O of a counting tube L. These processes are effected by actuating a multiplication key 39 in a row of function keys 40 (FIG. 3).

The machine contains a series of multi-poster keys, numbered 0 through 9, located in a row of multiplier keys 38 (FIG. 3). By pressing one of the multiplier keys, the glow discharge in the counter tube L is set to a specific cathode. Normally the tube is in the zero position. By pressing a multiplier key, the counter L is set to the nine's complement of the number with which the key in question is designated. Thus, if a multiplication by six is to be carried out, pressing the multiplier key No. 6 causes the counter tube L to be set to 9-6 = 3, that is, six steps are required to reset the tube to zero. When the tube reaches its zero position, the release electrode T \ is supplied with a potential that makes the tube T ₂ conductive, so that the tube T _{1 is} blocked and the voltage is switched off from the contact pieces of the various rows of keys.

During the execution of an automatic multiplication of a multiplicand by a multiplier instead of a control electrode ¹¹ of the counter tube must L L are connected to a contact of the contact pair with the GG, and the other contact to be connected to the anode T \ of the tube. 1 If, for example, the 851 is to be multiplied by 97, the multiplication key 39 in the function key row 40 is operated, and then the keys 1, 5 and 8 of the first, second and third row of keys are operated. By pressing the multiplication key 39, the keys representing the multiplicand are locked in their depressed position. By pressing the multiplier key no. 7, the counter tube L is set to 9 to 7, i.e. to 2, and the drive motor 24 of the machine is started. The brush F begins to rotate and bridges the contacts EE, as a result of which a single pulse reaches the triggering electrode T \ of the tube T ₁ , which is thereby ignited while the tube T _{2 is} blocked. When the tube T ₁ conducts, the contact

Pieces Q ₀ to Q _{7 of} the third row of keys, the contact _{pieces F 0} to P _{4 of} the second row of keys and the contact piece O _{0 of} the first row of keys via the switch contacts GS * and GS] of the switch CS ₄ to voltage.

By pressing the multiplier key no. 7, a glow discharge was ignited at the cathode Lf in the counter tube L. When the brush F slides over the contact groups assigned to the individual rows of keys, it transmits eight pulses to the counter Q ₁₀ , five pulses to the counter P ₁₀ and one to the counter O ₁₀ during its first rotation. After completion of the round brush completes a circuit through the contact pieces GG to the control electrode ¹¹ of the counter tube L L, thereby the glow discharge at the cathode L \ is cleared and proceeds to the electrode L \. Still no pulse, and the tube T ₂ this gets to the trigger electrode of the tube Tl _T2 remains blocked. The ignited tube T ₁ is connected to the contacts of the various rows of keys via the changeover switch CS ₄ , and the brush therefore again transmits one pulse to the counter O ₁₀ , five pulses to the counter P ₅₀ on its second rotation, causing this counter to be 0 is switched on and a pulse is _{transmitted to the counter ß 10 in the} manner described. In addition, the counter Q ₁₀ receives eight more pulses from the energized contact pieces, so that the counter O ₁₀ receives a total of seventeen pulses. Here, a pulse is transmitted to the counter R ₁₀ so that the numbers 1, 0, 7, 1 are now in the counters 0 _JO , P _1n , Q _1n , R _10. These operations are repeated until the glow discharge in the counter tube L according to the seventh revolution of the brush F from the cathode L \ V to the cathode ₁ passes. When the glow discharge passes from the cathode V ₁ to the cathode LJ, a pulse is transmitted via the contacts L ¹ J, Vl to the triggering electrode Tl of the tube T ₂ . The tube T ₉ is thereby conductive and the tube T _{1 is} blocked. The keys 1, 5, 8 in the first, second or third row of keys can now either be released by the operator or unlocked by an unlocking button.

You could now enter the digits 1, 5, 8 in the second, third and fourth row of keys and the Then multiply the multiplicands by 9 in the manner described, so that you get the final result 74528 received. As will be explained in more detail below, the present machine is but designed so that between two multiplication steps in which the multiplicand with two consecutive digits of the multiplier is multiplied, automatically shifting the in the counters is carried out one place to the left, so that it is sufficient to enter the individual digits of the multiplier to be keyed in one after the other.

The machine according to the invention is provided with a lock that prevents in a certain Button row several buttons can be operated at the same time. The machine is as well provided with a delay device which ensures that the key or one through it the actuated device can only return to the rest position after a period of time has elapsed, which is sufficient to allow the machine to perform the function initiated by the actuation.

A mechanical delay device is described in the main patent. The delay should be at of the present machine at least, about 0.1 second.

The present calculating machine makes it possible to carry out electrically what was often done mechanically in the previous table calculating machines by moving a slide carrying the counters. For this purpose, the content of the ίο individual counters is transferred to the counters in the next higher position, which corresponds to a multiplication by a factor of 10 in the decimal system. The shift is effected by feeding a pulse train to the individual counters until a carry occurs and then feeding the remainder of the pulse train into the counter in the next higher position. If, for example, the numbers 3, 1, 4 are in the counters in the first, second and third row, the number 3 is transferred from the counter in the third row to that of the fourth, and the number 1 from the counter in the second row, in a manner to be described below into that of the third and the number 4 from the counter in the first row into that of the second, so that the number 3140 is now in the arithmetic unit. The implementation of this shift will now be described in more detail below. For this purpose, the present calculating machine contains two further sets of contacts in addition to the arrangement described in the above and in the main patent. These contact sets are interconnected with two tubes through which a voltage can optionally be applied to one of the contact sets. Each contact group of the one set is assigned to a slip ring segment of a specific row of keys, while the corresponding groups of the other contact set are assigned to the slip ring segments of the next row of keys. The additional contact sets and the associated slip ring segments are scanned ^{by two rotating brushes F 1} , F ^2. The additional contact sets and the associated slip ring segments are preferably designed as a printed circuit on a contact plate, but they can also consist of solid metal parts which are embedded in a suitable insulator material.

The circuit arrangement shown in Fig. 1 allows to carry out an arithmetic operation which is referred to in the following as "multiplication by 10" shall be. Of course, the arrangement is not limited to the decimal system, but leaves apply in the same way to other number systems.

Assuming that the maximum capacity of the counters is ten, the circuit arrangement contains a set of ten contacts and a further set of new contacts for each individual row of keys. The first set thus contains twelve groups with ten contact pieces each, which are labeled _{O 12} to O ₂₁ , P ₁₂ to P ₂₁ , etc. to Z ₁₀ to Z _21. The other contact set contains twelve groups with nine contacts each, which are labeled O ₂₂ to O ₃₀ ... Z ₂₈ to Z ₃₀ . The contact pieces O ₂₂ , P ₂₂ to Z _{22 are at the} same level as the contacts O ₁₃ , P ₁₃ ... Z ₁₃ . From Fig. 1 it can be seen that the first contact of the individual contact groups of the second contact set is at the same height as the second contact of the corresponding contact groups of the first contact.

309 668/264

11 12

clock rate lies. Before the first contact of the individual show. When set to the multiplication of the nen contact groups is of the first contact set, so movable contact CSl of the changeover switch CS ₁ at the front of the contacts O _12, P ₁₂ to Z _12, is a respective associated with the anode Tl of the tube T ₁ Kon contact E ° arranged. Except in the contact cycle C \. An input electrode H _{2 of} the counter / ^ row O ₁₂ to O ₂₁ is in front of the individual, Zs ° -Kon, tak- 5 is a contact F ° with the state switched on during multiplication. The contact set P ₁₂ tional contact of the changeover switch CS ⁷ and the brush F ¹ _{assigned to Z 12} touches connected to their slip ring segment H. The switch CS ₅ circulation, which connects in front of the individual contact groups, connects the release electrode TJ of the tube T ₈ via arranged contact ^{pieces F 0} first. Then the contacts EE with the device U to cross them to generate a single pulse next to the contact F ^0. The electrode L _{11 of} the neten contact FA the contact groups O ₁₂ bis. Z ₁₂ counter tube L is connected to the anode T 'of the tube T ₁ via the switch CS ₈ and the consind the slip ring segments Z ₉ , F ₉ ... P ₉ , O ₉ clocks 3-3. The following are connected: the slip ring switch CS ₀ causes the release lever segments O ₉ to Z ₉ with the inputs of the O ₁₀ trode 1% of the tube T _{5 to} receive a positive pulse to Z ₁₀ ; the slip ring segment H with the input 15 is when the contacts GG through the brush F ^{1 of} the counter Ff ₁ ; and the slip ring segment L _{1 are} bridged at. If the machine is set to multi-setting, the machine is set to multiplication via plication and a multiplier key is operated on switch CS ⁷ with the input of counter H ₁ , brush F ¹ bridges the contact and when the machine is set to division with clocks EE, and the trigger electrode of the tube Tl T ₆ the input electrode of the counter tube L. the con- o is _a scarf clocks e ^0, F ⁰ applied to a pulse ₅ through the contacts CSl and CS'i front of the individual Schleifringsegmen- ters CS, the tube T ₀ th Z ₉ to O ₉ are at the same level as the power and the tube T ₅ blocks. If the corresponding contacts E and F is ^{0 0} ₅ blocked the first con- tube T, are connected to the anode T \ clock rate O ₁₂ to Z _12th The contacts E ⁰ connected to the contact set O ₁₂ to the tube T ₅ and assigned to the slip ring _{segments Z 12} are connected to a tripping 25 th Z ₉ to O ₉ assigned contacts E ⁰ on the ground electrode T1 of a tube T ₈ . The front of the potential, and when the brush F ¹ then the Kon-Schleifringsegrnenten Z ₉ to O ₉ arranged contactless couple Z? ^{0 is} bridged, the in the idle state clocks E ⁰ are connected to an anode Tl of a tube T ₅ negatively biased trigger electrode TJ of the, the contact groups O ₁₂ to O ₂₁ ... Z ₁₂ tube T _{8 is connected} to ground potential, so that the up to Z ₂₁ of the tube T are connected to an anode Tl ₈ Toggle ₃₀ ignites tube T ₈ and to Z ₂₁ in the closed contacts O _12th Contacts O ₂₂ to Z ₃₀ are applied when voltage is applied. If the tube T ₈ conducts, the machine is set to multiplication via one, the tube T _{7 is} blocked, and therefore no voltage switch CS ^{3 is connected} to an anode T \ of a tube T ₇ and the contacts O ₂₂ to Z ₃₀ . In the case of a fully closed, the cathode and the cathode of which the brush F ¹ continuously circulates, the tube T _{8 is then} connected to the 35 of each contact group via the associated busbar / via a pulse lock G _5. If the tube T ₅ blocked slip ring segments on the anist, the pulse lock G ₅ prevents the excluded counter from transmitting and this therefore advances a pulse ten steps to the release electrode T a of the tube T _a. Except in which is allowed, however, that a carry pulse reaches _{the counters O 10} , P ₁₀ , ß ₁₀ the digits 3, 1, 4 geKathoden of the tubes T ₇ , T _8. 40 stores and the machine is on multiplication

The tubes T ₇ , T ₈ are connected so that they are set. If the brush F ^1, the contacts EE normally both remain blocked, if their bridged, the triggering electrode Tl of the cathodes is fed via the pulse lock G ^ a pulse tube T ₀ a pulse. The tube T _{6 is} fed. However, if tube T ₈ stops and tube T ₅ is blocked. The anode Tl is already in the conductive state when its 45 of the tube T ₅ and the con-cathode connected to it and the cathode of the tube T ₇ an over-clock E ^a , which is fed before the slip ring _{segments Z 9, the} transmission pulse Tubes T ₈ to O ₉ are, therefore assume ground potential. locked, and the tube T ₇ conducts. If the brush F ¹ the contacts E ⁰ , which before the

The tube T ₅ is bridged together with the tube T ₆ - slip ring segments Z ₉ to O ₉ lie,

switched that 'only one of these tubes at the same time 50 the trigger electrode Ta of the tube T _{8 is} grounded,

can guide. When the machine is idle, the tube T ₈ ignites and the one with it

the tubes T ₂ , T ₅ , T ₉ , while the tubes T ₁ , T ₃ , anode T \ connected contacts O ₁₂ to Z ₂₃ are

T ₄ , T ₆ , T ₇ , T _{8 are} blocked. "the energized. When the brush F ¹ the

In the case of additions, subtractions and divisions of contacts O ₁₂ to O ₂₁ with slip ring segment Z ₁ , a movable contact CS \ of a switch is bridged, ten pulses are generated, which are fed to switch CS ₅ on a stationary contact CS1 , counter Z ₁₀ will. The counter Z delivers ₁₀ and the trigger electrode T \ of the tube T ₁ is connected to the case via a diode Z ₁₁ and the lock G _{5 is} a device for generating a single pulse U carry pulse to the cathode T? and T | the connected. In the case of the multi-tubes T ₇ or T _{8 of} interest here, whereby the tube T _{8 is} blocked plications, the device U for generating a 60 and the tube T. becomes conductive. In this way the single pulse via a contact CSl be ₅ to a trigger electrode of the tube Tl T _1, pieces O ₂₂ to Z ₃₀ set the switchover to the anode of the tube T ₇ connected contact ester CS to voltage. Since the connected. When switching the machine brush F ^a via the contact O _3n and the multiplication, six switches, namely slip ring segment L _{1 is} slid, the ignition remains the switches CS ^, CS _V CS ₅ , CS ₇ , CS _H , CS _a actuated. 65 of the tube T _{7 has} no effect. When the brush F ^{1 is in} the circuit diagram of Fig. 1, the switches with the contact pair F ° -F ° are reached, which is labeled in front of the contact function symbol, which the respective digit group P ₁ to P ₂₁ and the slip ring _{segment Y n} ment is in the corresponding arithmetic operations, a positive pulse is sent to the cathode Tl

13 14

and T? of the tubes T ₈ or T ₇ , which ignites the through the tube T _8. When the tube T ₇ is ignited, it blocks. When the brush ¹ F then E ⁰ - T _s tube are bridged associated with its anode Tl contacts before the contact group contacts P ₁₂ O ₁₂ to ₂₁ .. O .Z ₁₂ to Z ₂₁ in tension until P ₂₁ and the associated slip ring segment Y ₉ so that the counters Z ₁₀ to "O _{10 are} supplied with pulses, the triggering electrode of the tube T _{8 will be} a 5 when the contacts O ₁₂ to Z _{01 are} supplied with the pulse that ignites this tube. If the Slip ring segments Z ₉ to O _9. Brush F ¹ then then over the contacts P ₁₂ After the brush F ¹ slides over the contacts O ₁₂ to P ₂₁ , ten pulses O ₂₁ are slid to the counter F ₁₀ , it connects the Contact F ⁰ , which is supplied so that it indicates O, is also the one in front of contacts P ₁₂ to P ₂₁ , with the Kon tube T ₈ a pulse via the diode Y ₁₁ and the io clock F ^{0 in} front of the slip ring segment Y. ₉ , so that the pulse lock G _{5 is} fed, so that this tube cathode T \ of the tube T ₈ a pos itive potential is closed while the tube T ₇ ignites, which causes the tube T _{7 to} ignite, but is closed again when the contact when the brush F ¹ crosses the contacts F ° -F ° slides, clocks FQ-F "are bridged, which are in front of the in front of the contacts P ₁₂ to P ₂₁ and the sliding Pv contacts and the slip ring segment X ₉ . 15 ring segment Y ₉ , the cathode T? the

In the course of the working cycle, the tube T ₇ again reaches a positive potential, brush F ¹ the contact set X ₁₂ to X ₂₁ and that this tube blocks. With the further rotation of the slip ring segment Q ₉ , and when it overflows the brush F ¹ , the contacts P ₁₂ to P ₂₁ of the ten pulses are fed to the counter Q _1n. Since the number 3 was already stored in sequence with the slip ring segment Y ₀ " ver counter O ₁₀ , it creates ten pulses on the value O after the counter F _{10 has} transmitted. The processes described brush F ¹ has slid over seven contacts, and this is repeated for all contact groups, and cathode Tjj of tube T ₈ is fed via diode Q _n as a result, all counters remain in the zero position, a pulse which blocks tube T ₈ and after the brush F ¹ ignites via a contact group tube T _7. This causes the remaining 25 to slide, the busbar / via the three pulses from the contacts Z ₂₈ , X ₂₉ , X ₃₀ via the diode of the associated slip ring segment Imdie brush F ² the slip ring segment R ₉ supplied pulse supplied. However, the pulse gate G ₅ not render them, so that the counter i? switched to 3 _10th pulse to the trigger electrode T ₃ geWenn the brush F ¹ over the re Eastern slip ring length, but forwards it to the cathode τ \ of the segments P ₉ and O ₉ , which slides to the contact 30 tube T ₇ , whereby this tube is blocked, assigned to groups Y ₁₉ to Y ₂₁ and Z ₁₂ to Z ₀₁ are. The brush F ¹ bridged when turning the are in "the manner described by the Kon contacts GG, whereby a positive potential of the clock groups Y ₁₂ to Y ₂₁ and Z ₁₂ to Z _{21 is} fed to the trigger electrode T \ of the ROhBeT ₅ , counters P transferred ₉ and "O ₉ pulses, so that these because ignites the tube T ₅ and the tube T blocks _0, respectively first set to O, while loading of the tube 35 at Block T ₆ is acting with their that the Tube T ₈ blocked and tube T ₇ anode Tl coupled trigger electrode T \ which is ignited, whereupon the remaining pulses per tube T _{1 are connected} to ground, and tube T ₁ ignites because it is fed to the next higher counter. while the tube T _{2 is} blocked. When the result is the counters P ₁₀ , Q _w , R ₁ . , closing tube T ₁ conducts, the S-contact pairs and the borrowed on 3, I ₅ 4, while the counter shows O ₁₀ O. 40 K-contact pairs of the operations described above when entering the multi-function are activated and in the pressed position the _{keys originally locked in the counters O 1n} , P ₁₀ and Q _{1Λ are connected} to voltage. If the stored digits are each one place after the multiplicand, for example 851, the are shifted to the left, whereby the original contact O _{n of} the first row of keys, the contacts P ₀ in the register number with a factor of 10 multi- 45 and P _{1 of} the second row of keys and which has been contracted. measures Q _n to Q _{7 of} the third row of keys on span

To multiply a multiplicand by voltage. When the brush F slides over the key rows assigned to the first three rows of keys to carry out a multi-digit multiplier, the machine is first set in the manner described with one pulse to the counter O ₁ Counter P ₁₀ and eight pulses entered on the keyboard. The fed for the input of the counter O _10. If the multiplier is pressed when the multiplicand keys are pressed, for example 97 and the multiplier key pressed is locked. Subsequently, the No. 9 is pressed, ignites a glow discharge corresponding to the highest point of the multiplier on the first cathode of the counter tube L. When the multiplier key is pressed. By the operation of 55 brush F during a revolution about the Koneiner any multiplier key of the con- is clocks O ₀ to Z "slipped each key row clock U ₁ of the changeover switch U to the contact U" is environmentally, the glow discharge in the counter tube of is placed. The brush F ₁ is switched to the second cathode by pressing one of the first, labeled X function key in a still to After two revolutions of the brush F is the descriptive way set in rotation and 60 counter P _1n to O, since it has ten pulses has received, bridges the contact pieces EE, as a result of which the and the trigger electrode T \ of the tube T _a is fed a single pulse to the tube T ₀ via the diode T ₁₁ a pulse. When a supply is given that ignites this tube 'while the brush F then blocks the contacts CC ₁ , BB _Λ via the tube T ₅ . The bridged with the anode T \, is the tube T, frozen and the tube T of the locked tube T _n connected to contacts E ignited ₁ ⁰ 65, whereby the contact A to voltage therefore agreeable to ground potential, so that specifies when exceeding. This causes the counter O of the contacts E ° -E ° the Auslöserelek- the slip ring segment Q _1n bridge ₉ is supplied with a pulse, trode Tl of the tube T ₈ is connected to ground, WO before the brush F via the contacts Q ₀ to Q ₉

15 16

slides. Your brush F makes so many revolutions over all of the inputs of the multiplicand in the contacts O ₀ to Z ₈ , until the counter L nine main keyboard operated keys has been switched to steps by a descriptive trigger mechanism in each case Step, when the brush F ^1, the contacts 3-3 · position are returned, and another bridged one and a voltage to the driver lead of the multiplicand in the counter would not be electrode L ₁₁ ), whereupon a possible from the cathode LJ When the pulley 51 reaches the shaft 50 after pressing the trigger electrode Ti of the tube T _{2 , the multiplication key 39 ignites the tube T 2} and disconnects the tube T ₁ and locks the shaft 50 against rotation. would be backed up until either the multiplication key

After the multiplicand has been released nine times in the io 39 or a delete or result _{key counter U 11} , P _n , Q ₁₁ and .R _{11 has been} inserted, is actuated. The multiplication key 39 can come to rest when the counters come to rest, and the operating state can be locked, so that the next digit of the multiplier can now be pressed several times by successive presses in the multiplier key row, whereupon the multiplication keys can be carried out. Machine first all 15 stored in the counters. To be able to shift the digits one place to the left with the multiplication key 39 locked and to be able to connect the multiplication with the now arranged claw clutch 53 to the pulley 51 on the shaft 50, the given place of the Multiplier in the manner described above must be executed by pressing the delete keys 89, 90 and in the manner described. Playback buttons 91, 92 (Fig. 3) the connection

In the above, those were at a multiplication 20 between the multiplication key 39 and the belt run-off electrical processes described wor- disk 51 are solved. The belt ends can do this. In the following, the mechanical disk 51 should either run freely or via a niche for a short time Structure of the machine are entered into, forked part 54 with the claw coupling 53 in one way it is not yet described in the main patent. When on the forked part and in connection with the execution of 25 54 a force is exerted which turns it clockwise Interested in multiplications. (Fig. 3) pivots around its bearing 56, it couples the

As mentioned, in the case of multiplications, the pulley is first removed from the clutch 53, and the Multiplicand keyed into the main keyboard, and the shift carried out at the same time causes the actuated keys are locked in the depressed position that a spring attached to the forked part 54. Next, one of the first digits of 30 moves 55 into corrugations 57 on the adjacent major multiplier corresponding multiplier key area of the claw 53 engages and thereby the shaft presses, which decelerates in a multiplier key row 38 50. The part 54 becomes clockwise (Fig. 3) lies. (Fig. 3) rotates and couples the pulley 51

The machine also includes a multiplier from the pawl 53 when a down-cation key 39, the lever 58 which extends in a row of function keys 40 35 and which rests on the bracket 43 and denoted by the multiplication sign is ordered when the multiplication key is actuated is. When the button 39 is pressed, a motor 39 pulls a link 59 to the right (Fig. 3)., switching rod 41, which is connected to the multiplier keys in the movement of the lever 58 reaching downwards the row 38 cooperates, operated. With Additio- is on the connecting member 59 by an internal causes the shift rod 41 to be transmitted with a compression spring 60 adjustable by a bracket 40. The connection-like Part 43 connecting component 42 (Fig. 3), that member 59 has a collar 61, which ensures the end of the shift rod 41 (Fig. 4) not with the fact that the connecting member 59 when the Tab 33 engages. Key shaft of the multiplication key 39 upwards

The end 46 of the pivotable about shafts 44, 45 is released so that the forked part 54 through arranged bracket-like part. 43, the front in the 45 a light torsion spring 62 counterclockwise machine is enough, the multisense can be rotated under the shaft and thereby has the effect that plication button 39, so that the bracket 43 when you press the pulley 51 again engages in the claw 53, ken the multiplication key 39 around the shafts 44, 45 When the multiplication key 39 for a row

is pivoted and thereby pulls the shift rod 41 in the path of the tab 33 from multiplications by successive actuation. In addition, 50 operations of different multiplier keys in prevented that the free end of the tab 33 is locked in the pressed position and a delete rod 31 comes into engagement, if a key in key or result keys are pressed, the main keyboard is operated ; However, if the machine is set to multiplication by the shaft of the delete key or the shafts, the 63, 64 of the result keys, a bracket 65 is locked around pivoting tab 33 by the switching rod 41, and the 55 shafts 66, 67 pivoted, whereby one of the Bracket contact 43 cannot touch contact 35. depending lever 68 on a collar 69 after entering a multiplicand in the main grips, which is coupled to the connecting member 59. The pressure exerted by the hanging lever 68 on the multiplier key in the row 38, a special motor collar 69, compresses the spring switching rod 48, which moves the rod 41 from the 60 60 and moves the connecting link 59 3 loosens tab 33 and closes the contacts 34, 35 to the left, so that the forked part 54 enables the belt to be engaged in the claw 53.

With the motor running, while the top loading case a tooth 53 is not α to the jaw 53 immediately un-

Written operations are carried out, a hindered drive engages in a tooth 51 α of the pulley 51 on a vertical output shaft 25 of the motor 65, so a spring 72 enables the pulley 26 located via a belt lever 71 of the fork part 54 to yield somewhat. a pulley 51 on. After actuation, Fig. 12 shows a side view of the function of a multiplier key in row 38 were key row 38, in which also the bow-shaped parts

17 18

43, 65 can be seen, which allow coupling and uncoupling, delete keys 89, 90, unlocking of the Multiplides drive 50 in the key 39 described in the main patent.

ne delay device causes. Fig. 12 shows the second delete key 89 has a similar, each

also the device for locking the multiple but larger contact tongue 107 and works in the same way in the cation key 39, which is then required above all.

if a number entered on the keypad with an if a considerable number of each

multi-digit multiplier should be multiplied. Multiplications are to be carried out, it is necessary to operate the shafts 82 of the function keys if the multiplication key does not have to be actuated anew for each of an upper guide plate 80 and a lower guide. Rank plate 81 of a switch unit. The key io for the multiplication key is therefore still a business 82 carry changeover contacts, which are provided in the special interlock. In order for the multipli circuit diagram of FIG. 1 to be shown and to be permanently locked with the station key 39, it must cooperate with generic contacts which press on ISO and their upper part 95 lies backwards, that is to say glazing plates 83. The key stems 82 will be pushed in Fig. 12 to the right, so that engages by compression springs 84, the loading on the in each case between the upper 15 attached to the key stem 82 nose 108 at 109 under guide plate 80 and a collar 82 to the frame 86 .

matching key shaft are arranged in the rest When pressing the playback or result keys

position pressed. The upper part of the individual key 91, 92 or the delete keys 89, 90 are not only shadow 82 extends through an auxiliary frame 86 which actuates electrical contacts located on the shafts 82 and the contact plates 83 while the lower part of the key shafts briefly 20, it ends above the bracket 43 or 65 (FIG. 3), but this also does not touch the toggle lever 99 and the toggle lever. 98, which has the arm 102 reaching upwards

The shafts of the delete keys 89, 90, which contains the adder edge 101 , pivoted. This movement key 87, the result keys 91, 92 slide freely in the upper part 95 of the key shaft subframe 86, while the shafts of the multipliers 25 82 of the multiplier key have no effect when cation key 39, a division key 93 and a sub-these is in its rear locked position because traction buttons 98 are hinged at 94 and 98, respectively. Since the part 95 is no longer in this position, the upper part 95 of the shaft 82 can be tilted while the pivoting range of the edge 101 of the upward multiplication key 39 is forward or backward facing arm 102 of the toggle lever 98 the connection 98 on the shaft 30. The multiplication key 39 can, after completion 82 of the division key, allow the upper part of the all multiplications to be moved forward into its rest position relative to the key shaft 97. It can be returned that the addition key 87 ge-Correspondingly, the subtraction can also be pressed, as a result of which the contact tongue 110 can be tilted forward at a key 88. By pressing down the back of the upper part 97 of the shaft 82 and tilting the multiplication key 35 of the multiplier key 39 forward stop 111 39, a nose 94 on the upper part 95 of the key pushes forward until the nose 108 of the part 109 shaft with a Part 96 of the underside of the auxiliary of the frame 86 comes free.

frame 86 engaged and locked. In Fig. 11, the multiplier key row is in page

this setting of the multiplier key can then be displayed. This row of keys is structured in a manner similar to a multiplication with a multi-digit multi-digit as the rows of keys on the main keyboard, carried out with a multiplier in the manner described above, with the exception that no precautions are taken. After completing a multiplication, the return of an actuated key to the adding key 87 is actuated, thereby delaying a rest position on the shaft until the tongue 97 attached to this key hits the machine by pressing the key engaging a spring 87 for engagement with a level 45 has carried out operations. In addition to the right arm 98, a toggle lever 99 is brought, the multiplier keys numbered 1 to 9, which is supported by a bearing 100 and provided by a zero or space key 401 * the tension spring 105 is pulled upwards. When the use takes place when the multiplier in a lever 98 is pushed down by the tongue 97. counting digit contains a 0, an upper edge 101 engages an upward 50.The keys 401 to 410 are provided on their lower extending arms 102 of the toggle lever 98 at the ends with fork-shaped contacts 411 , the forward-facing surface of the upper part 95 which in the rest position do not bridge two fixed contacts 412 of the key shaft 82 of the multiplication key 39 to 413.

and pushes this upper part 95 backwards (in the rear end of the key rail 437 is

12 to the right), whereby the nose 94 from the 55 is provided an extension 411 which is notched in its resting frame 86. The same happens when in position, that is, when none of the keys 401 to 410 is pressed by actuating the result keys 91, 92 through tongues, engages an insulating cam 415 , the 103, 104, which is attached to a leaf spring 416 on the relevant key shafts. The leaf springs are ordered. 416 carries a contact board 418 with a

Upon depression of the clear key 90 a 60 a leaf spring 420 is attached to contact plate 417 contact tongue 106 engaged with the upper edge 101 of the according to a working contact and with a reaching of a leaf top arm 102 of the toggle lever 99 in spring 419 mounted contact plate 424 to engage and this lever characterized around its normally closed contact.

Bearing 100 rotated so that it the upper part 95 of the When one of the buttons 400 to 410, both

Key shaft of the multiplication key 39 auskünkt. For example, the key 405 corresponding to the number 4. The opening tongue 106 makes it unnecessary ^{to press the plus key after every 5} , the key bar 437 with its extension individual multiplication, 414 to the front, ie to the left in FIG. 11, since both the result keys 91, 92 as well as the so that the contact board 418 from the contact

Board 425 lifts off and makes contact with the contact board 417. The actuation of the button 405 also causes the fork-shaped contact 411 to short-circuit the contact pieces 412, 413.

The key 405 is pressed until a signal in the arithmetic unit indicates that the initiated multiplication process has ended.

Claims (16)

PATENT CLAIMS: IO 1. Calculating machine with full keyboard and a multi-digit register, which consists of counters that can be incremented by electrical pulses, the values can be entered in parallel into the keyboard and inserted one after the other in the counters, according to patent 1,086,921, characterized in that when a Multiplier key the values stored in the counters are shifted by one place and that one of the number of working cycles of the machine corresponding to the actuated multiplier key is triggered, during which the values entered into the keyboard are fed to the counters. 2. Calculating machine according to claim 1, characterized in that the shift in the Counters stored numbers in the counters of the next higher digit before an introduction of the multiplicand in the register. 3. Calculating machine according to claim 1 or 2, characterized by the number of additions controlling multi-cathode stepping tube (L), in which at the end of each addition cycle the glow discharge is incremented from one cathode to the next until the number of increments of the glow discharge is equal to the value of the actuated multiplier key. 4. Calculating machine according to claim 3, characterized in that the glow discharge of the "Multi-cathode stepping tube (L) is ignited by pressing a multiplier key on the cathode assigned to the key and that the working cycles of the machine end when the glow discharge has reached the zero cathode (Ll) . 5. Calculating machine according to one of the preceding claims, characterized in that the keys of the keyboard can be locked in the pressed position by a releasable latch arrangement (37, 222, 50). 6. Calculating machine according to one of the preceding claims, characterized in that the device for shifting a number stored in a first counter in a second counter includes a pulse generator (brushes F \, F ² and associated contact pieces) which supplies pulse groups, each one contain a certain number (e.g. 10) pulses and that the pulses of a pulse group _{are fed to the first counter (e.g. O 10} ) only until a certain number (e.g. zero) is stored in it and that the remainder of the pulse group is then fed to the second counter (e.g. P ₁₀ ). 7. Calculating machine according to claim 6, characterized by a switching device (T ₇ , T ₈ ) which can be controlled by a control pulse that occurs when the first counter has reached the specific number and. which switches the pulse generator from the first counter to the second when the control pulse occurs. 8. Calculating machine according to claim 6 or 7, characterized in that the two counters Adjacent counters of a multi-digit register are connected by a carry device are, and that each counter successively pulses from one of the pulse groups supplied for so long until this counter is at zero, and that then the remaining pulses of the relevant Group are fed to the counter of the next higher position in the register. 9. Calculating machine according to claim 8, characterized in that the pulse groups the Counting one after the other, starting with the counter with the highest digit and ending with the counter of the lowest digit of the register. 10. Calculating machine according to claim 14, characterized in that the pulse groups in a decimal register consist of ten pulses and that a device (G ₅ ) is provided for blocking the transmission device. 11. Calculating machine according to one of the preceding claims, characterized by a single carry memory (T ", T ₄ , T ₉ , etc.), which contains carry-over from all counters via a bus (J) and feeds them to the counter of the next higher position before it Counter is controlled by electrical impulses. 12. Calculating machine according to claim 11, characterized in that the carry memory contains a bistable device which is brought into the set state (T ₃ conductive) when a carry occurs in a counter, so that the bistable device is queried before each pulse cycle assigned to a counter (T ₄ conductive or non-conductive?) And that an additional pulse is fed to a counting device if the bistable device was set during the pulse period assigned to the preceding counting device. 13. Calculating machine according to claim 12, characterized in that the bistable device contains a tube (Γ ₃ ) with a trigger electrode (Tj) , which via a line (J) _{containing a gate (G 5} ) is always supplied with a pulse when a carry occurs in a counter, whereupon the tube becomes conductive, and that the cathode (Tl) of the tube is supplied with a further electrical pulse which it can block before a pulse period begins, with a pulse occurring at the anode of the tube, if this was in the conductive state. 14. Calculating machine according to claim 13, characterized in that the pulse occurring at the anode of the tube is _{fed via a capacitor to the control electrode of a second tube (T 4} ) which makes it conductive; that the potential at the anode (Ti) of the second tube is in turn fed to the relevant counters via a switching device (F, A) , so that these counters receive a carry pulse immediately before the start of the pulse periods assigned to them when the second tube (T ₄ ) is conductive. 15. Calculating machine according to claim 14, characterized by a third tube (T ₉ ) through which the second tube T _{4 is} blocked at the end of each pulse period if it was conductive. 16. Calculating machine according to claim 13, 14 or 15, characterized in that the counters consist of multi-cathode counting tubes and that a certain cathode (zero cathode) of each counting tube via a diode (O ₁₁ to Z ₁₁ ) with the control electrode (Tl) of the first Tube (T ₃ ) is connected. Considered publications: "Arithmetic Operations in Digital Computers", D. van Nostrand Comp., Inc., New York 1955, P. 143; 250 and 251; "Electronic Engineering", August 1951, pp. 286 to 291. In addition 3 sheets of drawings