CH211692A - Electric adding machine. - Google Patents

Description

  

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 Electric adding machine. The invention relates to an electrical calculating machine and aims to use components known from the technology of automatic telecommunication systems, such as relays and selectors controlled by current surges. According to the invention, for each digit of a multi-digit number to be set, an arm of a pick-up switching mechanism that sweeps a row of contacts is provided, on whose row of contacts the value is electrically identified, and which, when looking for the designated contact, sends a number of current impulses corresponding to the value to a for the relevant Stepping mechanism provided for arithmetic operations.



  For an arithmetic operation such as addition, subtraction or multiplication, as many arithmetic selectors designed as step switches can be provided as the result has places. These arithmetic selectors expediently have switching arms which electrically identify the individual values of the result on the contact rows of other taps.



  Such a calculator selector can also have two drive magnets, which allow the switching arm to be advanced in an additive and in a subtractive sense.



     Furthermore, each arithmetic selector can bezw when exceeding the highest. control means assigned to the lowest value contact, which cause an additional stepping of the arithmetic selector to the next higher position.



  The invention makes it possible to build electrical calculating machines that carry out all basic arithmetic operations, such as multiplication, division, addition and subtraction, and string together several such arithmetic operations. In this case, the means for setting the numerical values, together with the means for making the result visible, can be arranged spatially separated from the switching mechanisms of the calculating machine, since they are only electrically connected to them via lines.

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 Some exemplary embodiments of the invention are shown in the drawings and explained in detail in the associated description.

   1 shows the circuit arrangement of an arithmetic unit for carrying out additions and subtractions, FIG. 2 shows the circuit arrangement of an arithmetic unit for carrying out multiplications, FIGS. 8 and 4 the circuit arrangement of an arithmetic unit for carrying out divisions; Both figures are to be placed side by side when looking at them.



  5 shows a device for setting numerical values, FIG. 6 shows a device for identifying numerical values using keys, FIG. 7 shows a device for setting numerical values using a current impulse transmitter, FIG. 8 shows a circuit arrangement for identifying numerical values using keys, and FIG the schematic representation of a calculator selector.



  The arithmetic unit shown in FIG. 1 for carrying out additions and subtractions comprises a setting device E, which makes it possible to set the different place values of the number to be added or subtracted; a setting tap AE, which transfers the setting of the place values to the switching mechanisms which carry out the calculation; a set of arithmetic selectors RW and a result gripper AR, which determines the values of the result identified by the setting of the various arithmetic selectors.



  The setting device consists of several manually adjustable setting levers EA to EE. Such a setting lever is provided for each digit of a multi-digit number. The five setting levers EA to EE therefore enable a five-digit number to be set. Each of these setting levers sweeps a row of at least ten contacts. One embodiment of the setting lever, which is only indicated schematically in the drawing FIG. 1, is shown in FIG. Here the setting lever EH is adjustable along a scale ES; he has a contact arm anyway, which sweeps a number of contacts.



  The AE is designed as a step sehaltwerk on the type of selector used in automatic telephone systems. It has six switching arms ae1 to aes, which are arranged on a common shaft and are advanced by one step each time a drive magnet DAE is excited. Each of the switching arms ae2 to aes is assigned to a digit of the number to be set; the contacts swept by this switching arm are individually connected to the contacts swept by the relevant setting lever E A to EE. whereby one contact in each row is electrically identified.



  A sequence switch V AM is assigned to the adjustment gripper AE, which in its various switch positions closes the contacts identified by the letters za and a Roman numeral. The Roman numeral indicates the successive contact positions. In the idle state, the next switch is in contact position I.



  The arithmetic selectors RW are also designed as stepping mechanisms. Such a wobble calculation is shown in FIG. It has a shaft WRW, which carries two gear wheels TRA and TRS, as well as a ratchet wheel RH. A spring HF acts on the rate wheel RH. which holds the shaft II'RE 'in its respective position. The holding pawl RAIL, which is attached to the armature RAA of a 3ulagnetes RA, can engage in the drive wheel T-BA. The RSK indexing pawl can intervene in the TRS drive wheel. which is attached to the armature RS A of a magnet RS.

   Both drive wheels TR <4 and TRS are toothed in opposite directions. If the magnet RA is excited, then the shaft WRTI 'is turned over the drive wheel TRA in one direction - in an additive sense

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 advanced one step. If, on the other hand, the magnet RS is excited, then the shaft is rotated by one step via the drive wheel TRS in the opposite direction - in a subtractive sense.



  The shaft WRW carries switching arms, one of which is shown in the drawing FIG. 9. This switching arm sweeps a contact bank LB, which carries ten contact blades L in a row. The switching arm is designed in three parts and has arms rwa, rwb and rwc, which are angularly offset from one another by 120 '. The design is such that as soon as the arm rwa leaves the last contact lamella in the row when switching in one direction, the adjacent arm rwb or rwc sweeps the first contact lamella at the other end of the contact row. In FIGS. 1 to 4, the switching arms of the individual stepping mechanisms are always shown only in one piece for a better overview. However, as indicated in FIG. 9, they are to be thought of in three parts. The three-part switching arm rwa to rwc is supplied with current via a spring SF.



  In the arrangement of FIG. 1, the number of arithmetic selectors depends on the number of positions that the result can have. Five arithmetic selectors are shown in the drawing. The arithmetic selector in the lowest position has the drive magnets RAA and RSA and the switching arms ra1 to ra4. The arithmetic selector in the second position has the drive magnets RAB and RSB, as well as the switch arms rb1 to rb4. In a corresponding manner, the drive magnets of the arithmetic selector of the fifth - in the example the topmost position - are designated with RAE and RSE and its switching arms with re1 to re4.



  The result gripper AR is also designed as a stepping mechanism, the shaft of which carries the switching arms ar1 to ars. Each of the switching arms ar1 to ars is assigned to one of the arithmetic selectors; the contacts swept by him are individually connected to the contacts swept by at least one switching arm of the respective arithmetic selector.



  A sequence switch VDM is assigned to the result pick-up AR, which, in its individual contact positions denoted by Roman numerals, closes the contacts denoted by the letters vd and the relevant Roman numeral. The shaft of the pickup switching mechanism, which is incrementally advanced by the drive magnet DAR, also carries a type wheel TR, which has the ten types of numbers. A paper strip (not shown) can be hit against the type wheel by the armature of a magnet DM and the type just set can be printed.



  The circuit uses different relays marked with capital letters, the contacts of which are marked with the corresponding small letters.



  Assume that the numbers 12345 and 67890 are to be added together. To set the number 12345, the setting lever EE is moved by one step, the setting lever ED by two steps, etc. On the row of contacts swept by the switching arm aez, the fifth contact is then connected to the positive pole via the setting lever EA, and on the contact bank swept by the switching arm aes, the fourth contact is connected via the setting lever ED, etc. To transfer the set numerical value 12345 to the arithmetic logic controller, a Plus button struck, which controls the contacts TP1 and TP2.

   The contact TPi closes a circuit for relay PR, which closes a holding current circuit with contact pri. Contact prs closes a circuit for the drive magnet DAE via the switching arm aei, which responds and advances the switching arms of the setting tap by one step. When excited, the magnet DAE actuates a contact dae and thereby excites a relay J, which controls the contacts i1 to i3.

   The contact il excites a delay relay W, whose contact wi a further delay

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 relay H energized. The circuit of the drive magnet DAE has been interrupted by the switching of the switching arms ae. The magnet is de-energized and interrupts the circuit of relay J, which also drops out. Contact il closes a new circuit for the magnet DAE. The magnet DAE and the relay J work in an interplay and the switching arms ae are incrementally advanced over the first to the ninth contact. On the zeroth contact, however, the progression is initially interrupted because the contact lag of the delay relay H has now opened.



  During this step-up, the relay J with its contact i2 closes the step-up circuit for the drive magnet R4A for the additive step-up of the arithmetic selector of the first position with every excitation. This circuit is prepared by the contact prs and the sequence switch contact va1. At the same time, the relay P is connected to the switching arm aez via a sequence switch contact va1. As soon as the switching arm ae2 of the setting tap hits the contact that is connected to the positive pole via the setting arm EA after having performed five switching steps, relay P is energized. Contact p1 closes a holding circuit for the relay and contact p2 interrupts the incremental circuit of the arithmetic selector.

   The arithmetic-logic selector has thus been advanced by five switching steps in accordance with the setting of the setting arm EA to the value 5 and the switching arms ra1 to ra4 have been set from the zero contact to the fifth contact.



  As soon as the excitation of the magnet DAE and the relay J is interrupted for a long time after the first rotation of the switching arms ae of the setting tap 4E, the delay relay Wr drops out. The contact w1 interrupts the circuit of the relay H and the contact w7 interrupts the circuit of the relay P. For the duration of the release delay of the relay H, a circuit for the magnet V AM of the slave switch is closed via the contacts w1, h1, so that the slave switch is advanced to position II. As soon as relay H drops out. the contact h2 closes the circuit of the drive magnet DAE of the setting tap again and the switching arms ae are switched a second time via their rows of contacts.

   During this second continuation, the switching arm aes is connected via the sequence switch contact vaII to the relay P, which determines the setting of the setting lever EB. The current impulses transmitted by contact i2 are fed via a sequence switch contact vaII to the drive magnet RAB for additive continuation of the reehenwäblers of the second position, whose switching arms rb1 to) b4 are advanced to their fourth contact according to the setting of the lever EB to the value 4.



  After completing the second cycle, the sequence switch is switched to position III in the manner described. During the third cycle, the switching arm ae.4 is effective and the arithmetic selector for the third digit is set. In this way, the five digit values of the set number 1234.5 are transferred to the five arithmetic selectors during five successive cycles. As soon as the sequence switch is held in position VI at the end of the fifth cycle, the holding circuit of the relay PR is interrupted.

   Contact pr2 prevents the adjustment hook from being switched on again. The sequence switch is automatically advanced from position VI to position I.



  Now use the setting levers E-1 to EE to set the value of the number to be added 67890 and press the plus button again so that relay PR is excited a second time via contact TPi and see stops. The contact pr2 sets the setting tap AE in motion again. Since the setting arm en is set to contact 0, on which the switching arm ae2 is in its rest position, relay P is immediately energized

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 and with the first cycle of the setting tap the arithmetic selector of the lowest position is not advanced.



  During the second cycle of the setting tap, the arithmetic selector of the second position, whose switching arms rb1 to rb4 were set to the fourth contact, is advanced by nine steps according to the setting of the lever EB to the value 9. After switching by five steps, the switching arm rb1 is on contact 9, the last contact in its row of contacts. As soon as the drive magnet RAB is excited for additive incremental switching when the sixth current pulse is received, a contact rab controlled by this magnet with each excitation closes a circuit for a surcharge relay ZC, which responds immediately and closes a holding circuit with contact zc1. At the end of the second cycle of the setting tap AE, the switching arms rb1 to rb4 of the arithmetic selector of the second position are on their contact 3.

   Relay TV, which now drops out, interrupts the holding circuit of the surcharge relay ZC with contact wr2 and closes the circuit with contact w4 for a one-time switching of the drive magnet RAC for additive switching of the arithmetic selector to the next higher position. This circuit runs via contact zc2 of the surcharge relay ZC, which is equipped with a low dropout delay and does not immediately drop its armature. Since the arithmetic selector of the second digit was incremented in an additive sense beyond the end of its row of contacts, the arithmetic selector of the third digit is automatically incremented by one step in an additive manner with the help of the surcharge relay.

   If the arithmetic selector of the third digit were to be advanced from its ninth to the zeroth contact by this additional step, then the surcharge relay ZD would be temporarily energized, which causes the arithmetic selector of the fourth digit to be incremented by one step. The pause between two revolutions of the setting gripper AE is dimensioned in such a way - due to the delay in releasing the relay H - that, if necessary, all arithmetic selectors of the upper positions can be advanced by an additional step one after the other.



  In the assumed example, the third digit arithmetic logic controller was on contact 3 and is advanced to contact 4 by the additional step. During the third cycle of the setting tap A4E, eight current surges are transmitted to this arithmetic unit by the lever EC, in accordance with the setting of the value 8. The switching arms rc1 to rc4 reach contact 2; the surcharge relay ZD is energized and causes the arithmetic selector of the fourth digit to be incremented during the pause before the new rotation of the setting tap AE.



  In a corresponding way, all arithmetic selectors are incremented one after the other. If the setting gripper has finished its revolutions, then in the assumed example of adding the numbers 12345 and 67890 the switching arms of the arithmetic selector are on the contacts: switching arms re1 to re4: contact 8 switching arms rb1 "rb4: contact 0 switching arms rci" rc4: contact 2 switching arms rbi "rb4: Contact 3 switching arms rai" ra4: Contact 5 If this result is to be printed, a result key is pressed which actuates the contacts TRi to TRs.

   The contact TRi closes the circuit for the drive magnet DAR, which then switches the switching arms ari to ars of the result pickup in interplay with the relay JR. During the first cycle, the test relay PD is connected to the switching arm ari via the sequence switch contact i> dI. As soon as the switching arm ari meets the eighth contact, which is connected to the positive pole via the switching arm rez, relay PD responds.

   Contact pdi excites the printing magnet DM which, when the paper hits the type wheel, creates an imprint of Type 8

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 causes. The paper strip is then automatically switched on in a known manner. The contact pd2 interrupts the switching circuit of the magnet DAR and closes the circuit for a relay FR, which excites the sequence switch magnet VDM. The sequence switch is in position II. Relay FR has switched off test relay PD with contact fr2, which drops out and closes the circuit for the drive magnet DAR again. The result pick-up AB is incremented again until the switching arm arg meets contact 0, which is connected to the positive pole via the switching arm rb2.



  In this way, the switching arms arl to ar5 are effective one after the other, each of which determines the setting of a calculator selector. The position values of the result set on the arithmetic selectors are printed on the type wheel TB. After the result has been printed completely, the result key is released. Contact TRs closes a circuit for relay FR in the sequence switch position VI, which causes the sequence switch to switch to the starting position I.



  If a new number is to be added to this result or subtracted from it, the setting levers EA to EE are set accordingly and the plus or minus button is pressed. The addition takes place in the manner already described. When the minus key is pressed to initiate a subtraction, contacts M and TM2 are actuated. Contact TM1 closes a circuit for relay 1MR, which is held by contact mr1. The excitation of the relay MR instead of the relay PR has the consequence that the current impulses which are transmitted to the arithmetic selector during the revolutions of the setting tap AE do not affect the drive magnet for additive incremental switching, e.g. B. RAA, but the drive magnet for subtractive switching, z. B.

   RSA. The circuit is controlled by contact i3 of relay J. If an arithmetic selector whose switching arms are on contact 0 is switched on in a subtractive sense, a trigger relay is energized. For example, if the drive magnet RSA responds while the switching arm ra1 is on contact 0, the contact rsa controlled by the armature of the magnet closes the circuit for relay PD, which is self-supporting. In the pause before the next cycle of the setting tap, the contact pd2 causes the arithmetic selector of the second digit to be incremented in a subtractive sense. The result set after the subtraction of all the place values from the arithmetic selectors can in turn be determined and printed out by the result pickup AB.

   Any number can be added and subtracted on the calculator selectors. The setting of the calculation selector corresponds to the respective result.



  When subtracting a number it can happen that the result is negative. For example, if the arithmetic selectors are set according to the result 0000l and the number 00002 is to be deducted, then relay TB is energized in a subtractive sense via contact 0 when the switching arm rai is switched on, which, after the end of the cycle of the setting tap, the magnet RSB of the second arithmetic selector once excited. When switching arm RBi forward from contact 0 in a subtractive sense, relay TC is energized, which switches on magnet RSC.

   When switching arm rci, relay TD is energized. which turns on the magnet RSD. When the switching arm rdi is switched on, relay TE is energized, which switches on the magnet RSE, and when the switching arm rei is switched on, relay TK is energized, which holds itself with contact tki. The switching arms of all arithmetic selectors are now set to the result 99999, which does not correspond to the correct result. In addition, however, the identification relay TK is energized.



  If a printout of the result is to be made at this moment, then

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 the setting of the arithmetic logic controller must be corrected. A relay K is energized via contact tks when the result key, which actuates contact TRz, is pressed down, which with contact k1 closes the circuit for a relay KR. Relay K interrupts the holding circuit of the identification relay TK with contact k6, which drops out again and interrupts the circuit of relay K. Relay K is equipped with a delay and lets its armature drop out with a delay. While the relay K is energized, the contacts k2, k3, k4 and ks each close a circuit for the drive magnets for additive incremental switching of the arithmetic selectors of the above position.

   The switching arms of the magnets RAB, RAC, RAD and RAE are thus advanced by one step in an additive sense to contact 0 so that the arithmetic selectors are now set according to the result 00009.



  As a result of the excitation of the relay KR, the contact kr2 has removed the positive pole from the switching arms 2 of the individual arithmetic selectors and applied to the switching arm 3 of this arithmetic selector. As a result, the individual switching arms of the result pick-up now check which of their contacts of the switching arm 3 of the associated arithmetic selector is connected to the positive pole. The contacts 1 to 9 swept by the switching arm 3 of each rake selector are connected in the reverse counting manner to the contacts 1 to 9 swept by the switching arms 2 of this rake selector with the corresponding contacts of the result pickup.

   If the switching arms ra1 to ra4 of the arithmetic selector at the bottom are on the first contact, then the switching arm rag is used to connect the first contact, which is swept by the gripper arm ar5, to the positive pole. By contrast, the ninth contact is connected to the positive pole via the switch arm ras. If the switching arms ra1 to ra4 are on the ninth contact of their row of contacts, then the ninth contact of the row of contacts of the switching arm ars is electrically identified via the switching arm rat, but the first contact of this row of contacts is electrically identified via the switching arm ras. The zeroth contact of the switch arms ras and ras, however, is wired in the same way.



  Despite the setting of the result selector according to a result 00009, the result 00001 is printed out when the result is picked up and the KR relay is activated at the same time. In this case, the relay KR causes the additional printing of a minus sign in a manner not shown, which indicates that the result is negative.



  If, on the other hand, the negative result is not printed, new values are added to the intermediate result so that the result becomes positive again, then the identification relay TK is inevitably thrown off. In the example assumed, relay TK had been energized when the switching arm of the arithmetic selector of the top position was advanced from contact 0 to contact 9 in a subtractive sense as a result of the automatic switching.

   If one of the lower arithmetic selectors is incremented so far in the additive sense that the result is positive again, then the upper arithmetic dialer is automatically incremented by one step in an additive sense via contact 9 of the switching arm rei and contact tk2 a circuit for the right winding of the relay TIl is closed, which counteracts the left winding. Relay TK drops out.



  If, on the other hand, numerical values that are so large are added that the arithmetic logic controller in the top position is incremented in an additive manner via contact 9, then the circuit for an alarm relay A is closed, which holds itself and switches on a lamp with contact a2. This lamp AL indicates that the capacity of the calculator has been exceeded. By pressing a release button, which actuates the contact TA, the holding current

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 circuit of relay A is interrupted and a circuit for the automatic switching of all arithmetic selectors to their rest position is closed. This circuit runs through the switching arms ra4 to re4 and the drive magnets for additive incremental switching RAA to RAE.

   It is controlled automatically by an interrupter UR. The switching arms ra4 to re4 interrupt the switching in the rest position.



  If the arithmetic unit is to be used for a new arithmetic process after a previous setting of the arithmetic selectors, then all arithmetic selectors must also first be switched to the rest position by pressing the release button.



  The arithmetic unit for multiplication shown in FIG. 2 has setting levers EF A to EFD for setting the multiplicand or factor and setting levers EHA to EMC for setting the multiplier. The setting device EF of the factor is assigned a setting gripper AE, which corresponds to the setting gripper in FIG. 1. Another setting tap AM is assigned to the setting device EM of the multiplier.



  The arithmetic selectors RW are only designed for additive incremental switching. They therefore only have one indexing magnet. In the drawing, the indexing magnets RA to RF of six arithmetic selectors are shown, which index the switching arms. A result gripper AR is used to determine the result set by the arithmetic selectors RW, which is printed by means of the type wheel TR.



  If, for example, the multiplicand 0234 is to be multiplied by the multiplier 065, then after setting the setting levers EFA to EFC and EMA, EMB the multiplier key TM1 is pressed and this energizes relay C, which holds itself. The contact c2 closes the circuit for the drive magnet DAE of the setting tap AE, which now advances the switching arms in interaction with the relay J. The delay relays Wl 'and H are energized during the switching.



  The contact i3 of the relay J transmits the current impulses to all arithmetic selectors which are prepared in the control switch position I. The next switch VA is assigned to the multiplier tap. It is usually in position I, in which the drive magnets RA to RD of the first four arithmetic selectors are prepared by the contacts.



  Since the multiplicand only has three digits, i.e. the setting lever EFD is in the rest position shown, relay PD is energized. The contact pd2 prevents the transmission of current surges to the drive magnet RD of the arithmetic selector of the fourth digit. During the first cycle of the AE setting, all switching arms are effective at the same time. In the example assumed, relay PC responds after two steps, stops and, by opening contact pc2, prevents further switching of magnet RC. Relay PB responds after the third step and relay PA in a corresponding manner after the fourth step. At the end of the first cycle of the setting tap AE, the switching arms wc1 to wcs are on step 2, the switching arms wb1 to wbs are on step 3 and the switching arms wa1 to what is on step 4.

   After the first cycle, the setting tap is stopped for some time until the delay relays Wl and H drop out one after the other. As soon as relay TI 'drops out, the drive magnet D_131 of the multiplier tap is briefly energized via the contacts and 1s, which causes the visual arms a ii to a)

  124 hold one step forward. After the relay H has dropped out, a new cycle of the setting tap begins and the position values 234 are transferred a second time to the arithmetic logic unit. This is followed by a continuation of the illultiplier tick. This process is repeated until after the fifth step of the multiplier tap, i.e. the fifth

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 Transfer of the value of the multiplicand to the arithmetic selector, the Schaltaren am3s reaches the contact that is connected to the positive pole by the EMA setting lever.

   Relay PM is then energized, which remains and closes a circuit with contact pm2, via which the drive magnet DAM is periodically energized in interaction with relay J until the switching arms of the multiplier tap are again in the initial position shown. During this step, the relays W and H remain energized; they only drop out one after the other after the switching has ended. A relay F is energized via contacts w2, h3 and pm3, which energizes the sequence switch magnet VAM. The next switch moves to position II, in which the contacts are closed.



  After the relay H has dropped out, the revolutions of the setting tap AE begin again. Now, however, the four current impulses, which correspond to the value of the lowest digit of the multiplicand, are fed via the contacts pas and vaII to the drive magnet RB of the calculator selector, which corresponds to the second result digit, during each cycle. The calculation selector RA remains unaffected. In a corresponding manner, the rake selector magnet RC receives three current impulses via the contacts pbs and vaII, and the rake selector magnet RD receives two current impulses via the contacts pes and vaII. After each cycle of the setting tap AE, the multiplier tap is advanced by one step.

   The process is repeated until the switching arm am2 makes contact with the sixth contact, which is connected to the positive pole via the EMB setting lever. Relay PM is then energized again, which causes the multiplier tap to be switched to the rest position and the sequence switch to be switched.



  When the sequence switch is switched from position II to position III, the circuit of the relay PM is briefly interrupted. In position III, however, the PM relay is immediately re-energized, since the EMC setting lever is not adjusted in the example assumed. Relay F responds again immediately and causes the slave switch to remain in position IV. Relay RR is excited via contact vaIV. As can be seen, the multiplicand has been transferred five times to the arithmetic selectors corresponding to the ones place of the multiplier.

   Then a shift of the digits has taken place due to the progression of the sequential switch, and the digit values of the multiplicand have been transferred six times to the arithmetic selector of the next higher digit according to the tens value of the multiplier. Here, of course, the additional switching of individual arithmetic selectors took place under the influence of one of the surcharge relays ZB to ZF when the switching arms of the respective upstream arithmetic selector were adjusted beyond their ninth step. The excitation of the relay RR now causes the result set by the arithmetic selectors to be picked up.

   Contact rri closes the circuit for the drive magnet DAR; which advances the gripper arms ari to ar7. The magnet works in interplay with the relay JR. Via the switching arm vdi of a sequence switch, a test relay PD is switched on one after the other to the individual switching arms ari to czrc, which pick up the setting of the arithmetic selectors assigned to the various positions of the result.

   Every time relay PD is energized, the contact pdi causes the printing of the numerical value just set by the type wheel TR; the contact pd2 during this interrupts the progression of the result pick-up and initiates the progression of the sequence switch by energizing a relay FR, whose contact fri excites the magnet VDN of the sequence switch.



  As soon as all the values of the result have been tapped and printed, a relay SR is energized via the switching arm vdi. The contact sri interrupts the holding current

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 circuit of relay C, which drops out. Here, the contact causes the sequence switch VA to be switched from its position IV to its position I, so that relay RR also drops out. Contact e6 closes a circuit controlled by the interrupter UR, via which all selected arithmetic selectors are advanced until their switching arms What to wfs interrupt the circuit in the rest position.



  The arithmetic unit for division shown in FIGS. 3 and 4 has an adjusting device E for adjusting the dividend, which consists of adjusting levers EA to EE. An adjustment device EDE is also provided, which consists of the adjustment levers ED to EDC and is used to adjust the divisor.



  To transfer the set numerical values to the arithmetic logic unit, a setting gripper AE is used, whose switching arms wae1 to wae11 are incrementally advanced by the drive magnet DAE. A sequence switch is assigned to this tap, which closes the contacts marked 0 and I to VI in its individual positions.



  The arithmetic selectors RW are designed for incremental switching in an additive and in a subtractive sense; they are similar to the arithmetic selectors shown in FIG. 1 and in FIG.



  Furthermore, quotient selectors QA to QE are provided, the switching arms wqa to wqe of which are advanced according to the result of the division. The setting of this quotient selector and the calculation selector is determined by a result pick-up AB which controls a type wheel TR.



  It is assumed that the dividend 01728 should be divided by the divisor 064. First, the dividend is set by means of the setting device E. The setting lever EE remains at rest, the setting levers ED to EA are set according to the numerical values 1, 7, 2 and 8. Then, before setting the divisor, a division key TD (FIG. 4) is struck and this energizes relay C, which binds itself. Contact e2 closes a circuit for relay F via position 0 of the sequence switch, which excites the magnet SM, so that the sequence switch comes to position I '. Since the setting lever EE is in the rest position, in this position I a new circuit for relay F is established, which runs via the contact b4 and the contact ee controlled by the setting lever.

   Relay F energizes the magnet SM1 a second time, and the sequence switch moves to position II. Now another circuit for relay F does not come about because the contact ed was opened when the adjustment lever ED was set. The automatic switching of the sequence switch determined how many digits the dividend has.



  The divisor is adjusted with the adjustment levers EDA and EDB while the sequence switch is being switched. In the example assumed, the adjustment lever EDC remains in the rest position. Then the start button TB (Fig. 4) is struck and relay B energized, which binds itself.



  The contact b2 closes the circuit for the drive magnet DAE of the setting tap AE, which then alternates with the relay -1 for the duration of one cycle. During the first 1 "run, contact b5 switches on relay 11S on switching arm wae6.

   If the divisor were single-digit, relay 31S would be energized immediately when contact b5 was closed, since the zero contact of the contact bank would then be connected to the positive pole via the contact corner of the unadjusted setting lever EDC and the unadjusted setting lever EDB. In the example assumed, the divisor has two digits and therefore the lever EDB is adjusted.

   In the first step of the setting tap, a circuit for relay F is thus excited by the contact cal, which enables the sequential switch to be switched to the next position, position 11I. caused. Closes on the first contact in its series of contacts

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 the switching arm wae6 now the circuit for relay MS, which binds and with contact ms2 prevents the relay F from being energized again during the further steps of the setting tap. If the divisor were three-digit, the circuit for relay MS would only come about on the second contact and relay F would be excited twice by contact a2.

   As soon as the setting tap passes through its zero position at the beginning of the second cycle, a relay U is excited via the switching arm wae11, which closes a holding circuit with contact u1. The contacts u2 to u6 connect the test relays NA to NE with the switching arms wae1 to waes, which are prepared in the next switch position III. The contact us closes the circuit for the additive switching of those arithmetic selectors that are prepared in the sequence switch position III.

   During the second cycle of the setting tap AE, the value of the dividend set by the levers ED and EC are thus transferred to the drive magnets RAD and R AC for the additive continuation of the respective arithmetic selectors, so that the switching arms wd1 and wd2 on the first contact, the switching arms wc1 and be set off on the seventh contact. As soon as the switching arms of the setting tap go through the zero position again at the beginning of the third cycle, the arm wae11 closes a circuit for relay 0, which responds, interrupts the holding circuit of relay U with contact o1 and holds itself.



  The contact o5 prepares the circuit for relay W, so that the relays W and H are energized during the following cycles of the setting tap, which interrupt the switching for a certain period of time at the end of a cycle and then drop out one after the other due to their drop-out delay. Contacts o2 to o4 connect the test relays MA to MC to the switching arms wae7 to waes, and contact os closes the circuit for the subtractive switching of the arithmetic selectors. During the third cycle of the switching arms of the setting tap, current impulses are now transmitted from the contact a4 to the magnets RSC and RSD for subtractive incrementation of the arithmetic selectors of the third and fourth digits, which were previously incremented according to the value of the dividend.

   The magnet RSE of the arithmetic selector in the top position does not receive a current surge, because relay MC responds immediately via the zero position of the switching arm wae7. The contact ma4 of the relay MA, which is energized after four switching steps via the switching arm waes, interrupts the current surge transmission on the magnet RSC. The switching arms wc1 and wc2 of this arithmetic selector, which were set to contact 7, are thus switched back to contact 8.

   The contact mbs interrupts the current impulse on the magnet RSD when the relay MB is energized via the switching arm waes after six steps of the setting tap. The switching arms wdl and wd2 of this arithmetic selector, which were set to contact 1, are thus switched back to contact 5 via contact 0. In this case, the extraction relay TE is energized, which with the contact te2 after the relay W has dropped out at the end of the cycle of the pickup switchgear excites the magnet PSE once.

   As a result, the switching arm white of the arithmetic selector of the top position is advanced from the contact 0 in the subtractive sense to the contact 9. Relay TK is energized, which binds and, with contact tk2, prevents one of the quotient selectors (FIG. 4) from progressing, since the one-off deduction of the divisor from the top two digits of the dividend led to a negative result.

   Contact tks energizes relay Y, the circuit of which runs through contact q3 of relay Q; After relay W has dropped out, relay Q is energized for the duration of the dropout delay of relay H. After relay H drops out, relay Q also drops out

 <Desc / Clms Page number 12>

 and with contact q3 it closes a holding circuit for relay Y, prepared by contact y1, in which winding I of relay X is also excited. Relays Y and X are therefore energized during the new cycle of the setting tap.

   As a result, the two place values of the divisor, which were previously transferred to the drive magnets RSC and RSD for subtractive incrementation, are now transferred to the drive magnets RAC and RAD for additive incrementation of the same arithmetic selectors. Contacts x4 and x5 have switched the circuit from the magnets for subtractive incremental switching to that for additive incremental switching. The switch arms wd1 and wd2 come back to the first and the switch arms wc1 and wc2 back to the seventh contact.

   When the ninth contact is passed, the switch arm wrd1 energizes the slam relay 2E, which at the end of the cycle energizes the drive magnet RAE of the arithmetic selector at the top by means of the contact ze2, so that the switch arm we1 comes back to contact 0. In this step, the winding II of the relay TK is energized and thus relay TK is thrown off.



  Simultaneously with this resetting of the adjusted arithmetic selectors, the next value of the dividend is transmitted during the same cycle of the setting tap AE. In the next switch position III the transmission circuit for the drive magnet RAB for additive incremental switching of the arithmetic selector of the second position is closed by the contact y3, so that the current impulses transmitted by the contact a4 act on this magnet. In the next switch position III the relay NB is also connected to the switching arm wae4 via the contact y6, so that it is energized after two switching steps according to the setting of the lever EB on the contact 2 and limits the transmission with contact nb2.

   As soon as relay Q is excited in the manner described at the end of this cycle, contact q3 interrupts the holding circuit of relay 1 ', which drops out.



  Relay X drops out a little later than relay 4Y. A circuit for relay F is therefore temporarily closed via contacts g2 and xs, which switches the sequence switch to position IV. During the next cycle of the setting tap AE, current surges are now transmitted to the magnets for subtractive incrementation of the arithmetic selectors of the second and third digits in accordance with the position values of the divisor. The relay MA limits the advancement of the magnet RSB with contact ma5, and relay MB limits the advancement of the magnet RSC with contact mb4. At the end of this flow of the setting tap AE, the switching arms wd1 and wd2 are on the first contact, the switching arms wc1 and wc2 on the zeroth contact and the switching arms wb1 and wb2 on the eighth contact.

   When relay Wl drops, relay Q responds. After the relay H has dropped out, the magnet QB of the quotient selector of the second position is excited via the contacts tk2, h3, q1, IV, which advances the switching arm wqb by one step.



  When the relay H drops out, a new cycle of the setting tap AE is initiated, during which the same process is repeated. At the end of this cycle, the switching arms wd1 and wd2 are on contact 0. wc1 and wce2 on contact 4 and abi and ic, b2 on contact 4. The Q, dialer QB is advanced a second time. 'During the next cycle of the setting tap, the digits of the divisor are subtracted from the numerical value set on the arithmetic selectors.

   The result is negative again, so that relay TK responds, which prevents the quotient selector from switching and causes relays Y and X to be energized. During the following cycle of the setting tap AE, the position values of the divisor become the negative intermediate result in the manner described

 <Desc / Clms Page number 13>

 added again so that the numerical value set by the arithmetic selectors for the second and third digits becomes positive again. At the same time, thanks to the closing of contacts y3 and p7, the value of the units place of the dividend is transferred to the magnet RAA for the additive incremental switching of the arithmetic selector of the lowest place.

   When relays Y and X drop, the sequence switch is then switched to position V.



  In position V, the numerical value of the divisor's digits is transferred to the magnet RSA for subtractive incrementation of the arithmetic selector of the lowest digit and the numerical value of the tens of the divisor is transferred to the drive magnet RSB for subtractive incrementation of the arithmetic selector of the second digit. If a positive remainder remains after the cycle, then the quotient selector QA is incremented once by the excitation of the relay Q. This game is repeated seven times in the assumed example.

   As soon as relay Q is energized after the seventh cycle of the setting tap and the quotient selector QA advances to the seventh step, the switching arms of all arithmetic selectors are on their zeroth contact. About the switching arms what to Wes, the circuit for a relay G is closed in position V of the sequence switch through contact q4, which is self-supporting. Contact g5 interrupts the holding circuit of relay C, contact y2 closes the circuit for a relay RS, which is maintained and with contacts rs2 and r s4 interrupts the holding circuits of relays B and O. When relay C drops out, contact c2 closes a circuit for relay F, which causes the sequence switch to switch to position 0.



  The contact g3 of the energized relay G sets the result tap AR in motion. The magnet DAR, which incrementally advances the switch arms wait until war12, works in interplay with a relay AR. The test relay PD is connected one after the other to the individual switching arms of the result pick-up via the switching arm ws1 of a distributor selector, which is advanced by the magnet SMR. If the test relay PD responds, then the pressure magnet DM is excited via contact pd1, which causes the imprint of the relevant type. In the meantime, the contact pd2 interrupts the progression of the result pick-up and closes the circuit for a relay FR, which excites the magnet SMR for the purpose of advancing the distributor selector by one step.



  In the example assumed, the switching arm wqb is set to the second and the switching arm wqa to the seventh contact. The numbers 0002'7 are printed one after the other on the type wheel TR. Then the test relay PD is connected to the switching arm of the result pickup. In the row of contacts of this switching arm, a special eleventh contact is firmly connected to the positive pole. The type wheel TR carries a letter type in the corresponding angular position, e.g.

   B. "R", which indicates that the following numbers, which are printed, reflect the remainder. Since the division worked without a remainder in the example, the number types 00000 are then printed.



  If, on the other hand, the result is negative during the last cycle of the setting tap AE while the sequence switch is in position V and relay TK is excited, then relays Y and X are also excited one after the other in the manner described. Contact ys only closes the circuit for relay G when relay TK has dropped out again. Under the influence of the contacts of relay X, the divisor is added again in the manner described during one cycle of the setting tap AF, so that the arithmetic selectors indicate a positive remainder.

   Relay G then responds, which

 <Desc / Clms Page number 14>

    The result gripper is set in motion and the result set on the quotient selectors and the remainder set on the arithmetic selectors are printed out.



  The setting of the numerical values, which form the basis for the calculation. can also be done using buttons. In the arrangement shown in FIG. 6, a row of keys ET is provided for each digit of the number to be set. When pressed, the buttons in each row place the positive pole on a contact that is controlled by a switching arm ae1 or. ae2 of a pick-up switching mechanism coated contact row. The keys are expediently designed so that they are held in their depressed position after the stop by a rocker or the like, which is actuated when another key in the same row is pressed, so that the first pressed key pops out and the newly pressed key is held . Such devices are known from the so-called full keyboards of calculating machines.



  The individual numerical values can also be set using selectors. 7 shows an arrangement, for example, in which a WVä is provided here for the lowest digit of the number to be set, the switching arm of which is advanced by a drive magnet EA. The voter eb, EB is assigned to the second position and the voter ec, EC to the third position. The rows of contacts swept by the switching arms of this selector are wired in a known manner with the rows of contacts of the setting tap. The current surges for setting these voters are given by means of a dial, as is known in automatic telephone systems. Such a dial carries the individual numbers and finger holes.

   To emit the current impulses, the finger is inserted into the hole assigned to the desired number and the disc is rotated until it stops. The disc is then released. When the disc rotates back under the influence of a spring, the spring actuates a surge contact nsi as often as it corresponds to the numerical value. A contact nsa is closed while the disk is rotating. In the embodiment shown in FIG. 7, the drive magnets of the individual selectors are successively connected to the contact nsi via a sequence switch. A start button AT is pressed and a relay C is energized before it is used. During each rotation of the dial, a relay W 'is excited by the contact nsa, which switches on a delay relay H.

   When the N dial is run for the first time, the current surges reach the magnet EC via the follower switch contact vI. The relays W and H then drop one after the other. The sequential switch magnet VMl is excited and switches to position II, in which contact vII is closed. The current impulses of the second series of current impulses now reach the magnet EB. The setting selectors are set one after the other.



  In the arrangement shown in FIG. 8, individual rails ES of a croup of five rails are connected to the positive pole by the number keys ET, one of which is indicated. A sequence switch connects five relays to the rails ES "at the same time, which via their contacts connect a contact in a contact row of the setting tap _1E to the positive pole.

   For example, the illustrated key ET connects the first, third and fourth of the rails ES to the positive pole; this energizes relays RE, RC and RB at the same time. The seventh contact in the row of contacts of the tap AE is thus connected to the positive pole via the contacts ra, rbi, rc2, rei.



  In another position of the sequence switch, which is only indicated by the position I in the drawing, another group of relays is connected to the rails ES, the contacts of which are circuits

 <Desc / Clms Page number 15>

 Close via another row of contacts on the pickup switchgear. As a result, it is possible to use the same ten keys to sequentially transfer the digit values of the multi-digit number to be set.



  In FIGS. 1 to 4, various embodiments for the design of the pickup switching mechanisms are shown. The setting taps can be designed in such a way that their switching arms are activated one after the other by a sequence switch; in this case, only one place value is transferred to an arithmetic selector during each cycle (see FIG. 1). However, all the switching arms of the pickup switching mechanism can also be effective at the same time (see FIG. 2), so that all the value values are transferred simultaneously to different arithmetic selectors.



  In the exemplary embodiments described, a common pick-up switching mechanism AR, whose shaft carries a type wheel, is used to determine all the values of the result. Instead of an imprint of the number type from this type wheel, individual pressure magnets could also be excited via further switching arms of the pickup switching mechanism, which bring the corresponding number type to the imprint by stopping a type lever. If an imprint of the numerical values, i.e. a permanent display, is not required, but if the result is only to be displayed temporarily, then a special switching mechanism is expediently provided for each point, which carries a number disc and which adjusts to the contact made by the switching arm of the assigned arithmetic selector is marked electrically.

   The numbers set by the individual number discs of the various switching mechanisms can then be made visible behind a window. All these display switchgear can be set simultaneously when the result is requested.



  In the examples described, a comma is not shown between individual numerical values. The comma can be transmitted in a position of the sequence switch provided for this purpose. The print of the comma can be effected by a type of the type wheel TR, whereby the setting of the result tap can be initiated in the same way as is shown for the print of the residual character in the exemplary embodiments of FIGS. 3 and 4.



  The electrical control of the individual calculator selectors makes it possible that the setting devices and the printing devices respectively. the display devices are assembled in a small device, while the stepping mechanisms, i.e. the setting grabs and the arithmetic logic unit, the sequence switches and the required relays are arranged in a separate frame that is simply connected to the device by cables.



  It is also possible to use one and the same result tapping mechanism to determine the result set by different sets of arithmetic selectors. A tapping switch mechanism can also control setting selectors in the manner of the setting selectors shown in FIG. 7, which set the numerical value of the result as the starting value for a new arithmetic operation. This makes it possible to combine any arithmetic operations with one another.



  Lengthy arithmetic operations can also be broken down into sub-operations, which are carried out simultaneously by different arithmetic units. For example, if the number 9999999 is to be multiplied by the number 9999999, it is possible to multiply the number 9999999 by the number 9999000 in one calculator for multiplication and to multiply the number 9999999 by the number 999 in another calculator for multiplication. The two partial results are then added together in an arithmetic unit for addition and produce the correct final result.

 <Desc / Clms Page number 16>



 

Claims (1)

PATENT CLAIM Electric calculating machine, characterized in that for each digit of a multi-digit number to be set there is an arm of a pick-up switching mechanism which sweeps a row of contacts, on whose row of contacts the value is electrically identified, and which, when looking for the designated contact, sends a number of current impulses corresponding to the value to a stepping mechanism provided for the relevant arithmetic operation. U LATERAN PROBLEMS 1. Electric calculating machine according to claim, characterized in that as many arithmetic selectors designed as stepping mechanisms are provided for one arithmetic operation as there are digits for the result. 2. Electric calculating machine according to claim and dependent claim 1, characterized in that each arithmetic unit has at least one switching arm sweeping a row of contacts which, by its setting, electrically identifies a contact corresponding to the value of the result on a bank of contacts coated by the arm of a pick-up switching mechanism. B. Electric calculating machine according to claim and dependent claim 1, characterized in that the arithmetic selectors are designed as ten-part stepping mechanisms. 4th Electric calculating machine according to claim and dependent claims 1 and 3, characterized in that each arithmetic controller has two drive magnets, one of which advances the switching arms incrementally in an additive sense and the other incrementally advances the switching arms in a subtractive sense. 5. Electrical calculating machine according to claim and dependent claims 1 and 2, characterized in that a switching means controlled by an arithmetic selector, when it is advanced in an additive sense from the contact that corresponds to the highest priority, closes a circuit which switches the next one Position of the result assigned arithmetic selector by one step to a higher value. 6th Electric calculating machine according to claim and dependent claims 1, 2 and 5, characterized in that a switching arm of an arithmetic selector closes the circuit for a transmission relay when the contact corresponding to the highest priority is advanced, and the relay for the next digit of the result is advanced assigned calculation selector by one step to a higher priority. 7th Electric calculating machine according to patent claim and dependent claims 1 and 5, characterized in that the switching means. which is controlled by the row selector assigned to the top position of the result, and when it is switched on by the contact corresponding to the highest priority, a signal is switched on. B. Electric calculating machine according to claim and dependent claims 1 to 4, characterized in that a switching means controlled by an arithmetic selector, when it is switched in a subtractive sense from the contact corresponding to the lowest value, closes a circuit which maintains the next higher digit of the result Arithmetic voter in the subtractive sense. 9. Electric calculating machine according to patent claim and dependent claims 1, 2, 3, 4 and 8, characterized in that a switching arm of a calculator selector when advancing from the contact corresponding to the lowest place value, the excitation circuit for a transmission <Desc / Clms Page number 17> relay closes, which holds itself, and prepares the advance of the arithmetic selector assigned to the next digit of the result by one step to a lower value. 10. Electric calculating machine according to claim and dependent claims 1, 2, 3, 4 and 8, characterized in that the switching means, which is controlled by the arithmetic selector assigned to the highest digit, a contact corresponding to the lowest value of this digit when it is advanced in a subtractive sense Circuit for an identification relay closes, which holds itself. 11. Electrical calculating machine according to claim and dependent claims 1 to 10, characterized in that the switching means controlled by the arithmetic selector of the top position makes the identification relay ineffective again when the arithmetic selector is advanced in an additive sense from the contact corresponding to the highest digit. 12. Electric calculating machine according to patent claim and dependent claims 1 to 3, characterized in that the contact corresponding to the highest priority of a contact row swept by a switching arm of a calculator selector is connected to a contact controlled by the drive magnet for additive incremental switching. 13. Electrical calculating machine according to claim and dependent claims 1 to 4, characterized in that the lowest value corresponding contact of a row of contacts swept by a switching arm of a calculator selector is connected to a contact controlled by the drive magnet for subtractive incremental switching. 14th Electric calculator according to claim and dependent claims 1 to 4, 12 and 13, characterized in that the contact corresponding to the highest priority and the lowest priority is arranged in the row of contacts swept by the same switching arm. 15. Electrical calculating machine according to claim and dependent claims 1, 2, 3, 4, 8 and 10, characterized in that the identification relay prepares the tapping of a result value which is complementary to the numerical values corresponding to the setting of the arithmetic logic unit. 16. Electric calculator according to patent claim and dependent claims 1, 2, 3 and 4, characterized in that the arithmetic selectors equipped with two drive magnets have switching arms which brush two separate rows of contacts, the contacts of which are connected to one another in counter-counting manner and which are optionally effective depending on the actuation of the identification relay be made. 17. Electrical calculating machine according to claim and dependent claims 1, 2, 3, 4, 8, 10, 15 and 16, characterized in that the identification relay prepares an incremental switching of all arithmetic selectors with the exception of the arithmetic selector corresponding to the ones digit of the result by one step in an additive sense . 18th Electric calculating machine according to patent claim and dependent claims 1 and \ -, characterized in that the result tapping switching mechanism controls devices for identifying the value set by a calculator selector. 19. Electrical calculating machine according to claim and dependent claims 1, 2 and 18, characterized in that for each arithmetic selector assigned to a position of the result, a tapping switchgear is provided which controls a number disk. 20th Electric calculating machine according to claim and dependent claims 1, 2 and 18, characterized in that for <Desc / Clms Page number 18> All arithmetic selectors a common tapping switch is provided which has at least one number of rows of contacts and switching arms corresponding to the number of arithmetic counters and whose individual switching arms are made effective one after the other by a sequence switch to determine the individual values of the result. 21. Electrical calculating machine according to claim and dependent claims 1, 2, 18 and 20, characterized in that the pick-up switching mechanism controls a type wheel which carries number types for printing the place values. 22nd Electric calculating machine according to patent claim and dependent claims 1, 2, 18 and 20, characterized in that the tapping switching mechanism controls switching means for the combinational control of individual selection magnets of an electromagnetically controlled writing device. 23. Electrical calculating machine according to claim and dependent claims 1, 2, 18, 20 and 21, characterized in that the type wheel carries other types for printing additional characters in addition to the number types. 24. Electric calculating machine according to claim and dependent claims 1, 2, 18 and 20, characterized in that the tapping switching mechanism controls means for setting memory selectors, which electrically identify numerical values by means of a switching arm each in preparation for an arithmetic operation. 25th Electric calculating machine according to patent claim, characterized in that a common pick-up switching mechanism is provided for all places of a set number, which has at least one number of rows of contacts and switching arms corresponding to the places. 26. Electrical calculating machine according to claim and dependent claim 25, characterized in that the tapping switching mechanism controls switching means for emitting current surges when it is switched on. 27. Electric calculating machine according to patent claim and subclaims 25 and 26, characterized in that a test means is energized via each switching arm when it hits an electrically marked contact corresponding to the value of the set number, which is self-contained for the remaining duration of the rotation of the switching arms and the transmission of the current surges to the assigned arithmetic selector is prevented. 8th. Electric calculating machine according to patent claim and dependent claims 25 to 27, characterized in that a sequence switch assigned to the tapping switching mechanism makes the individual switching arms and the corresponding arithmetic selectors effective one after the other. 29. Elelz: #trische calculating machine according to claim and dependent claims 1, 2, 5, 6 and 25 to 28, characterized in that switching means assigned to the pickup switchgear temporarily stop the switching arms at the end of each cycle and initiate the prepared additional advance of the arithmetic selector. 30th Electric calculating machine according to patent claim and dependent claims 1, 2, 5, 6 and 25 to 29, characterized in that these switching means cause the sequential switch to be switched on. 31. Electrical calculating machine according to claim and sub-claims 1, 2.5, 6 and 25 to 29, characterized in that these switching means interrupt the holding circuit of the test equipment. 32. Electrical calculating machine according to patent claim, characterized in that several setting levers are provided, each covering a row of contacts, to identify the values of a number, which via each contact of their row of contacts an electrical potential to the corresponding contact of the <Desc / Clms Page number 19> create an orderly series of contacts of the pickup switchgear. 33. Electrical calculating machine according to claim, characterized in that a row of keys is provided for each digit of a number, each of which applies an electrical potential to the corresponding contact of the associated row of contacts of the pickup switching mechanism when actuated. 34. Electric calculating machine according to patent claim, characterized in that for each digit of a number a spoke selector is provided which can be set by current surges, the switching arms of which apply an electrical potential to the corresponding contact of the associated contact row of the tapping switching mechanism via each contact of its contact row. 35. Electrical calculating machine according to claim and dependent claim 34, characterized in that switching means assigned to the memory selectors feed the series of current pulses sent by a dial to the individual memory selectors one after the other. 36. Electric calculating machine according to claim, characterized in that each number key above all number keys common rails connected to combination relays excites individual combination relays, the contacts of which apply an electrical potential to the contact of the contact row of a pick-up switching mechanism corresponding to the number key pressed. 37. Electrical calculating machine according to claim and dependent claim 36, characterized in that different groups of combination relays are successively connected to the common rails via a sequence switch, the contacts of which are each assigned to a row of contacts of the tapping switching mechanism. 38. Electric calculating machine according to claim and dependent claims 1, 2, 3 and 4, characterized in that switching means optionally depending on the actuation of an incentive button for addition and for subtraction, the current surges sent by the pickup switching mechanism to the drive magnets for additive incremental switching and the drive magnets for - Conduct subtractive progression of the calculation selector. 39. Electric calculating machine according to patent claim and dependent claims 1 and 2, characterized in that two tapping switching devices are provided for determining the multiplicand set for a multiplication and the set multiplier. 40. Electrical calculating machine according to claim and dependent claims 1, 2 and 39, characterized in that a test relay is connected to each of the switching arms of the Aiultiplikanden- tap, which, when energized via the marked contact, interrupts the drive circuit of the respective arithmetic selector, so that all values of the multiplicand are transferred to the assigned arithmetic selectors with one rotation of the tap. 41. Electric calculating machine according to patent claim and dependent claims 1, 2, 39 and 40, characterized in that the multiplicator gripper causes the multiple transfer of the digit values of the multiplicand to the arithmetic selectors as a function of the set value. 42. Electrical calculating machine according to claim and dependent claims 1, 2, 39 to 41, characterized in that switching means assigned to the multiplicand picker advance the multiplier pickup by one step after each revolution and then cause a new turn of the multiplicand pickup. 43. Electric calculating machine according to claim and dependent claims 1, 2, <Desc / Clms Page number 20> 39 to 42, characterized in that a sequence switch assigned to the multiplier tap activates the switching arms of the multiplier tap assigned to the lowest position and the switching arms of the multiplier tap assigned to the higher positions of the multiplier. 44. Electrical calculating machine according to claim and dependent claims 1, 2, 39 to 43, characterized in that the test means excited via a switch of the multiplier tap causes the sequential switch to be switched on. 45. Electric calculating machine according to patent claim and dependent claims 1, 2, 39 to 44, characterized in that the test means causes the multiplier tap to be automatically switched to its rest position. 46. Electrical calculating machine according to claim and dependent claims 1, 2, 39 to 44, characterized in that the sequence switch transfers the stepping current circuits, which are controlled by the test relays assigned to the individual digits of the multiplicand, to the arithmetic selector corresponding to the relevant digit of the multiplier switches. 47. Electric calculating machine according to patent claim and dependent claims 1, 2, 39 to 46, characterized in that switching means of the multiplier tap cause the multi-digit result identified by the arithmetic selectors to be picked up when determining the value of the highest multiplier digit. 48. Electrical calculating machine according to claim and dependent claims 1 to 5 and 8, characterized in that a common tapping switch is provided for transmitting the dividend set for a division and the set divisor. 49. Electrical calculating machine according to claim and dependent claims 1 to 5, 8 and 48, characterized in that switching means assigned to the division tap determine the number of digits of the dividend. 50. Electric calculating machine according to patent claim and dependent claims 1 to 5, 8, 48 and 49, characterized in that these switching means are activated by an incentive button independently of the setting of the divisor. 51. Electrical calculating machine according to claim and dependent claims 1 to 5, 8, 48 to 50, characterized in that switching means assigned to the tap determine the number of digits of the divisor. 52. Electrical calculating machine according to claim and dependent claims 1 to 5, 8, 48 to 51, characterized in that a sequence switch which is advanced according to the number of digits of the dividend is also advanced as a function of the number of digits of the divisor. 53. Electrical calculating machine according to patent claim and sub-claims 1 to 5, 8, 48 to 52, characterized in that a switching arm is activated during a first ITmlaufes of the dividend pickup, the row of contacts thereof. is connected to rest position contacts of the divisor setting means, while the current surges generated during the runner-up act on the sequence switch. 54. Electric calculating machine according to patent claim and subclaims 1 to 5, 8, 48 to 53, characterized in that during a second cycle of the tap of the sequence switch, the incrementing of a number of arithmetic selectors corresponding to the number of the divisor position in an additive sense depending on the value of the above Dividend places arranged. 55. Electric calculating machine according to claim and dependent claims 1 to 5. B. 48 to 54, characterized in that after the second cycle of the waste <Desc / Clms Page number 21> gripper's switching means (O) become effective, which make the switching arms that determine the values of the divisor effective during the following cycle of the gripper. 56. Electrical calculating machine according to claim and dependent claims 1 to 5, 8, 48 to 55, characterized in that the switching means (O) cause the transmission of the series of current pulses corresponding to the values of the divider to the drive magnets for subtractive incremental switching of those arithmetic selectors which the previous additive increment are preset. 57. Electric calculating machine according to patent claim and dependent claims 1 to 5, 8, 48 to 56, characterized in that the switching means (O) cause a quotient memory to be incremented after each transmission of the divisor. 58. Electrical calculating machine according to claim and dependent claims 1 to 5, 8, 48 to 57, characterized in that the quotient memory comprises a plurality of memory selectors which are made effective one after the other by the sequence switch. 59. Electrical calculating machine according to claim and dependent claims 1 to 5, 48 to 58, characterized in that a that the identification relay (TK), which is excited when the arithmetic selector is set negative, prevents the quotient memory from being continued. 60. Electric calculating machine according to claim and subclaims 1 to. 5, 8, 48 to 59, characterized in that the identification relay initiates a single transmission of the series of current impulses corresponding to the digit values of the divisor to the incremental magnets for additive incrementation of the selected arithmetic logic unit. 61. Electric calculating machine according to claim and dependent claims 1 to 21 5, 8, 48 to 60, characterized in that the identification relay causes the transmission of a further value of the dividend to a further arithmetic controller. Electric calculating machine according to patent claim and dependent claims 1 to 5, 8, 48 to 61, characterized in that switching means (X, Y) controlled by the identification relay (TK), the one-time addition of the divisor and the transmission of the next place value to a calculator selector during the same cycle of the pickup switchgear. Electric calculating machine according to claim and dependent claims 1 to 5, 8, 48 to 62, characterized in that the switching means (X, Y) prepare the drive magnets for subtractive incremental switching of at least the newly set arithmetic selector at the end of this cycle of the tap. :. Electric calculating machine according to patent claim and dependent claims 1 to 5, 8, 48 to 63, characterized in that the switching means cause the sequential switch to be switched which reverses the drive circuits of the calculator selectors. Electric calculating machine according to patent claim and dependent claims 1 to 5, 8, 48 to 64, characterized in that when the division ends, a closing relay is energized which causes the result to be tapped from the quotient memory. Electric calculating machine according to patent claim and dependent claims 1 to 5, 8, 48 to 65, characterized in that the identification relay initiates the tapping of the residual value from the arithmetic selectors with simultaneous identification in the presence of a negative remainder after adding the divisor once.