BE405589A - - Google Patents

Description

       

   <Desc / Clms Page number 1>
 for: "Improvements to accounting machines and more particularly to accounting machines controlled by punched cards"
The present invention relates to accounting machines and more particularly to accounting machines of the type controlled by punched cards.



   The main object of the invention is an accumulator or totalizer mechanism for tabulating machines, a mechanism of improved form and of greater selectivity in operation. thanks to which one can carry out calculations with greater efficiency, greater precision astonishes greater speed than hitherto, the number of

 <Desc / Clms Page number 2>

 moving parts being much less in this mechanism than in the accumulator or totalizer mechanisms !! already known.



   In a more particular way, the object of the invention is an electromagnetic accumulator or counter of a new form, in which the element which operates the accumulation or totalization is constituted by an armature capable of rotating under the control of two electro-magnetic fields which are established alternately, the entry of a quantity in each order of magnitude being effected by the repeated alternating change of the direction in which the two magnetic fields are established.



   The invention also relates to an accumulator or counter operating by means of an electromagnet and in which the parts relating to the different orders of magnitude are mechanically independent of each other and in which an improved transfer mechanism has been provided for the passage of quantities of an order of magnitude to the order of magnitude immediately higher.



   The subject of the invention is also an improved accumulator or counter used for carrying out subtractions, a counter in which the quantity to be subtracted is introduced by addition in the form of its complement.



     Other purposes and advantages of the. present invention will become clear from the particular description which follows of two embodiments of mechanisms executed in accordance with the iaventioa or from the inspection of the accompanying drawings, in which:

 <Desc / Clms Page number 3>

 different mechanisms; FIG. 2 is a diagram showing the adjustment, over time, of the electrical devices of the machine;

   FIG. 3 is a median section through the card feed and analysis mechanism of the machine, the section being taken substantially along 3-3 of FIG. 1; FIG. 3 & shows the detail of the start key and the stop key; FIG. 4 is a section on 4-4 of FIG. 1 and shows the control links for the mechanism for supplying and analyzing the cards; Figure 5 is a median section of the printing mechanism of the machine, the section being taken substantially along 5-5 of Figure 1; Fig. 6 is a diagram showing the adjustment over time of an apparatus performed in accordance with another embodiment of the invention;

   FIG. 7 shows in detail one of the sets of parts relating to the different orders of magnitude of the accumulator or totalizer mechanism, the section being taken substantially along 7-7 of FIG. 1; FIG. 8 is a plan with partial section of the parts corresponding to a certain number of orders of magnitude of the totalizing mechanism; Figure 9 is a section on 9-9 of Figure 7 and shows the arrangement and construction of one of the sets of parts of the totalizer mechanism;

   Figures 10, 11, 12 and 13 are sections taken on 10-10, 11-11, 12-12 and 13-13 of Figure 9; Figures 14 and 14a placed side by side constitute a connection diagram of the electrical circuits of the machine;

 <Desc / Clms Page number 4>

 FIG. 15 represents a modified embodiment of the invention and shows the key input device for controlling the operation of the accumulators or totalizers; FIG. 16 is a partial plan of the keyboard corresponding to this embodiment;

   Figure 17 is a section on 17-17 of Figure 16 and shows the detail of some of the control keys established in accordance with this latter embodiment of the invention; FIG. 18 is a circuit diagram corresponding to this last embodiment of the invention *
GENERAL DISFOSITION
The various main assemblies of the machine are arranged as shown in fig. 1, the card feeding and analysis mechanism being placed on the left, a mechanism through which the punched cards are brought one by one in front of the analyzer brushes. which reveal the indication represented by perforations located in different places.

   The printing mechanism is disposed in the vicinity of the card supply mechanism and it is capable of being controlled by the circuits which close through the perforations of the cards to record in printed characters the meaning of the perforations analyzed. The accumulator or totalizer mechanisms are arranged to the right of the printing mechanism and each of them comprises several separate totalizer assemblies. These assemblies are preferably arranged in groups of five and two of these groups are shown mounted on the main frame of the machine. These groups have no mechanical connection with the rest of the machine and we

 <Desc / Clms Page number 5>

 as compared to the rest of the mechanism.

   If desired, they can be placed in a location remote from the machine itself, and as many assemblies can be used as necessary for the kind of work to be performed by the machine.



   Under the printing and totalizing mechanism, there is provided a 4-plug table provided with appropriate plug sockets by means of which the different mechanisms can be coordinated according to the requirements of the work to be performed.



   CONTROL SYSTEM
The energy for controlling the mechanical devices of the machine is supplied by a motor M (see fig.l) which is connected by a belt and pulley connection 10 (see also figure 3) to a shaft 11. On the shaft There is mounted a toothed wheel 12 meshing with a toothed wheel 13 integral with a clutch control element 14 freely mounted on a shaft 15.



  On the shaft 15 is fixed an arm 16 which carries a clutch pawl 17 actuated by a spring and normally maintained in the position shown in Figure 3 by a release arm 18 pivoting at 19 and controlled for its operation by an electromagnet 20, The energization of the electromagnet 20 opens the contact 20a and oscillates the arm 18 in a counterclockwise direction to release the pawl 17 from the control element. clutch 14, after which the shaft 15 rotates with wheel 13 until the electromagnet 30 ceases to be energized and the arm 18 therefore causes the clutch linkage to be released.

   In FIG. 4, it can be seen that the shaft 15 is provided with a toothed wheel 21 by means of which the mechanism for feeding and analyzing the cards of the machine is controlled. This mechanism will be described

 <Desc / Clms Page number 6>

 later with more detail.



   The shaft It passes through the card feed mechanism, extends to the printing mechanism and carries a toothed wheel 22 (see figure µ) which, by idle wheels 23, controls a toothed wheel 24 on the 'shaft 25. A clutch control element 26 is integral with the toothed wheel 24 and cooperates with a clutch pawl 27 on which a spring acts and which is carried by an arm 28 fixed on the shaft 25. 28 and the pawl 27 are held in the position shown in Figure 5 by an arm 29 pivoting at 30.

   The arm 29 is controlled by an electromagnet 31 which, when energized, oscillates the arm 29 counterclockwise to release the arm 28 and the pawl 27 so that the latter engages. with the control unit 26 @
It is clear that the card feeding mechanism and the printing mechanism can be connected by their respective clutch mechanisms to the main control shaft 11 of the machine, so that the fine mechanism of the machine. cards can operate independently of the printing mechanism and vice versa *
CARD FEEDING AND ANALYSIS MECHANISM
When the card feed mechanism is connected by clutch to the main drive shaft 11,

   the punched cards R are driven down one by one from the magazine 32 by a reciprocating pusher 33 which advances the lower edge of the card to a pair of feed rollers 34 which then pass it past a set of brooms upper @@ then up to other 35 food roll sets that continue to, move the card down in front of a set
 EMI6.1
 da t) a1 << c -1 ---- .¯s¯¯¯ T

 <Desc / Clms Page number 7>

 food 36 advance said card in a mechanism
 EMI7.1
 Stacking mechanism adsîgn6 as a whole by 37, so that said card is deposited on a discharge stack 38.

   The stacking mechanism consists of a drum 39 provided with a certain number of clamps 40 capable of pivoting and on which a spring acts, said clamps being intended to receive the cards and being capable of successively engaging a roller to fixed cam 41 when said clamps pass in front of it.
 EMI7.2
 This action takes place when the leading edge of the card approaches the drum and is time adjusted so that this edge is gripped by the gripper when the card comes off the roll.
 EMI7.3
 



  On figure 4 we have shown the control mechanism for the pusher 33 and for the various
 EMI7.4
 sets of feed rollers or rollers. The pusher mechanism is carried by a stick 42 connected, by means of a connecting rod 43, to a crank button mounted on a toothed wheel 44. This is controlled from the toothed wheel 21, which the shaft carries. 15, by a gear train designated as a whole by 45 and which, in combination
 EMI7.5
 naison with other engcopages, is used, as it was indicated, to control the shafts 34.1. rollers 34, the shafts 35a of the rollers 35 and the shafts 36, A, of the rollers 36.

   One of the toothed wheels 45 further serves, by means of a gear train designated as a whole by 46, to control the wheel 47 which is fixed on the stacking drum 39.
 EMI7.6
 MEBANIsm t The printing mechanism is shown
 EMI7.7
 in Figure S and it is controlled, as was said above, from the shaft, which carries a grooved cam 48. A roller 49 controlled by the groove of the cam is carried by an arm SO and causes oscillation

 <Desc / Clms Page number 8>

 of a shaft 51. On the shaft 51 are fixed two arms 52 connected, by connecting rods 53, to a stick 54 which, when the caries supply and impression mechanisms are both operating, performs a vertical reciprocating movement. to each card fed by the feed mechanism.



  On the butt 54 are mounted, so as to be able to slide, type carriers 55 normally maintained in the position shown in FIG. 5 by arms 56 on which the springs act. When the stock moves upwards, the arms 56 drive the type holders 55 and the elements 57 are present successively in front of the printing roller 58. each of the type holders is able to have a certain number of ratchet teeth 59. which cooperate with a pawl 60 on which a spring acts and which. normally, is maintained in the position shown by a latch 61 connected, by a return wire 62, to the L-shaped frame 63 of the printing electromagnet 64, an electromagnet and a mechanism. connection being provided for each type carrier.

     The electromagnet 64 can be energized at different times during the upward movement of the type carriers and this excitation has the consequence that which 61 releases the pawl 60 so that said pawl can engage with one of the pawls. teeth 59, which stops any subsequent upward movement of the corresponding type holder without hindering the invariable movement of the butt.



   A printing hammer 65 is provided for each of the type holders and, as the drop types move upward, the hammers are withdrawn or, in other words, the hammers can swing counterclockwise. a watch.



   At the end of the upward movement d: the
 EMI8.1
 "" J'8t \ ae ... "........- 1.- --- ¯8f¯- ...

 <Desc / Clms Page number 9>

 position, the hammers of the type carriers are forcefully thrown in a clockwise direction against the type carrier elements which are in the correct position, this action being linked to produce an impression from said elements.

   The mechanism intended to operate the aforementioned hammers comprises a cross member 66 pivoting at 67 and connected, by means of a connecting rod 68, to a member 69 which pivots at 70. On the arm 52 pivots at 71 a member 72 whose end free engages an arm of the member 69 and rotates the latter clockwise, despite the action. antagonist of its spring 73, when the butt 54 rises. In the vicinity of the upper end of the movement of the butt 54, an ankle 74 carried by the member 72 engages with a fixed stop 75, which has the effect that the free end of the member 72 releases the pawl 69, after which the spring 73 returns the member 69 to its normal position, and.

   by means of the connecting rod 68. oscillates the span. 66 and hammers 65 quickly clockwise to make the impression.



  The mechanisms of card fine, analysis and printing which have just been described are similar to those which are used in the tabulating machines known heretofore as regards their general organization and mode of operation and the description of these mechanisms has therefore been limited to the essential characteristics necessary for the understanding of the plant invention.



   ACCUMULATOR MECHANISM
The accumulator mechanism, the construction and mode of operation of which constitute the main feature of the present invention, will now be explained in detail with regard to its gold.

 <Desc / Clms Page number 10>

   nization, after which the circuit diagram will be explained to show how the accumulating or totaling mechanism is coordinated with the card feeding mechanism and the printing mechanism.

   
 EMI10.1
 The whole ae # mula.teur or totalizer ,, as was said above, is constituted by several individual organs relating to orders of magnitude
 EMI10.2
 determined, organs which have no mechanical link with each other and in fact that all the organs relating to the different orders are identical from the point of view of their construction and their organization, a detailed description referring to one of these organs will suffice for all.



   The mechanism of each set is mounted
 EMI10.3
 on a support plate? 5 (figi7,8 and ') 4 On the plate 7S are two electromagnets 76 and W, the pole pieces 78 of which are arranged in a
 EMI10.4
 circumference around a shaft 7t as shown in figures 7 and 10 * On ltutra 7 'and in the same plane as the pole pieces 78 is a rotor 80 provided with ten teeth 81 of identical shape * The position relative of the parts is such that, when two teeth
 EMI10.5
 diametrically opposed 81 dk rotor 80 are 1rolled on the common axis of a pair of pole pieces, the common link of the other pair is in the aspeoo cmpn, wanders the pairs of teeth 81 immediately adjacent to the other pair of pole pieces.

   This provision is represented
 EMI10.6
 shown on a larger scale in FIG. 10 and the operation is such that, when a magnetic circuit is established between the pairs of pole pieces which are located in the vertical plane, the rotor advances from the space of half a tooth to center the rotor in the field.
 EMI10.7
 fl4 - - # -.,.

 <Desc / Clms Page number 11>

 horizontal when the first polar field has disappeared, the rotor 81 advances by another half-tooth, that is to say by 1/20 of a turn. In this way, the successive and alternate excitation of the pairs of electromagnets 76 and 77 causes the rotor to advance step by step and the speed of the advance depends on the rapidity with which the magnetic fields are made to alternate.



   We see in figure 9 that the tree
79 is mounted so that it can rotate in the anterior support 82 and in a posterior bearing 83. Immediately in the vicinity of this bearing, a device is provided to prevent the backward movement of the rotor, the device in question comprising several balls 84 (see also figure 13) which are arranged between a groove presented by the shaft 79 and surfaces 85 in the form of a ramp% arranged in the bearing 83.

   Springs 86 normally urge the balls in the direction shown in Figure 13 and serve to prevent rotation of shaft 79 clockwise with respect to said Figure 13;
When the machine is in operation, a magnetic field is established normally between the horizontal pole pieces 78, this field tending to maintain the rotor in the position shown in FIG. 10. The rotor serves as a totalizing member and every 1/10 of a turn causes entry of a unit. Therefore, if a one-unit entry is to be made, the horizontal magnetic field normally in action is removed and a vertical magnetic field established to move the rotor forward.
1/20 turn.

   The field is then returned to the original horizontal direction, which advances the rotor another 1/20 of a turn. To enter the number "6", the direction of the field is modified twelve times, in order to execute a movement of twelve successive notches.

 <Desc / Clms Page number 12>

 rotor. How the field direction is rotated and the field is kept horizontal to retain the rotor in its new position will be explained in more detail in connection with the description of the circuit diagram.



   The device for advancing a rotor-shaped accnmulatenr on member such as that designated 80 was tested and operated at a speed exceeding 6,400 increases in advancing motion for each cycle. of machine one for each punch card amended in the machine and analyzed.



   At this speed, the indications can be introduced into the totalizing element or organ from 200 cards per minute in a positive and efficient manner, the horizontal magnetic field maintaining the rotor in its displaced position and the balls 84 preventing any retrograde movement. pieces.



   The shaft 79 (see fig. 11) carries a brush 87 which advances at the same time as it and which can occupy any of the ten positions in which the rotor can be held. Around the shaft 79 is disposed a cylinder 88 in which are embedded several studs 89, a stud for each of the positions that the brush 87 can occupy and with which the brush makes contact when the brush] finds it in the correct positions. - respondents.

   The brush 87 and the pads 89 are provided for the purpose of recording indications from the member to the totalizing element during the machine totals pressure operations and the way in which this operation is carried out will be explained in detail in connection with of the circuit diagram.



   On the shaft 79 are also mounted two brushes 91 isolated from said shaft by means of a
 EMI12.1
 nanchon 90 and rw? i 7 t ,, i n # .--- - "- -

 <Desc / Clms Page number 13>

 function of flying off an additional / transfer impulse to the order of magnitude immediately higher when the order to which said brushes are associated passes through zero, In the plane of the brushes '91 and flooded
 EMI13.1
 in cylinder 88.

   two pads' 2 and 93 have been arranged so that, when the rotor 80 is in the
 EMI13.2
 zero position, the brushes 91 are used to electrically connect the pads 92 corresponding to zero and
 EMI13.3
 that when the rotor is in position on3, not to represent the figure '19ft, a similar connection is established between the pads 93.
 EMI13.4
 



  It can be seen from the figure '"that, on each plate 7: i of an accumulator mechanism, four electro-magnet relays 95, 96, 97 and 98 have been mounted, the function of which will be explained in connection with the knowledge diagram.



    For convenience, in the present embodiment. the totalizing members have been arranged in groups of five as can be seen in FIG. 1, each group comprising a complete totalizing assembly of five orders of magnitude. A common boot surrounds each
 EMI13.5
 group to'orôfin "8 relating to five orders, as shown in figqreo 7 and 8 and we have mounted in said box five relays with multiple contacts 99,, p0, '41 162 and 103 which control the contacts associated with the five acc1Ul1uJ.ahurs oros of a particular group.



  .-P, fFQSJTpS C # A 0a. In figures let 4, the shaft 11 carries a den wheel. ée 104 mistletoe, by means of a wheel e: fo.¯ 1. 30.5, entrained Wlo wheel dont6o 106 mounted on a shaft 107 which, in turn, 'by cogwheels 108 controls a shaft lOf, on the shafts 107 and 109 are mounted the various cam-controlled contactor devices and the various cam-controlled pulse distributors; the function of these contactor devices
 EMI13.6
 

 <Desc / Clms Page number 14>

 and these distributors will be described later @ with regard to the connection diagram and the adjustment of these devices over time is shown in the diagram of fig.2.



  A toothed wheel 110 fixed on the shaft 107 drives a toothed wheel 111 mounted on a shaft 112 which, in turn, carries two brushes 113 electrically connected and isolated from the shaft. The brushes 113 tighten to successively connect isolated contactor pads 114 to a common arcuate conductive terminal 115. Thanks to the transmission by gear which must be described, the shafts 107, 1a! and 112 can run constantly as long as the engine is running.



   In Figures 1 and 4, it can be seen that the shaft 15 is provided with cam contactor devices, devices which, due to the fact that the shaft 15 only operates during card feeding operations, operate the contacts. at these times only *
In Fig. 5, the shaft 25 also carries contact control boxes, cams which only operate as the shaft 25 rotates to make lists and to print totals.

   In FIG. 3, it can be seen that two @CL contacts and a pair of similar LCL contacts are provided which are attempted by the usual card levers when the perforated cards R pass in front of the upper brush and lower brush stations respectively. In FIG. 3a the construction of the start key and the stop key has been shown. The key to the left is the start key which, when lowered, closes the contacts STa and STb. The stop key, when it is operated, opens the contact Sp and remains locked in the open position by a pivoting latch 116 on which a spring acts.

   The Sp contact is kept open
 EMI14.1
 thus iusantpin fnnrF4nt, ..,., ... ¯-s¯ 1. -.

 <Desc / Clms Page number 15>

 start, operation which allows the stop key contact to close when the start key contacts are closed.



   CONNECTION DIAGRAM We will now explain in detail the connection diagram (fig. 14 and 14a) and the coordination of the different elements, as will be explained in connection with said elements. Current is supplied to the main conductors 120 and 121 from a suitable source 8 by the closing of the switch 122 of the main line. Immediately after closing switch 122, current flows from source 8 to wire 123, the motor, wire 124 and line wire 120 to source S. This results in operation of shafts 107, 109 and 112 (see fig. 4) and the various cam-controlled contactor devices then operate.



   In order to make the circuit diagram clearer, FIG. 14a has reserved the connections of the circuits of the accumulator or totalizer assembly, while the control circuits of the machine itself, circuits which include the analysis circuits. and printing, are shown in Figure 14. The connections, shown in short dotted lines between the two figures show that the accumulator can be electrically connected to the main part of the machine and that the individual connections can be brought together. in one cable.



   Several relays and several contacts associated with these relays have been shown in the two figures of the diagram. To allow better identification, the contacts operated by the relays have been designated by the same reference number as the corresponding relay.

 <Desc / Clms Page number 16>

 followed by a lower case.



   CONNECTIONS BY PLUG
Before starting up the machine, make the following plug connections, make a plug connection 125 - see fig. 14) between each * of the lower brush bushings corresponding to the card columns whose indications are to be listed and a plug socket 126. This connection establishes the choice of a particular vacuum electromagnet 64 for recording the information cited above in the selected column.



   When the figures are to be totaled, a connection is made by fiéhes 127 from each of the columns to a plug socket 128 (see fig. 14 &) which is associated with one of the elements corresponding to one of the orders of magnitude of the 'accumulator. The circuits which pass through these connections will be indicated below.



  Other connections, such as the one designated 129 (see fig. 14) are made between the pin sockets 130 of the accumulator expression mechanism and the sockets 131 to direct the totals read from the accumulator. accumulator to certain selected printing electromagnets 64. When the cards are placed in the magazine, the machine is ready to start moving the cards. Lowering the start key at this moment closes the ST & contact of said key and the following circuit is established: source S, line wire 120, conductor 124, contact STa, contact CR-1, contact P-2 , contact 132a of the relay electromagnet 132, electromagnet 135, conductor 133, contact 134b of the relay electromagnet 134, conductor 123 and source S.

   The excitation of the electromagnet 135 closes its contacts 135a and 135b, the first of

 <Desc / Clms Page number 17>

 
 EMI17.1
 
 EMI17.2
 7.éLeatro-ai, mant: wire 123, relay contact 184, wire 133, electromagnet 135, contact 13fiA, stop button SP contact, CR-3 contact, wire 124 and line wire 120. The closing of oontaot 1351 establishes the following cirouit through the electromagnet of the clutch of fine cards': wire IZ3, electromagnet dm 20. contact l35J2., wire 136, contact 2 wire 124 and line wire 120.



   When the card feed clutch is engaged, the first card moves down past the upper brushes and Closes the UCL contact of the card lever, which immediately sets the
 EMI17.3
 following circuit, line wire 121, tErL contact, electromagnet 137, wire 124 and line wire 120. Electromagnet 137 closes its 13 "A contact through which current is supplied to the contactor roller of the upper brushb L ' electromagnet 137 also closes its contact 137c which short-circuits the cam contact Ces and maintains the circuit
 EMI17.4
 between stop switch SP contact and wire 124r as long as cards pass the upper $ brushes.



   When the map goes down and goes past
 EMI17.5
 the lower brushes, the iJ1flSrieur LCL contact. lever to. card is closed, which establishes the next circuit '. wire 123, contact tCL, electromagnet 138, wire 124 and line wire l20 The electromagnet 138. closes its contacts 138A, 18, 13â..c .. J.3I (and 138i and opens its contacts 1384 and 138A, as will be indicated later, contact 138b controlling the arrival of current to the common contactor rollers of the brushes
 EMI17.6
 iDftir.ieurs.



    If the machine has to make lists, close the switch 139 and the electromagnet 31 of
 EMI17.7
 1 "print clutch is energized at the same time as 1telOCtro-aima, ut / 0 of the card feed clutch, the

 <Desc / Clms Page number 18>

 following circuit being established: wire 123, electromagnet 31, contact 134d, contact 138f, switch 139, contact 135b, wire 136, contact CR-2, wire 124 and line wire 120.



  In this way, the printing mechanism works simultaneously with the card feed so that, as cards descend and pass the lower brushes, circuits are established for the listing and for the totalization. .



     LIST OMIT
The following listing circuit can be given as an example: line wire 120, brush wire 140 of the pulse distributor D-3, wire 141, contact 138b now closed, contact roller of the lower brushes, perforation of the punched card, lower brush 13, plug socket of the lower brush, plug connection 125, socket 126, contact 142a normally closed, selector electromagnet 64 for printing, contact P-3 closed while the card passes in front of the lower brushes and line wire 121.

   Usually the excitation of the electromagnet 64 which is regulated in time interrupts the movement of the type bar to present the character corresponding to the position of the perforation, in front of the pressure cylinder.



   ADDITION CIRCUIT
An addition circuit will now be indicated by way of example * This circuit is the same as that which was indicated for the listing, except that at the place of the plug socket of the lower brushes it passes through the pin relay 127 to go to socket 128 (see fig. 14a) and from there to source 8 via the following elements: wire 343, contact 101a of the element of the order of magnitude corresponding to socket 128 switched on, contact 99c, electro-
 EMI18.1
 magnet 95, wire 143 wn; r t on7 ...,., 1 ': -' u '\ h-

 <Desc / Clms Page number 19>

 card lever), thread 144 and thread 123. '
The effect of closing this circuit is to energize the electromagnet 95 and move its contact from the position shown in FIG.



  14a. * Contact 95 @ controls the holding circuit for the accumulator mechanism to hold the accumulator element in place. This circuit is established immediately after closing the main line switch 122 (see fig. 14) and follows the following path: source S. line wire 121, wire 145 (see fig. 14a), contact 95d, electro - magnet 77, line wire 120 and source S.



  As was said above, the excitation of the electromagnets 77 establishes the horizontal magnetic field and the maintenance of this field by the circuit which has just been indicated keeps the accumulator element in place or totalizer.



  However, when the electromagnet 95 is excited under the control of a perforation carried by a column of the perforated card, this holding circuit is cut off and the electromagnets 76 and 77 are connected to a pair of distributors or transmitters. of pulses D-1 and D-2 which are capable of emitting a series of alternating pulses some or all of which can be sent to the electromagnets 76 and 77 by the control of the electromagnet 95. The Pulse distributor D-1 first establishes the following circuit: line wire 121 (see fig. 14), distributor D-1, wire 146 (see fig. 14), contact 9, electromagnet 76 and 120 line wire.

   This impulse. as was said above, advances the accumulator element by one twentieth of a turn. Immediately then the pulse distributor D-2 establishes the following circuit: line wire 121, distributor D-2, wire 147, contact 95c, electromagnet 77 and line wire 120. The circuit which passes through the electromagnets 76 is interrupted at the same time so that the accumulator element now advances one

 <Desc / Clms Page number 20>

 another twentieth of a turn, whereby a full step of movement is recorded.

   In this way, the distributors D-1 and D-2 alternate to control the pairs of electromagnets 76 and 77 in order to carry out the step-by-step advance of the accumulator element *
On the adjustment over time diagram (see fig. 2), we see the adjustment over time of the pulses emitted by distributors D-1 and D-2 and it is clear that if the electromagnet 95 is energized under the control of a perforation in the position of the indicator point corresponding to the number "9" of the perforated card, the distributors will each emit nine pulses to advance the accumulator element by nine notches,

     while if the electromagnet 95 is excited by the command of a perforation in the position of the indicator point corresponding to the number "5" only five pulses from each of the distributors will take place after the introduction of the number "9" in the cycle of the machine to cause the displacement of the accumulator element *
Due to the fact that the initial excitation of the circuit of the electromagnet 95 is momentary, it is necessary to provide a holding circuit for this electromagnet.

   The CR-14 contacts. and CR-15 (see fig. 14) are closed during the exploration part of the machine cycle and are used to establish the following circuit: line wire 120 wire 148, contacts CR-14 and CR-15 , wire 149 (see fig. 14a), contact 99 @, contact 95a, electromagnet 95, wire 143 (see fig. 14), contact 138g wire 144, wire 123 and line wire 121.



  Since the electromagnet 95 has been energized at a different time during the cycle, it is kept energized for the remainder of the part of the cycle where the input occurs, in order to allow the transmission of the necessary input pulses.

 <Desc / Clms Page number 21>

 
 EMI21.1
 accumulator, the electromagnet 95 ceases to be energized and the initial holding circuit by the contact 95d is closed again to maintain the accumulator element in its displaced position until the electromagnet 95 is energized again during a next cycle.

   In this way, the indications taken from punched cards successively brought in front of the LR lower brushes can be printed or added together and the listing and totalization continue until the card reserve is exhausted or until the automatic control mechanism, a mechanism which will be explained in the following, causes the operation of the machine to be interrupted in order to allow the operations of printing totals.



   TRANSFERS
For different orders of magnitude in which inputs have been made, inputs which together amount to ten or more, the contact brushes 91 (fig. 14a) pass or stop on those of the segments S3 of cylinder 88 which correspond to zero, at the end of the part of the cycle which corresponds to the entry.

   Assuming that the brushes 91 of the second order of size from the left in FIG. 14a pass through the position corresponding to the number "9" during the part of the cycle which corresponds to the input, it is established, at the moment of the passage, the following circuit: line wire 121 (fig. 14), distributor of pulses D-4, wire 150 (fig. 14a), relay contact 103a normally closed, wire 151, segment 93 corresponding to number "9", brushes 91, second segment 93 corresponding to number "9", coil of relay 98 to double winding, wire 152 and line wire 120.

   This circuit is established during the part of the cycle corresponding to the input each time the accumulator element is

 <Desc / Clms Page number 22>

 on the position corresponding to the figure "9" or reached this position, The excitation of the coil 98 attracts and closes its contacts 98a, 98b and 98c, the contact 98a establishes a holding circuit for the electromagnet, circuit which is the following:

    line wire 121 (see fig. 14), wire 145 (see fig. 14a), wire 153, right winding of 1 electromagnet 98, contact 98a, wire 154, wire 155, wire 156 (see fig. 14) , contact at. continuous motion cam CR-18, wire 148 and line wire 120. The CR-18 contact remains closed throughout the part of the cycle corresponding to the input until the transfer operations have been completed, said contacts s 'then opening to interrupt the holding circuit.



   If the brush 91 establishes contact between the pads 92 corresponding to zero, after having passed the segments 93 corresponding to the digits "9" and if it has established the circuits which have just been indicated, other circuits are established. will establish from line wire 121 (see fig. 14) and comprising the following elements: pulse distributor D-5, wire 356, relay contact 98b (formed at this time), pads 92 corresponding to zero, brushes 91 , left winding of electromagnet 97, wire 152 and line wire 120.

   The electromagnet closes its contacts 1A and 97b and opens contacts 97c and 97d Contact 97a establishes a holding circuit for the electromagnet, this circuit comprising the following elements: line wire 121 (see fig. 14), wire 145 (see fig. 14a), wire 153, right winding of solenoid 97, contact 97a, wires 154, 155 and 156, cam contact CR-18, wire 148 and wire line 120. It clearly follows from the foregoing that, whenever the accumulator element is in the position corresponding to the number "9", the electromagnet
 EMI22.1
 QQma.4- .....-. T.lo..C "1 -¯t., 04 *., ...,. -

 <Desc / Clms Page number 23>

 the accumulator element passes through the zero position.

     the electromagnet 97 is also energized, the holding circuit being established for said electromagnet.



   It will be assumed that the accumulator element of the second order of magnitude from the left in FIG. 14a has passed successively through the positions corresponding to the number "9" and to zero during the part of the cycle corresponding to the entry, so that the two corresponding electromagnets 97 and 98 are energized, during the part of the cycle which refers to the transfer, the CR-19 cam contacts close to establish the following holding circuit:

   line wire 121 (see fig. 14), wire 148, cam contacts CR-19, wire 157 (see fig. 14a), transfer solenoid 101, wire 152 and line wire 120, The excitation of the The electromagnet 101 causes the opening of its contact 101a and the closing of its contact 101b.



   After closing the CR-19 contact, closing the OR-16 contact establishes the following transfer circuits: line wire 120 (see fig. 14), wire 148, CR-16 contacts, wire 158 (see fig. 14). 14a), second order 97b contacts 4 from left, lead wire 159 for transfer which can be a plug connection if desired; contacts 101b, contacts 99c, electromagnet 95 of the order of magnitude which is on the left; wire 143 (see fig. 14) contact 138g of the card lever relay, wires 144 and 123 and line wire 121.



   Sum previously, the excitation of the electromagnet 95 moves its contact so as to connect the electromagnets 76 and 77 to the alternating action distributors D1 and D2 and each emits a single pulse to the electromagnets 76 and 77 to make advance the accumulator element one step. It is obvious that the parallel transfer circuits are formed for all the orders of magnitude of which the accumulator elements

 <Desc / Clms Page number 24>

 pass through zero during the part of the cycle corre- sponding to the input and that additional units will therefore be added to the immediately higher orders of magnitude.



   Measures have been taken so that, if the order of magnitude which receives the transferred quantity is in the position corresponding to the number "9", during the transfer operation, additional circuits are automatically established to add also a unit of the order of magnitude immediately higher. The operation of these circuits can be illustrated if it is assumed that a transfer is to take place of the third order of magnitude from the left of Figure 14a in the second order of magnitude and the second order of magnitude is found. a number "9": in this case, its electromagnet 98 is excited as has been said above.

   The transfer circuit which has just been indicated and which passes through the connection 159 between the second and the third order, then passes through the contact 10112. of the second order of magnitude to excite the electromagnet 95 as previously.



   However, a branch is established from contact 10b and passes through the following elements: wire 160, contact 98c of the tenth order of magnitude, contact 97c (now closed) connection 159 between the second and the first order of magnitude, contact 101b of the first order of magnitude, contact 99c electromagnet 95 of the first order of magnitude, wire 143 and line wire 121 as before.



   SUBSTRACTION
Usage sum in tabulating machines, punched cards, the details of which must be
 EMI24.1
 AL¯¯. J "'. 1 a -

 <Desc / Clms Page number 25>

 accumulators are identified by a special perforation made generally in the indicating position "X" of a chosen column of said card. This perforation is analyzed by the upper brushes and a circuit which is established through said perforation enables the machine to operate a subtraction.

   A plug connection 161 (see fig. 14) is established between the brush plug socket UB of the column in which the perforation "X" is located and a special plug socket 162, so that when the perforation "X "is explored by the upper broom, the following circuit is established to. from the common roller of the upper broom: perforation, connection 161, socket 162, a pair of CR-10 cam contacts which close while exploring the perforation "X" of the card, the electromagnet 163, the wire 124 and line wire 120. The electromagnet 163 closes its contact 163a and establishes the circuit passing through the electromagnet 164 which is connected between the line wires 121 and 120 as shown. .

   The electromagnet 164 in turn closes its contact 164a in order to establish for the electromagnet 164 the following holding circuit: line wire 120, wire 124, contact CE-11, contact 164a, electromagnet 164 , wire 123, line wire 121. Contact CE-11 remains closed until the end of the cycle, which keeps the electromagnet 164 energized in the same period.



   After the holding circuit has been established, the CR-12 contact closes to establish the following branch circuit: contact 164a, contact CR-12, electromagnet 165, wire 123, line wire 120, Elect @@ - magnet 165 closes its contacts 165a, 165h and 165c it Contact 165a closes to establish the holding circuit, following for the electromagnet 165: line wire 120, wire 124, contact CR-13, contact 165, electro magnet 165 and line wire 121. Contact CR-13 remains closed for

 <Desc / Clms Page number 26>

 
 EMI26.1
 the whole attractive part of the cycle that is devoted to entry and transfer.

   This next cycle is that during which the same card passes in front of the lower brushes, the indications of said card being introduced by subtraction into the accumulator device.



   Closing contact 165c establishes the following circuit: line wire 121, wire 123, wire 166, contact 165c, wire 167 (see fig. 14a), electro-shock magnet 102, wire 156, contact ce-18, wire 148 and wire line 120. This circuit is closed at the beginning of the cycle during which the card passes in front of the lower brushes and this circuit remains closed throughout the duration of the cycle parts which correspond to the input and the transfer. The energization of the electromagnet 1 ± closes its contacts 102a and 102b. It opens its contact 102c in order to establish cooked airs which will be indicated now.

   Contact 165D (see fig. 14) establishes the following circuit: line wire 121, wire 123, wire 166, contact 165b, wire 168, contact CR-20, wire 169, electromagnet 99, wire 152 and line wire 120.



  The CR-20 contact remains closed during the entire part of the cycle corresponding to the input and the electromagnet 99 therefore remains energized during this time; it maintains its contacts 99a, 99} 1. and 99d closed and keeps its contacts 99c and 99e open *
Contact 165b (see fig. 14) further establishes the following circuit: line wire 120, wire 123, wire 166, contact 165b, wire 168, contact CR-21 which is set so that it closes exactly before point corresponding to the number "9" in the machine cycle, wire 170, electromagnet 100, wire 152, line wire 120;

   this momentary excitation of the electromagnet 100 closes its contact 100a and the following circuit is established: line wire 120, wire 148, contact CR-17 (which closes momentarily.

 <Desc / Clms Page number 27>

 contact 100a, contact 99b (closed at this time), electromagnet 95; wire 143 and line wire 121 as before.



  The excitation of the electromagnet 95 displaces *, as before. its contacts so that the pulse distributors D1 and% emit alternating pulses to the electromagnets 76 and 77 which operate the accumulator.



   In this way, accumulator elements of all orders of magnitude advance concurrently and continue to advance step by step until the perforation of the punch card is explored by the lower brushes.



   At this moment, a circuit is established by the element of the corresponding order of magnitude, a circuit which prevents a new advance of the accumulator element.



  The end result is that said element has advanced by an amount corresponding to the complement to "9" of the perforation, which has the effect of subtracting the amount perforated in the card from the amount which is already recorded in the ac- cumulator. The holding circuit of the electromagnet 95 during subtraction operations is followed by line wire 121 (see fig. 14), wire 123, wire 144.

   contact 138g, wire 143 (see fig. 14a), electromagnet 95, contact 95a, contact 99d (now closed), contact 102b (now closed), contact 96b, wire 173, wire 174, wire 149, contacts CR-14 and CR-15, wire 148 and line wire 120, It is the interruption of this circuit which stops the step-by-step advance movement of the accumulator element.



   We can better explain the operation by referring to a concrete example. If it is assumed that the analyzed perforation corresponds to the figure "6, the accumulation or totalization operation is interrupted in a corresponding way after three notches of the movement have been carried out under the control of the distributors Dl and D2

 <Desc / Clms Page number 28>

 and this occurs at the point in the cycle of operations which corresponds to the number "6". The circuit passing through the lower brushes consists of the following elements: line wire 120 as for the addition, brushes, plug connection 127, socket 128 (fig. 14a), wire 143, contact 102a (now closed), electro - magnet 96, wire 172, wire 153. wire: 145 (see fig. 14) and line wire 121.

   The excitation of the electromagnet 96 opens the contact 96b to interrupt the holding circuit of the electromagnet 95 and any new advance movement of the accumulator of the corresponding order is prevented * The contact 96a closes for keep the holding circuit interrupted, this interruption being effected by the following holding circuit: line wire 121 (see fig. 14a), wire 145, wire 153, wire 172, electromagnet 96, cintact 96, wire 156 , contact CR-18, wire 148 and line wire 120.



    @@ TEMPORARY ITE
The electromagnet 102, when energized, also closes an additional contact 102d (see fig. 14a) which controls the entry of the temporary unit into one of the orders of magnitude of the accumulator to complete the process. quantity entered in that order and bring it to 10.

   During the part of the cycle which corresponds to the transfer, the following circuit is established: line wire 120 (see fig. 14), wire 148, contact CR-16, wire 158, contact 102d, connection 175 which can be inserted between the contact 102d and an element corresponding to any order oulu of the accumulator, contact 101b of the chosen order, contact 99c, electromagnet 95 and line wire 121 as before *
The excitation of the electromagnet 95, at this moment, causes the addition of one unit to the order
 EMI28.1
 pn-rr.crnn'nt10 "f" l + A 10l "Io - ## t - aia ¯: 1.11 - -....

 <Desc / Clms Page number 29>

 



     GROUP CCNTROLEDE MECHANISM
The machine is provided with a so-called group control mechanism which keeps the machine in operation as long as the indications of card placement, successively brought through the machine, remain unchanged. The group control method is well known in the tabulating machine industry and for this reason it suffices to describe it briefly. The plug connections 176 are made between the sockets of the upper brushes UB which analyze the columns of the card in which the indicator number of the classification or group is punched and the sockets 177. Plug connections 178 are made between the sockets. of the lower brushes LB and - the plug sockets 179.

   Thanks to this organization, when the cards pass successively through the upper and lower brushes, the circuits are established through the similar perforations of the various columns to cause the excitation of the windings of the electromagnet 180. This causes the closing of the contacts. 180a which, under the control of the cam contacts CR-7, establish a holding circuit for the electromagnet 180 by energizing the lower winding of said electromagnet.

   The second contact 180b of the electromagnet 180 is connected in series and as long as there is agreement between the cards being compared, all the contacts 180b chosen close during each cycle, After the part of each cycle which corresponds to input and analysis, the CE-8 cam contact momentarily closes to test the series circuit, which, if the boards match, will be established as follows: line wire 120, wire 124, electromagnet 181, wire 182, CE contact, .8, series contact 180b, branch connection

 <Desc / Clms Page number 30>

 tion 183 which removes unused columns from control and line 121.



   If, at the time. the CR-8 contact closes, one or more of the contacts 18012 .. are open, this circuit does not close and the contact 1814 of the solenoid 181 closes for this reason * Immediately after closing the
 EMI30.1
 contact CE-: contact P-1 closes and, if there is a match, establish the following circuit: line wire 120, wire l2 +, contact I.-1 contact ï38g ,, electromagnet 134, wire 123 and line wire 121. Contact 134a establishes, for the electromagnet 134, the following holding circuit *. thread
 EMI30.2
 line 121, wire 123, electromagnet 134, contact l34; & ,. contact CB-9 switch 183, wire 134. and line wire 120.



  The CR-9 contact remains closed throughout the next cycle and the electromagnet 134 remains energized for this reason for
 EMI30.3
 the same time, opens his contacts damn, and 13 <d. and closes its contacts 1 and I34a. Covering contact 13q causes the excitation of the electromagnet 135 to be suppressed.

   The electromagnet 135 then opens its contact 135k and the electromagnet 20 of the card feed clutch as well as the electromagnet 31 of the printing clutch are energized whereby the feed. cards stops. Closing contact 134c allows a new excitation.
 EMI30.4
 of the electromagnet 31 of the clutch cltimpression towards the end of the cycle under the control of the CR-2 contact so that, during the following cycle, the vacuum mechanism operates but without the card feed mechanism. 134e supplies current to the totals print transmitter so that the quantities on the accumulator can be read from said accumulator and printed during this cycle.,
 EMI30.5
 T1IPR1eSSIOJ DES TO} '. \ U1;

  .
 EMI30.6
 To ¯¯.¯¯1 'f¯¯ ī9¯t¯ o !! - o '

 <Desc / Clms Page number 31>

 
 EMI31.1
 
 EMI31.2
 different orders of magnitude (see fig.l4.,) occupy positions corresponding to the number presented by the corresponding accelerator elements and come into contact with the corresponding pads 89, When the contactor brushes 113 successively connect
 EMI31.3
 The pads 114 with the pad CODlD11U1ll :, the pulses are successively oJ1Voyées in the fUs 184 and it establishes different orders of magnitude at different times which depend on the way in which the brushes 87 are arranged.



   We can indicate, by way of example,
 EMI31.4
 the cixsu3.t line wire 120 (see fig. 14 ..). wire 124, contact 134-.1 ;; wire J. $ 5 * conunun pad 115, brushes 113, wires 184 successively switched on, one of the pads 89
 EMI31.5
 broom 8 ', wire 186, connection 129 # plug socket 131, contact I4 (now closed), pressure electromagnet 64, contact P-3 and line wire ma 121. Contact l42.b, is closed for the operations dt, 2-m pressure of the totals under the control of the electromagnet 142 which is excited during this time by the following circuit ': electro-
 EMI31.6
 magnet 14, wire 187. contact 134M4 contact M-9, wire 124 and line wire 120. In this way, the number that carries each of the accumulator elements corresponding to a determined order of magnitude is noted.

   It will be noted that the accumulator corresponding to the different orders of magnitude without the parts of the accumulator moving so that, after the printing of the total has taken place, the accumulator is in the same position as that in which it was at the start of printing operations for totals *,
RESET The reset takes place during the cycle following the printing of the total and is caused by

 <Desc / Clms Page number 32>

 the following way:

   towards the end of the printing cycle, after the CE-9 contact has opened to interrupt the excitation of the electromagnet 134 so that the contact 134b is closed, the closing of the P-1 contact closes the next circuit: line wire 120, wire 124, normally closed relay contact 190c, board feed clutch solenoid contact 20a (now closed), solenoid 132, contact 134b , wire 123, line wire 121. The electromagnet 132 operates the contact which corresponds to it, the contact 132c establishing a holding circuit for the electromagnet by the following circuit: line wire 121, wire 123, contact 134b, electromagnet 132, contact 132c, contact CR-5, wire 124 and line wire 120.

   The CR-5 contact maintains the circuit for the duration of the reset operations. The contact 132, by its closure establishes the following circuit: line wire 121, wire 123, contact 132e, wire 168, contact CR-21, wire 170 '(see fig. 14a), electromagnet 100 and line wire 120 .



   At the same time, the following parallel circuit is formed through contact CR-20: wire 168, (see fig.), Contact CR-20, wire 169 (see fig. 14a), electromagnet 99 and wire. line 120. As before, the simultaneous excitation of the electromagnets 100 and 99 causes the establishment of the following circuit by the electromagnet 95: line wire 120 ((see fig. 14), wire 148, contact CR-17, wire 171 (fig. 14a), contact 100a, contact 99b, @ electromagnet 95, wire 143 (see fig. 14), contact 132d, wire 123 and line wire 121.

   The excitation of the electromagnet 95 connects, as has been said above, the pulse distributors Dl- and D-2 to the input devices of the accumulator elements and the aforementioned distributors emit pulses alternated with said elements. The

 <Desc / Clms Page number 33>

 which is necessary to bring the elements to the zero position; at this time, the electromagnet 95 ceases to be excited. This takes place as follows: the individual holding circuits for the electromagnets 95 are as follows: line wire 121 (see fig. 14), wire 123, contact 132d, wire 143 (see fig. 14a), electro - magnet 95, contact 95a, contact 99d, contact 102c, contact 97d, contact which is closed if the accumulator element is not in the zero position, wire 174, wire 149 (see fig.



  14), contacts OR-14 and CR-15 and line wire 120. It is clear that if the accumulator element is at zero, contact 97d opens and a holding circuit is not established. for the electromagnet 95, which / immediately ceases to be excited so that there is no transmission of impulse from the distributors D-1 and D-2 to this element d special accumulator, which remains in the zero position. The previous closure of contact 132f (see fig.l4) closes the circuit following line wire 121, wire 123, contact 132f, wire 191 (see fig. 14a) electromagnet 103, wire 155, wire 156, contact CR-18 , wire 108 and line wire 120.



   The electromagnet 103 has opened its contact 103a and closed its contact 103b as well as the contact 103c which controls the holding circuit for the electromagnet 99. When the various circuits have been closed, as has been said. above, the various accumulator elements receive pulses from the distributors D-1 and D-2 and the holding circuits of the electromagnets 95 are controlled by the holding contacts 97d of the electromagnets 97.

   When the accumulator element of each order of magnitude reaches the zero position so that its brushes 91 connect the plds 92, the following circuit is immediately established: line wire 121 (fig. 14), distributor of pulses D-6, wire 192 (fig. 14a), contact

 <Desc / Clms Page number 34>

 103b, pads 92, brushes 91, left winding of the electromagnet 97, wire 152 and line wire 120. The excitation of the electromagnet 97 immediately causes the opening of its contact 97d, l interruption of the energization of the electromagnet 95 and the interruption of the transmission of further impulses to the element which, for this reason, remains at the zero position. The holding circuit of the electromagnet 97 is established as before.

   In this way the cooperation of the brushes 91 with the pads 92 serves both to prepare the transfer circuits during the operations of entering indications of the machine and to the resetting of the elements during the resetting operations.



   The operations of feeding the cards and entering the indications of the machine resume automatically, after the completion of the resetting operations, as will be explained.



   The CR-6 cam contact momentarily closes towards the end of the reset cycle and closes the circuit following line wire 120, wire 124, CR-6 contact 132b contact (now closed) t solenoid 135, wire 133, contact 134b, wire 123 and line wire 121. The electromagnet 135 closes the 13% contact which energizes the circuit of the electromagnet of the card fine clutch and one cycle of operation of the card. card supply mechanism occurs and continues as long as the group designation numbers of successive cards remain the same.



   CONTINUOUS PRINTING OF TOTALS
When you want the machine to perform printing operations for totals without resetting
 EMI34.1
 2- ----- 1 x - -. .... - - -. -

 <Desc / Clms Page number 35>

 the group control mechanism detects a discrepancy between successively supplied cards, the printing of the totals takes place as stated above, but the reset cycle is suppressed. The feeding and analysis of the cards recommences immediately after the total has been printed out under the control of the accumulators, and the indications taken from successive groups of cards are added to those already on the accumulators. The circuits involved to bring about this state will be described now.

   If there is a mismatch of the characteristic numbers of the groups of the successive punched cards, the electromagnet 181 ceases to be excited, as was said above, and the circuit through the electromagnet 134 is established from the same point. same way. Closing contact 134a establishes the following circuit: line wire 121, wire 123, electromagnet 190, switch 183, contact CR-9, contact 134a, contacts 138a 181a and F-1, wire 124 and line wire 120.



   The hold circuit for solenoid 134 is as follows: line wire 121, wire 123, electromagnet 134, contacts 134a, and CR-9, switch 183, contact 190a, contact P-4, wire 124 and. line wire 120. The electromagnet 190 is held by the following parallel circuit: line wire 121, wire 123, electromagnet 190, contact 190a, contact P-4, wire 124 and line wire 120.



   As before, the excitation of the electromagnet 134 interrupts any other card feeding operation and causes the start of a cycle of operations of the printing mechanism during which the total carried by the accumulator is printed. as it was said above: Towards the end of the printing cycle, the cam contact P-1 closes and it is established

 <Desc / Clms Page number 36>

 the following circuit: line wire 120, wire 124, contact P-1, contact 190b (now closed), contact 138c (also closed), electromagnet 135, wire 133, contact
 EMI36.1
 134 ,, wire 123 and line wire 121. Contact 136h closed by interrupting the excitation of the electro-
 EMI36.2
 magnet 134 when the CH-9 contact has stopped at an earlier point in the cycle.

   In this way, the solenoid 135 is energized towards the end of the totals printing cycle and therefore closes its contact 135b which again energizes the solenoid 20 of the clutch. card feed so that card feed operations can take place in the next cycle.
 EMI36.3
 



  FONOT ION1ijJ!: HNT DURING THE PASSAGE OF THE DEHMEEE CAR'l'B
Measures have been taken for the automatic reset of the accumulators, after the last card has been analyzed, when the machine is set for continuous printing of totals. This occurs by the energization of the electromagnet 132 during the last cycle of printing of totals, the contact P-1 establishing the following circuit ;: line wire 120, wire 124,
 EMI36.4
 P-I contact, I9t contact, 13QL contact (now closed due to the fact that there is no card at the lower brush station), electromagnet 132 contact 134b wire 123 and line wire 121.



   As before, the electromagnet 132 establishes its holding circuit through contacts 132c and CR-5 and, through its various other contacts, puts the circuits in condition for reset operations. After the latter reset to zero, an additional cycle of operations of the card supply mechanism is set in motion as was said above and during this time
 EMI36.5
 In;: J.1 "" n; "'' '' --4- ¯ ... a..at ¯ ----" 1-

 <Desc / Clms Page number 37>

 RECAPITULATION
A brief summary will now be given of the entire operation of the machine to indicate the succession of the various operations.

   Lowering the start key first of all causes the machine to perform a cycle of reset operations, which ensures that the accumulators are at zero and are ready to record entries.



  This reset cycle is caused by the closing of the STb contact of the start button which establishes the following circuit: line wire 120, wire 124, contact STb, contact CR-4, contact 138e (closed because it there are no cards at either brush station), electromagnet 132, wire 133, contact 134b, wire 123, and line wire 121. Electromagnet 132 causes a cycle of reset operations, in the manner explained above.

   Simultaneous closing of contact STa and contact STb causes a card feed stopper cycle, in the manner already described, so that a card is fed from hopper 32 to the upper brushes while it is taking place. resetting the accumulators, After this operation, the electromagnet 135 is energized again when the contact OR-6 closes and its contact in turn causes the excitation of the electromagnet 20 of the 'card feed clutch. If the machine is ready for listing, with switch 139 closed, electromagnet 31 is also energized after the first card has reached the lower brush station.



   From this point, entries will be made in the accumulator elements corresponding to the various orders of magnitude and in the printing mechanism from the successive cards and the. group control mechanism keeps the machine running too

 <Desc / Clms Page number 38>

 as long as the numbers corresponding to the groups remain the same for the successive cards * The indications of cards whose perforations represent positive values are entered directly into the accumulators. Those which represent negative values are introduced into the accumulators in the form of their complement.



   When there is a change in the characteristic number of a group, the supply of the cards is interrupted and the operations of the printing cycle take place; during this time the quantity on the accumulator is printed. If the machine is set up for continuous printing of totals, the card feed purges resume and new entries are made in the accumulators.

   If the machine is not enabled to perform continuous printing of totals, a cycle of reset operations follows each of the printing cycles, the accumulators being reset during this time and the operations of resetting to zero. 'supply of cards being taken back after this reset cycle. After the reserve of cards has been exhausted, the machine automatically prints the total which is on the accumulators at that moment and automatically resets them to zero.



    VABIA @ TE
FIG. 15 shows a modified embodiment of the invention, in which a keyboard is provided for making entries into the accumulators and in which a printing mechanism similar to that of the embodiment The preferred embodiment of the invention is also provided for printing the indications and the totals. The accumulator mechanism of this second embodiment is entirely similar to that of the main embodiment. The organization of this
 EMI38.1
 fn1 "ll1" mnr71'fi ns a'F * aÎÎw .C ..... Î ¯¯¯..1 ---, t t¯-¯¯

 <Desc / Clms Page number 39>

 operation and, for simplicity, the characteristic elements for subtraction have been omitted.



   A keyboard is provided with several columns of keys 200, a drive bar 201, a key 202 for an intermediate total, a key 203 for the grand total and a lever 204 which is used to set the key. machine able to list the indications or not to list them. The keys 200 are capable of cooperating with the usual locking bars 205 on which a spring acts and which serve to keep the keys lowered in their lower position until the bars 205 are moved to the left under the control of a release electromagnet 206.

   The lower end of each of the keys 200 carries a contactor tape 207 isolated from the key and capable of establishing a connection between the conductor 208 corresponding to a determined order of magnitude and a conductor 209 corresponding to the position of the digits. so that when any key is lowered, for example key 200 of number 5, an electrical connection is established between bar 208 of the column to which the key that has been lowered belongs and bar 209 corresponding to number 5 The keys 202 and 203 are also provided with a locking bar 205a which is also controlled so as to release the keys by the electromagnet 206.

   The printing mechanism is controlled in the same way as in the preferred embodiment by a mechanism controlled by the main shaft 210 of the mechanism. printing, shaft on which is mounted a clutch control element 211, this element being integral with the toothed wheel 212 controlled by a toothed wheel 213 carried by the shaft 214, which, in turn, is controlled by the motor M. The excitation of the electromagnet 215 causes

 <Desc / Clms Page number 40>

 operate a single-turn clutch mechanism which is designated as a whole by 216, so as to couple the shaft 210 to the clutch control member 211 during one cycle of operation, during which time the type bars rise to print the quantity that has been "compounded" on the keypad.

   The shaft 214 carries a certain number of contactor devices with cam control, devices which will be designated in what follows either by the prefix CR or by the prefix M, these devices operate at all times.



   The mode of operation of this embodiment can be explained with greater clarity if one refers to the connection diagram of fig. 18. In this diagram, elements analogous to elements which perform the same functions in the main embodiment are identified, for convenience, by numbers of like references. Closing the switch 122 starts the motor @ whereby the shaft 214 begins to rotate continuously.

   As in the main embodiment, a circulation is also immediately established by the accumulator electromagnets 77 and by the contacts 95d to hold the accumulator elements in place; the contacts 95b and 95c serve to connect the alternating acting distributors D-7 and B-8 to the electromagnets 76 and 77 respectively.



   After a quantity has been entered on the keyboard by lowering the corresponding keys, the driving bar 201 is lowered so as to close the contact 2117 and the following circuit is established: source S, wire 218, contact 217, electromagnet 250, wire 220 and source S. Closing contact 2501 then maintains the circuit by electromagnet 250 gr @@ ce on command of cam contact CR-22 so that when the contact

 <Desc / Clms Page number 41>

 
 EMI41.1
    wire 218, contacts CR-22, 250 & and CR-23, electromagnet 219, wire 220 and source S. The excitation of the electromagnet
219 closes from contacts 219a, 219b and 219.



   Assuming that the machine is set for totalization only, closing contact 219c establishes the following circuit: source S, wire
218, contact 219c, wire 221 common conductive strip 222, brush 223 controlled from the shaft 214 and, successively the pads 224 which are electrically connected to the number bar 209.



   If we suppose that the key 200 corresponding to the number "8" of the order of magnitude which is on the extreme left has been lowered, the following circuit is established: pin 224 corresponding to the number 8, bar 209 corresponding to the number 8, connection 207, the bar 208 which is on the far left, wire 225, contact 101a, contact 99b, electromagnet 95 and the other terminal of the source S. As in the embodiment The preferred way of energizing the electromagnet 95 at different times causes transmitters D-7 and D-8 to advance the accumulator cell by an amount proportional to the value of the digit selected for the control.

   Similar circuits pass through the elements of the other orders of magnitude of the accumulators during the cycle and towards the end of a cycle; transfer operations take place in the same way as in the preferred embodiment.



   When quantities need to be entered to be subtracted, the 10's complement of the numbers can be manually dialed on the keypad and an ordinary addition operation performed.



   If the machine is to list the entered quantities as they are appended the list control lever 204 is moved to the desired position to close contact 226 which closes a

 <Desc / Clms Page number 42>

 circuit after relay 219 has been energized as mentioned above; this circuit is as follows: source S, wire 218, electromagnet 227, wire 228, contact 226, contact 229, contact 230 wire 231, contact 219b, wire 220 and source S. The electromagnet 227 closes several contacts 227a to connect the different bars 208 which correspond to the different orders of magnitude to the printing electromagnets 64 which correspond to these orders of magnitude.



  In addition, contact 227b which closes at the same time as contacts 227a closes the following circuit for the print clutch solenoid 215: Source S, wire 220, contact 219b, contact 227b, solenoid clutch 215, wire 218 and source S.



   At the same time as the addition circuit closes, a parallel circuit starts from bar 208 and passes through contact 227a, through the corresponding printing electromagnet 64, through wire 220 to return to the source. S and the entered quantity is printed. During the last part of the cycle the CR-25 cam contact momentarily closes to establish the following circuit: source S, wire 218, contact CR-24, contact 219a (which establishes the hold circuit for relay 219). CR-25 contact, key release solenoid 206, wire 220 and source S, whereby the down key is released.



  In this way the quantities can be introduced successively into the accumulator and printed at the same time if desired.



   PRINTING OF PARTIAL TOTALS
If at any time it is desired to obtain a partial total, that is to say to print the quantity which is on the accumulators without resetting these accumulators to zero, the corresponding key 202 is lowered.
 EMI42.1
 dant aux fofanr Tiei-k4alc lmr7¯ 4.¯ -.- 1 ..- 2-L -. L .... '1.

 <Desc / Clms Page number 43>

 
 EMI43.1
 opens to break the circuit through the electromagnet 227 and the contacts 232, 233 and 234 close.



  The closing of contact 233, after contact 217 of the driving bar has closed and relay 219 is energized and maintained, establishes the following circuit: source S, wire 220, contact 219b, wire 231, contact 233, electro- magnet 215, wire 218 and source,. The printing mechanism begins to operate and the next circuit closes; source S, wire 220, contact 219b, wire 231, contact 234, contact M-8, wire 235, electromagnet 100, wire 236 and source S. The electromagnet 100 closes its IODA contact.



  A parallel circuit is established from contact 234, this circuit comprising the following elements: contact M-7, wire 237, electromagnet 99, wire 236, source S, this circuit energizing electromagnet 99 and closing its contact 99a so that the latter, at the same time as the contact 100a closes a circuit passing through the electromagnet 95 and comprising the following elements: source S, electromagnet 95, contact 99a contact 100a, contact M -4 and source S.



   The circuit is closed at the beginning of the part of the cycle where the entry takes place and the transmitters D-7 and D-8 begin to emit pulses towards the electromagnets 76 and 77 to advance each of the elements by one revolution. complete during which circuits are established towards the electromagnets 64 at different times in order to express the quantities which are found in the elements corresponding to the different orders of magnitude.



   The closing of the contact 232 closes a circuit starting from the source S and passing through the wire 231, as was said above, through the contact 232, through the wire 240, through the electromagnet 241 and through the wire 236 ends at the source S. The electromagnet 241 closes the contact 241b and opens the contact 2 + la. When the

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 brushes 91, of different orders of magnitude, rotate and make this complete revolution, they establish contacts with the pads 92 corresponding to zero when the type elements, corresponding to the quantities carried by the accumulator element, arrive in the position d 'impression it is then established, for each order of magnitude, the following circuit:

   wire 220, electromagnet 64, wire 242, contact 241b, pads 92, brush 91, wire 243. contact 98b, previously closed when the brushes 91 have established the connection with the pads 93 in the manner which has been explained in connection with the preferred embodiment, wire 244, pulse distributor D-10, wire 218 and source S.



   After establishing this circuit, the accumulator element advances and completes the remainder of one revolution to occupy the same position it had at the beginning of the cycle. In other words, each of the elements corresponding to a certain order of magnitude is made to complete a complete revolution at different times during which the circuit which has just been indicated is closed in order to put the type-carrying bar in position in order to '' print the quantity that is on the element.



   PRINTING OF THE GENERAL TOTAL
If you want to reset the accumulators, push down key 203 corresponding to the general total in order to open contact 229 and close contacts 245, 246, 247 and 248. Contact 247 is connected in parallel with contact 234 of the key corresponding to the subtotals and closes circuits in a similar way by means of the contacts M-7 and M-8 so as to energize the electromagnets 99 and 100 in order to start a cycle

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 with an asterisk under the control of a printing solenoid 64a to indicate that the quantity printed is a grand total.

   Contact 246 is in parallel with contact 233 and serves to energize the electromagnet 215 of the print clutch in the same way. Contact 245 closes the following circuit: source S, wire 220, contact 219b, wire 231, contact 230, contact 245, wire 249, electromagnet 103, wire 218 and source S. Electromagnet 103 closes its contacts 103b and 103d which control the reset and print totals circuits respectively.



   When the electromagnet 95 is excited, the following circuit is established: source S, electromagnet 95, contact 95a, contact 99c, wire 2bl, contact 97d, wire 252, contact M-1, contact M-2 , wire 318 and source S. When the accumulator element reaches the zero position, the following printing circuit is immediately established: source S, wire 218, distributor D-ll, contact 103b, wire 243, brush 91, pads 92, contact 241c, wire 253, contact 103d, wire 242, printing electromagnet 64, wire 220 and source S. The number that the element carries is therefore in the printing position as before .

   At the same time, the following branch circuit occurs: contact 241c, wire 254, the electromagnet 97, wire 255, and source S, The electromagnet 97 opens its contact 97d to interrupt the maintenance circuit of the The electromagnet 95 and this prevents any further advance of the accumulator element, the latter remaining in the zero position.



   Although in the foregoing the new fundamental features of the present invention have been described and shown in the accompanying drawing, without their application to two embodiments, it is understood that various deletions, substitutions and changes in shape and details

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 of the devices shown and in their operation, without departing from the spirit of the present invention.


    

Claims (1)

ABSTRACT The subject of the present invention is a tabulating machine controlled by punched cards and having the following characteristics taken separately or in combination: 1 - it comprises an accumulator provided with accumulator elements capable of rotating which cause electromagnets to act and it is also provided with devices controlled by the punched cards to alternately excite said electromagnets in order to cause the rotation of the corresponding accumulator cell; 2 - the place where the perforation is located in the perforated card determines the amplitude of the rotational movement of the accumulator element; 3 - transmitters launch pulses to excite the control electromagnets and the punched card determines the number of pulses which must act on the accumulator element; 4 - the rotating accumulator element consists of a rotor located in the magnetic fields of the electromagnets; 5 - one of the electromagnets is normally e @ quoted to prevent the rotor from rotating. BRIEF SUMMARY Tabulating machine controlled by punched cards and provided with accumulator elements capable of rotating and causing electromagnets to act as well as devices controlled by punched cards to alternately excite said electromagnets in order to cause the