CH262320A - Calculating machine for automatic multiplication. - Google Patents

Description

  

   <B> Machine </B> calculate <B> for automatic multiplication. </B> The present invention relates to a calculating machine for automatic multiplication comprising two actuating devices, one for the multiplier, the other for the multiplier, characterized in that between these two devices of actuation is arranged a control member for the actuating device of the multiplicand, this control member being capable of being placed, by the actuating device of the multiplier, in three positions representing an absence of rotation,

    a positive rotation and a negative rotation for the actuator of the multi plicand to actuate the latter to perform abbreviated automatic multiplication.



  The appended drawing represents, by way of example, an embodiment of the machine forming the subject of the invention: FIG. 1 is a cross section thereof. Fig. 2 shows the machine from under, some parts (in particular the motor and the driving or transmission elements) being broken or removed; we can consider fig. 2 as a horizontal section on line II-II of FIG. 1.



  Fig. 3 is another view from below of the machine, in the direction of arrows III-III of FIG. 1.



  Figs. 3A and 3B show details. Fig. 4 shows a detail seen from below, some parts broken up to show the lower parts. We can consider fig. 4 as part of FIG. 3, some items by being broken and removed.



  Fig. 5 shows, seen from below the machine, a detail of the drive rotor and neighboring elements.



  Fig. 5A is an end view of the drive mechanism seen from the left of FIG. 5. FIG. 6 is a detail of a drive rotor disc viewed from the left (ie in the opposite direction to that of Fig. 1).



  Fig. 7 shows a detail taken from FIG. 4, namely part of the guide of the tine to the reader carriage, seen from below.



  Figs. 8A and 8B are end views in the direction of arrows VIII A-VIII A and VIII B-VIII B, respectively, of FIG. 7.



  Fig. 9 is a detail of a notch shift device for the reader, seen from the rear side of the machine; one can consider the fig. 9 as a detail seen along the direction of the arrows IX-IX of FIG. 5.



  Fig. 10 is a detail of FIG. 5, and it represents part of the reader mechanism. Fig. 11 shows the detail of FIG. 10 seen in the direction of arrows XI-XI of FIG. 10.



  Fig. 12 is a detail view of a wedge for erasing the drive rotor.



  Fig. 13 shows this erasing wedge seen along arrows XIII-XIII of FIG. 12. FIG. 14 is an end view in the direction of arrows XIV-XIV of FIG. 12.



  Fig. 15 is a plan view of the lower part of the machine, the upper parts being broken off and removed in order to show more clearly the notch shift mechanism; the figure can be considered as a section along the line XV-XV of fig. 1, some parts by being broken and removed.



  Fig. 16 is a detail view of the right side of the machine seen in the direction of the arrows XVI XVI of FIG. 2.



  Fig. 17 shows the machine seen from its right side, that is to say a view in the direction of arrows XVII-XVII of FIG. 3.



  Fig. 18 is a detail of FIG. 17, after some parts have been broken up and removed for clarity; fig. 18 shows the position of the organs before the start of the read operation.



  Fig. 19 is a view similar to fig.18, and it shows the positions of the organs after the end. of the read operation.



  Fig. 20 is a view of a detail of the reader mechanism, taken from FIG. 17.



  Fig. 21 is a view along arrows XXI-XXI of FIG. 20.



  Fig. 22 is a detail view along arrows XXII-XXII of FIG. 18, the upper half of fig. 22 showing cross-sectional details.



  Fig. 23 is a detail view of a coupling between the shaft of the actuator of the quotient counter and the actuating notch of the reader; this figure is a detail seen along arrows XXIII-- XXIII of fig, 17.



  Fig. 24 is a detail view along the arrows XXIV-XXIV of FIG. 3.



  Fig. 25 is a side view of the machine, on the left side, that is to say along the arrows XXV-XXV of FIG. 3.



  Fig. 26 is an axial section through the reader rotor and indicates the method of assembly.



  Figs. 27g and 27B are details taken from FIG. 17 and indicate the different positions of a correction arm or lever.



  Figs. 28A, 28B and 28C are also details taken from FIG. 17 and indicate three different positions for slides determining the direction in which the ordinary or main actuator operates during automatic multiplication.



  Finally, fig. 29 is a detail of FIG. 4. It should be expressly mentioned here that several kinds of reference signs were chosen for the different figures of the drawing and that these series of signs were chosen only in order to give more clarity to each figure considered. individually.



  Still for the sake of clarity and on certain figures only, only those organs which are closest to the observer (those closest to the plane of the drawing) have been shown, whereas organs farther away have been omitted; for the same reason, we have completely or partially cut organs in some figures.



  Where not expressly indicated otherwise, the terms right, left, forward, backward, upward and downward are used throughout this description to indicate these. directions as they exist for the operator in front of the machine keypad. <I> Principle </I> general <I> of </I> lake <I> machine. </I>



  The calculating machine represented com takes a single keyboard to prepare or set the two factors of the multiplication. In the first place, the multiplier is set by means of this keyboard. The placed entity is then recorded simultaneously by a main actuation device and by a special multiplier or reader mechanism (multiplier actuation device or reader) connected in parallel with said ordinary actuator. .E1 this effect, the organs carrying out the.

   data and actuated by the keys set up the main actuator as well as the multiplier mechanism. During. as the multiplier is being prepared, the reader or multiplier mechanism is moved step by step at the same time as the ordinary actuator.

   During its rotation, the latter actuates an accumulator (recorder of results) in the usual way, while the reader or multiplier mechanism serves to automatically control the number and direction of the rotations to be performed by the acceleration device. main ting for each individual denomination of said accumulator.



  After the multiplier has been placed simultaneously in the main actuator and in the reader mechanism, a special actuation key, marked X for example, is manually lowered so as to clear the main device from. operation, while, on the other hand, the placed entity (the multiplier) remains placed in the reader mechanism which, as a result of the manual lowering of the special key X mentioned at the moment, is released preparation units actuated by said keyboard and also, if possible,

      organs determining the movement of the notches (here the keyboard is of the ten-key type). Then, the multi-pHcand is placed in the main operating device by means of the same keypad (and this has no influence on the reader mechanism which has been released from the preparation or delivery devices before this process of preparation, as we saw above).

         When a special actuation key is now lowered, bearing the sign - for example, the multiplication operation is carried out automatically because the main actuation device is rotated in the direction and a determined number of times. by the numerical value of the multiplier which has been placed in the reader mechanism in the corresponding denomination.



  After sensitive reading has taken place in a certain denomination of the reader mechanism and the main actuating device has completed its revolutions in accordance with the corresponding denomination of the accumulator, the actuating device main and the reader itself of the reader mechanism are shifted by one notch to the next denomination in which the reading then takes place, and so on, >> rite. Automatic multiplication continues in this manner until the multiplicand has been multiplied by the entire multiplier placed in the reader mechanism.



  The same notch shift mechanism is used for both the main actuator and the drive mechanism, and this greatly simplifies the construction.

   However, it should be noted that during. the installation of the multiplier, the drive channel, consisting of a drive rotor, as well as the main actuator, consisting of a spindle-gear rotor, are shifted together in steps, while during the reading operation the multiplier makes the reader mechanism (the reader rotor) stationary, while the reader proper (reader finger) is shifted in steps together with the main actuating device. The latter is provided, as usual, with reading members or is coupled to them, so that the.

    pose, the multiplier and the multiplicand, respectively, can be read successively. The result can be read on the result recorder or accumulator after the end of the calculation operation, the tachometer simultaneously indicating the multiplier. The calculation operation having been completed, the two factors (multiplicand and multiplier) as well as the result can be read from. for verification purposes.



  For automatic multiplication, the reader mechanism should preferably be operated without changing (deleting) the multiplier placed there. After the end of the multiplication, the multiplier still remains in the reader mechanism. Now, if the erase key (key 0) is lowered, the main actuating device and the reader mechanism, as well as the reader unit proper, are released simultaneously. If, on the other hand, a Z key is depressed, only the main actuator and the reader are released, while the multiplier remains in the reader mechanism.

    A new multiplier can then be placed in the main actuator and, in a similar way (by manually lowering a - key), this multiplier can be multiplied by the remaining multiplier of the operation. previous calculation. Therefore, the machine can easily and quickly perform a series of multiplications by a given and constant factor.



  If we first simultaneously (in the same fitting operation) a factor (multiplier) both in the main actuator and in the drive mechanism, as has been said above, and that we lower - then directly the key - (instead of the X key), it is obvious that the set entity is immediately transformed to the square, given that the same number is set at the same time in the device d main drive as a multiplicand and in the drive mechanism as a multiplier.

   As a result, squaring operations can be performed very quickly and simply.



  The number of revolutions to be accomplished by the main actuator in each denomination is controlled by a toothed segment connected to the reader, said toothed segment determining the advance of a gear by sensitive reading of the number of notches according to the indication of the digit felt. When this is done, the gear is released from the segment and is brought into mesh with a tooth (counting tooth) which successively counts the gear returning to zero by one notch with each revolution of the main actuator.

   Said counting tooth is coupled to the shaft of the tachometer actuator. Thus, when the gearing has been reset to its zero position, the main actuating device is stopped in its full cycle position and is moved one notch at the same time as the sensor, after which the Sensitive reading is carried out in the same way in the following designation. When at last the whole multiplier has been felt in this way and the automatic operation of multiplication has thus been terminated, the machine is stopped.



  In order to make the calculation operations as fast as possible, the automatic multiplication operation is carried out following an abbreviated method, namely: with the minimum number of turns in each denomination. To this end, said drive mechanism gear is fitted with a cam whose profile has three different radii, to see one for the plus calculation, one for the minus calculation and another, neutral, for no calculation ( no turn).

   For the plus calculation, the main actuator rotates in the plus direction of rotation and for the minus calculation in the direction of minus rotations (i.e. in the opposite direction of rotation to that of the plus rotations) . In the no turn position, the main actuator does not perform any turn (it is only moved one step to the next denomination).



  Said cam actuates a slide which is thus placed in three different positions by the different radii of the cam, and the position of the slide determines the direction in which the main actuator must turn. The plus calculation position (position of the plus rotations) of the cam and slide corresponds to the numbers 1-5 in the corresponding denomination of the multiplier, while the minus calculation position or position of the minus rotations corresponds to the numbers 6- 9 in the corresponding denomination of the multiplier. The zero position (position no turns) of the cam slide corresponds to the number 0 in the corresponding denomination of the multiplier.

   In its position of rotation plus, the slide determines the rotation of the main actuator over 1 to 5 turns in the plus direction (positive direction, or direction of addition) in the ten in question. In its minus rotation position, the slide determines the rotation of the main actuator in the minus direction (negative or subtraction direction). The number of rotations in this direction minus constitutes the value complementary to the multiplier number (6-9) in the denomination in question.

    If this multiplying number is 6, for example, the laying main actuator performs 10 - 6 = 4 turns in the minus direction. After fewer rotations have been made in a denomination, the number felt in the next highest denomination should be automatically increased by one. This is done very simply by moving the toothed segment of the drive mechanism an additional notch (either at the beginning or at the end of the sensitive reading movement of the toothed segment).



  For this reason, the construction of the machine becomes very simple and its operation very safe, and the machine will operate very quickly also in automatic multiplication.



  In addition, the machine shown can perform division, addition and subtraction in the well known manner. The machine therefore lends itself to many uses.



  The machine shown is such that it can also perform the multiplication minus (multiplication in the direction of subtraction). To this end, the machine is provided with a selector device which reverses the direction of rotation of the main actuating device in accordance with the manual arrangement of said selector device by the operator.

   Normally, that is to say in the usual multiplication plus, the direction of rotation of the main actuator is determined, as stated above, by the numbers 1-5 counted in the positive direction of rotation. and the numbers 6-9 in the negative sense. But if the machine is prepared to perform less multiplication, the directions of rotation are reversed in different cases, so that the digits 1-5 of the multiplier are counted in the negative direction of rotation of the main device. actuation, while digits 6-9 are counted in the positive direction.

   However, the direction of rotation of the quotient tooth and of the rev counter actuating device, as well as that of the related counting tooth, are not reversed.



   <I> Keyboard-laying </I> numbers.



  In addition to the ten keys 0 to 9 for setting numbers or numeral entities (fig. 15), the machine shown includes the following actuators a) a key 10 for moving the device in steps to the right. main drive; the key has an arrow pointing to the right; b) a button 11 for moving the main actuator in steps to the left; the key has an arrow pointing to the left;

    c) a full tab key 12, the lowering of which determines the displacement of the main actuator to its extreme left position (for division); the key has an arrow directed to the left and presenting a circle at its rear end; <I> d) </I> an addition key 13 marked ADD; e) a subtraction and distribution key 14 marked with an =; this key is preferably called less multiple rotations; f) a multiplication key 15 bearing the sign +; this key is called, preferably, key plus multiple rotations; g) a multiplier key 16 marked with an X; h) a product key 17 marked with a - sign.

    



  In addition, the machine has a main control lever 18 (fig. 2) and a release lever 19 to put the machine in a condition to carry out multiplication and division, a release button 20 (fig. 17) for the main actuating device and for the reader or multiplier mechanism, and finally also a shift lever 1000 at least (fig. 17) to operate the shift towards the subtraction.

    However, the release key is used to release only the main actuating mechanism (but not a multiplier mechanism). Likewise, for the registers (the accumulator and the tachometer, respectively) there are release devices actuated by levers A and B- (fig. 2).



  The number keys 0 to 9 are articulated respectively on shafts 21- and 22 (fig. 1) which are fixed in the frame 23 of the machine. The keys of one row are articulated on shaft 21 and the keys of the other row on shaft 22. These keys are fitted, respectively, at their rear parts, with curved buttonholes 24 (in the keys). ches 0 to 4) and 25 (in keys 5 to 9), these cam buttonholes being established to cooperate, respectively, with studs 26 and 27 which are carried, respectively, by setting levers 28 and 29. These setting levers articulate on axes 30 fixed to the frame of the machine.

   The setting lever 28 comprises two arms, namely an arm 28a provided with a finger 31 intended to cooperate with the main actuating device 32 which may be called here the multiplicand mechanism, as well as an arm 28b provided a finger 33 having to cooperate with a reader or multiplier mechanism 34. In a similar manner, the setting lever 29 comprises two arms, namely an arm 29cs provided with a finger 35 for actuating the main device for ac - actuation 32 and an arm 29b provided with a finger 36 for actuating the multi plier mechanism 34.

   Springs 37, 38 are provided to maintain the levers 28, 29 for installation in their rest position indicated in FIG. 1.



       Mechanism <I> drive or </I> multiplier.



  The main actuator 32 and the registers (not shown) are constructed in a known manner.



  The reader mechanism consists of a reader disc 39 for each denomination (fig. 1, 5, 5A, 6 and 26). The drive discs 39 are mounted so as to rotate on a shaft 40, said discs being arranged on spacer tubes 41 and guided by cups 42. The tubes 41 and cups 12 are pushed onto a tube 43, at the left end of which is welded a terminal plate 44 which could be fixed in any other way. At the opposite end of the tube is provided an end plate 45, the fixing of which is ensured by a nut 46 screwed onto the tube.

    The cups 42 are guided by a bolt 47 (fig. 1 and 26) which is in turn guided by openings made in the end plates 44 and 45. Thus, the drive discs 39 and the members 41 and 47 constitute a rotor. reader 34 which is analogous, to a certain extent, to the barrel-wheel rotor of the actuator 32. The shaft 40 of this rotor 34 is fixed by its two ends in a support member 48 in <B> U </B> (fig. 7. and 5) which is screwed into the underside of the base plate of the machine. In the end plates 44, 45 of the drive rotor 34 are grooves 49 for the slide or locking bar 50 (fig. 1, 5, 5A, 10, 11).

   The grooves 49 guide the drive rotor when the latter slides in the direction of the shaft 40 on the bar 50. Said locking bar has, at its right end, a cavity 50c as well as a hook. Or projection 50d, while the left end qe this bar is provided with a 50th groove slightly in <B> S. </B> At the location of the groove 50e, the locking bar 50 enters a cavity 48a (fig. 5 and 8B) located in the right leg of the U-shaped member 48, and the projection 50d engages in a cavity 48b provided in the same leg.

    Thus, the right end of the locking bar is kept locked both in the radial direction and in the axial direction (relative to the shaft 40). However, the right end of this bar can swing radially down into the groove 48e formed in the left leg of the U-shaped member 48 (fig. 5 and 8A). The drive discs are provided with caps or grooves 39a, 39b (fig. 1 and <B> 6) </B> \ 0à respectively engage the fingers 36 and 33, respectively on the laying arms 29b and 28b, when the numbers are set in the drive rotor.

   Each drive disc has at its periphery nine notches 39c, not very deep, as well as a deep notch 39d. After a drive disc has been placed by one of the laying arms 28b or 29b and the drive rotor is then moved one notch to the left, one of the notches 39c, 39d is biased by the edge of locking 50a of the locking bar 50 (fig. 5, 10, 11), so that the player disc in place is locked in this position. The periphery of the drive disks 39 also comprises ten stepped shoulders 39e, 39f (fig. 6) which correspond to the numbers 0 to 9.

    It has been indicated in FIG. 6, by means of dashed lines bearing the digits 0 to 9, the way in which these shoulders correspond to numerical values. These shoulders cooperate with a reading finger. In addition, the drive discs include a curved buttonhole or mortise 39h for a release wedge 52 (fig. 1, 5 and 12 to 14), as well as a slot or buttonhole 39g for releasing the bolt 47. Consequently, this bolt guides only cups 42 without preventing rotation of drive discs 39.



  On a finger 51, screwed onto the left end of the release wedge 52, is formed a projection 51a which penetrates the curved plug 50e, at the left end of the locking bar 50. The finger 51 also carries a shock absorber 51b. When the release wedge is in its extreme right position (rest position) shown in fig. 5, the projection 51a hand holds the locking bar 50 in its blocking or locking position, so that said bar blocks all the drive disks 39 located to the left of the cavity 50b.

   During the disengaging or erasing operation, the wedge 52 is moved to the left and it then lifts the locking bar 50 which is thus released from the drive disks 39 to the left of the cavity 50b. The locking bar is actuated by the erasing wedge and not by any spring.



  In the lateral direction, the laying arms 28b and 29b are placed opposite the cavities 50b (fig. 5 and 10) of the locking bar 50. The drive disc 39 to be placed immediately after is thus housed in said cavity 50b. and is thus not blocked by the bar 50.

   However, this drive disc is blocked by a tooth 53a of a stopper or tilting hook 53 (fig. 1) which is articulated on a pin 54 fixed on the assembly 55 (fig. 1) which is in turn fixed on the organ 48 in <B> U. </B> A spring 56 urges the hook 53 so that the finger 57 of this hook rests on the edge of the fixed projection 55a (see also fig. 5A).

   When any of the arms 28b, 29b is tilted as a result of the lowering of a numeral key, a lug 58 on the setting arm hits the edge of the hook 53 and moves its tooth 53a out of the notch. <B> 39th </B> of the drive disc, while the lugs 33 and 36, simultaneously and respectively on the laying arm, penetrate. in the notches 39b, 39a of this disc. This removes the locking of the drive disc at the same time as the installation operation begins.



  In the axial direction, the drive rotor 34 is guided by an arm 59 (FIGS. 1 and 2) articulated on a pin 60 fixed on the base plate 23 of the machine. This arm carries a moving finger 61. in a mortise 62 (fig. 2, 5 and 26) located in a projection of the end plate 45 of the drive rotor. A spring 63 (fig. 2) tends to pull the drive rotor to the left, that is to say in the direction of arrow C. Such movement is however prevented by the fact that a slide 64, placed on the arm 59 serves as a guide for a coupling finger 65.

   Slide 64 is provided with studs 67 housed in oblong slots 68 in arm 59, so that it is movably mounted in said arm, while being held in a locked position by the slide. action of a tension spring 69. A finger 60 is also fixed on the arm 59.



  The coupling finger 65 is fixed on a rod 71 (fig. 1.5) in order to pull the ordinary actuating device 32. Thanks to a pin 72, this rod is articulated with a lever 73 and, thanks to another axis 74, with a lever 75. The two levers 73, 75 are articulated on fixed axes 76, 77, respectively, which are fixed to the base plate of the machine. By means of a finger 78, the lever 73 is articulated on the lever 79, which is fixed by means of a pin 80 to the carriage 81 of the main actuating device 32 (see also FIG. 1).

   The main actuating device is moved step by step in a known manner, both during the installation operation and. the lowering of the keys 10 and 11. Thus, when the main actuator 32 is moved by notch, the drive rotor 34 is also moved notch by notch in the same way by means of the coupling finger 65 The system of links between these two rotors is established according to dimensions allowing that the movements in steps of the rotors 32 and 34 are equal.



   <I> Drive rotor erasure. </I>



  The release or erase wedge 52 for the drive rotor 34 is guided in slots 82 (Figs. 5A, 8A and 8B) of the U-shaped support 48. In addition, it is guided in slots. or buttonholes provided in the cups 42 of the reader rotor and, finally, in slots made in the end walls 44, 45 of said reader rotor. As mentioned above, on the left narrow end of said wedge is fixed a finger 51 by means of screws and, thanks to this finger, the wedge actuates the locking bar 50 (FIG. 5).

   At the right end of the wedge there is a slot 52a in which one end of the lever 83 engages (fig. 3, 4, 5). This lever is mounted articulated on a screw 84 fixed in the base plate and it carries a finger 85 penetrating into a curved buttonhole 86 of an actuating slide 8 7 of the erasing wedge. This actuating slide is movably mounted and articulated on axes 88 of the base plate of the machine (see also fig. 29).

    When said slide 87 is moved in the direction of arrow D (FIG. 4), the actuating slide obviously causes the lever 83 to tilt, by means of the finger 85, in a clockwise direction. shows, that is to say in the direction of arrow E in fig. 4 and 5. Normally, the release wedge is in its extreme right position (rest position) shown in fig. 5. Therefore, the drive disks will be released or erased when, as just described, the release wedge is moved by lever 83 to the left, ie in the direction of arrow E.

   In order to keep the slide 87 in its rest position, a tension spring 89 is provided around the roller 90. Thus, this spring also maintains the lever 83 and the release wedge 52 in their rest position.



  The actuator slide 87 is provided with a notch 87a which is located in the displacement orbit of a drive and erase lever 91 (Figs. 3, 4 and 16). This lever is articulated on an axis 92 on the extreme right wall of the machine and it is driven in an oscillating and reciprocating movement around this axis by an arm 94, a roller 95 of which runs through a curved groove 91a of the drive lever. 91.

   By means of a link 96, the lever 94 is connected to a lever 97, which is articulated on a fixed axis 98 and is provided with a roller 99 resting on a release cam 100 mounted on a shaft 101. Said shaft rotates when the main actuator 32 is disengaged. The release wedge 52 for the drive rotor 34 is thus driven simultaneously or in synchronism with the corresponding release wedge of the main actuator 32.

   The actuating slide 87 is further provided with a projection or lug 87h <B> e </B> (fig. 2, 4 and 29) which, when this slide is moved in order to perform an erasure operation in the direction of arrow D, strikes against notch 59a (fig. 2) of the guide arm 59 and swings this arm so that the drive rotor 34 is returned to its zero position (extreme right position). This takes place at the same time as the release wedge is. moved to the left by lever 83, as indicated above, in order to release the drive discs 39.

   It should be observed that the hook 53 is provided with oblique surfaces, so that the drive discs 39 can be released without it being necessary to remove the hook first from the notches 39c, 39d.



  The actuating slide 87 moves counterclockwise on the fi-. 3 and 4, when an arm 102, with its finger 103, acts on the oblique surface of a cam 87c (FIG. 3) of the actuation slide. On a fixed plate 10-1, which is rigidly connected to the base plate of the machine and. located somewhat below this base plate, a locking arm 106, comprising a number of teeth 107, is articulated by means of an oblong slot on an axis 105 (FIG. 4). This locking arm is also provided with a buttonhole 106a.

    traversed by a fixed finger 108 of the plate 104 and serving as a guide to the locking arm 106. The latter is normally hand held, thanks to a tension spring, in its rest position shown in FIG. 4, and in which the locking surface 45a on the right end wall 45 of the drive rotor can pass freely relative to the teeth 107 (Fig. 3).

   But when the locking arm 106 is. tilted backwards in the machine (ie downwards in fig. 3), the locking surface or rusting worm 45a is blocked by one of the teeth <B> 107. </B> Therefore, the spring. 63 cannot then pull the reader rotor 34 over a greater distance than that determined by the stop of the right end surface of the slot 106a against the finger. 108.

   This terminal surface is of such dimensions that when the locking surface 45a of the reader rotor is urged by one of the locking teeth 107, the reader rotor 34 has moved a distance of such a length, in the lateral direction of the machine (that is to say in the longitudinal direction of the shaft 40) that the laying arms 28b, 29b can no longer act on the drive discs 39.

   In other words, the drive rotor is moved axially by about half a notch, and if the laying arms 28b, 29b are actuated now, their fingers 33, 36 (fig. 1) pass freely between the two discs. readers 39. Thus, the disk drives are no longer operated now when a number key 0 to 9 is pressed.



  When the key X16 is lowered, projection 16a. (fig. 3) actuates one end of the. aforementioned link 102 which is articulated on a fixed axis 110 and which is also gui dée by fixed axes 111 operating at. the interior of oblong and circular mortises made in said connecting rod. When the Î16 key is lowered, the rod 102 is bottom abutment counterclockwise on the. fig. 3 and, by virtue of its finger 103, it swings the aeration slide 87 in the counterclockwise direction.

   As a result of the actuation of a tension spring 112 (fig. 4), soot connecting rod 113 is. then pulled to the left so that the projection or tooth 113a attacks the drive and release lever 91 (Fig. 3). Normally, that is to say when the key Y16 is not lowered, the rod 113 attacks by means of its contact surface 113b the actuating slide 87, and the. projection 113a is. then outside the orbit of displacement of the arm 91.

   When thus, following the lowering of the key 16, the rod 113 with its projection 113a has entered the displacement orbit of the arm 91 in the manner just described, the arm 91 does. tilting the link 113 in the reverse direction of clockwise (FIG. 4) on the axis 110, on which the said link is also articulated by virtue of an oblong slot through which the axis passes. The link is also guided by the finger 111. When the link 113 is thus tilted counterclockwise (fig. 4), its edges strike the finger 70 (fig. 1, 2, 3 and 4) of the slide 64.

   The latter is then disengaged from the finger 65 (Fig. 2), so that the drive rotor is disengaged from the detent displacement device for the main actuator 32. At the same time, the lug .113c (fig. 4) acts on the locking arm 106 so that the latter is tilted (in the direction of clockwise in fig. 3 and 4) and that it attacks, by means of its teeth <B> 107, </B> the blocking surface 45a of the drive rotor 34.

   The spring 63 (fig. 2) now maintains the stop or stop surface 45a of the drive rotor in pressure against one of the teeth 107.



  Thus, when the key X16 is lowered, the drive rotor is disengaged with respect to the main actuating device 32 (and its device for moving by notches) and it is blocked in the determined position in the lateral direction of the machine. As stated above, the drive rotor, the fitting operation of which has already been completed before, is now also outside the displacement orbit of the laying arms 28b, 29b.



       The right end of the arm 102 is in the form of a fork surrounding the lower end of a lever 114 (Figs. 3 and 17). Said lever is articulated on a fixed axis 115. When, following the process described, the arm 102 is tilted counterclockwise (FIG. 3), that is to say in the direction of .

   arrow F in fig. 17, the lever 114, with its projection or lug 145U (fig. 17) actuates the erasing link 116 so that the latter is moved rearward in the machine and performs the erasure or disengagement of the main device. 'actuation 32.



   <I> Installation of </I> multiplier. When both the main drive rotor 32 and the drive rotor 34 are disengaged or deleted, the multiplier can be set by means of the ten-key keypad 0 to 9. The main operating lever 18 is located. then in its automatic multiplication position.

   If a numeral key is lowered, for example key 4, a spindle disc in the actuating rotor 32 is prepared in the well-known fashion by the setting arm 28a when the latter is moved in the opposite direction. hands of a watch as a result of the lowering of the button (fig. 1). At the same time, the arm 28b prepares the drive disk 39 of the same designation to the numerical value 4.

   During this process, the finger 58 fixed on the arm 28b acts on the locking arm 53, so that its hook 53a is tilted out of engagement with the corresponding locking notch. <B> 39th </B> on the drive disk that one is in. posing. The number 4 is thus placed in the same name on the two rotors 32 and 3.1.



  After that, the actuating rotor 312) is moved from the. well-known way of half a screen to the left. The finger 65 (Figs. 2 and 15) connected to the actuator is also now moved half a notch to the left and the drive rotor 34 is also moved a half notch towards the left. the left thanks to its tension spring 63.

   The fingers 31 and 33, respectively on the laying arms 28a, 28b are thus released from the discs which have just been prepared in the two rotors and, as a result of this movement of half a notch, the drive disc 39 that the 'we have just asked is locked by one of its notches 39c, 39d (Fig. 6) cooperating with the. guide projection 50a of the locking bar 50. The disc which has just been placed in the main actuating device is, of course, blocked in a similar manner.

    When the previously lowered digital button 4 is now released, the laying arm 28 returns to its rest position, the notch movement mechanism is released in the well-known manner, so that the two rotors are moved together always half a notch to the left. When the laying arm 28 returns to its rest position, the locking member 53 also returns to its rest position shown in FIG. 1, as a result of the action of the spring 56. The next drive disc which is now in the set-down position is thus locked by the hook 53a until a number key is lowered again.



  The other digits of the multiplier are then set in an entirely analogous manner and simultaneously in the two rotors 32 and 34.



  After all the digits (denominations) of the multiplier have. been installed, the X16 key is lowered. Following the process described above in detail, this determines the clearance of drive rotor 34 from the notch movement mechanism and causes it to be gripped by a tooth (lock 107 (fin. 3).

   At the same time, the main actuator 32 is disengaged by the actuation of the arm 102 (fig. 3 and <B> 17). </B> Since the actuation slide 87 has already been tilted in order to be released from the drive and release arm 91 (fig. 3 and 76), the drive rotor is not disengaged.



  Thus, the multiplier is now stored in the drive rotor 34 which is locked in the given position, while being mechanically isolated from the Brans displacement mechanism. The main actuator 32, however, is disengaged.



   <i> Pose says </I> nnitltipdicaade.



  By means of the ten-key keypad 0 to a, the multiplicand can now be placed in the main actuating rotor 32 in the usual manner. The fingers 33, 36 (fig. 1) on the laying arms 28b, 296 now pass freely between two discs in the drive rotor which has been moved and locked, the latter having been locked in a full stop position. by the finger <B> 108 </B> which per cute against the right end of the. slot 106a (fig. 4).

   When said laying arms are working, they certainly release the locking device 53 (thanks to the finger 54 fig. 1), but all the drive discs have now been blocked by the locking bar 50 and, therefore, are not moved. . Ef face2nent oit degageni.ent <I> of the rotors. </I> To erase or disengage the two rotors, press button 20 (fig. 17).

   The actuating rotor 32 is thus erased in the well-known manner, and the disengaging shaft 101 (Fig. 16) at the same time begins to rotate, so that the driving arm and (the die, has --entent 91 moves forward in the machine, that is to say respectively to the left on fig. 16 and upwards in fig. 3, and it attacks the projection 87a on the -lis S7 actuation in order to move it in the direction of arrow D (fig. 4).

    The ear 87b of this slide then strikes the notch or the stop 59a (fis. 2) of the lever 59 which is. caused to rotate in an anti-clockwise direction (fi, -. 2) and which now pulls, by means of the finger 61, the drive rotor back towards its rest position, that is to say say to the far right. The locking surface 45a (Fig. 3) rests on the oblique and beveled surfaces of the teeth 107 so that the locking device 106 is released from the drive rotor.



  In the manner indicated above, the erase or release wedge 52 of the drive rotor is moved to the left by the. actuating slide 87 through the intermediary of the lever 83, so that the drive discs 39 are released and their notches 39d are successively penetrated by the edge 50f of the locking bar (fig. 5) and that they are blocked by this edge in the zero position.

   Before the start of the disengaging or erasing operation, the left part (that is to say, located to the left of the notch 50b on figures 10 and 5) is released from the notches 39c, 39d of those drives that are. placed to the left of notch 50b; this takes place in the manner described above. due to the fact. than the finger. 51, through the protrusion 51a, acts on the cam groove 50e during the movement to the left of the release wedge 52.

   It should be observed that, when the locking bar 50 is tilted upwards (FIG. 5), the edge 50f is not released from those among the drive discs 39 which are. placed against said. edge, but who are not. not posed.

   We can also sou li-ner that the movement of the release wedge is so long that the drive discs 39 are already released when not felt near the locking device 53a. However, the. Locking slide 64 biases finger 65 (fig. 2), so that drive rotor 31 is disengaged or erased and again coupled to the notch movement mechanism of main actuating rotor 32.

   The actuating slide 87, and thus would equal the release wedge 52 and the locking bar 50, return to their rest position under the action of the return spring 89 (Figs. 3 and 4). <I> The reader device. </I>



  In the U-shaped support member 48 is mounted (Figs. 1, 3, 5 and 17 to 19) a shaft 120 which has an oblong buttonhole into which is inserted a key 121. The latter comprises, along d Part of its length, a series of teeth 122 and a reader 123 (reader finger) moves along the shaft. The key 121 prevents the reader finger from rotating around the shaft 120. This reader finger has the. shape of an organ in <B> U </B> 123, both legs of which are pushed towards shaft 120.

   On one of the legs of the reading finger is provided a curved part or ear 124 which, when the reading finger is tilted in the direction of clockwise according to FIG. 1, strikes one of the shoulders 39e, 39f of that among the disk drives which are located just in front of said ear 124.

   The setting of a factor, previously operated in this denomination of the drive rotor, determines which of the shoulders 39e, 39f is in the orbit of rotation of the ear 124, and the rotation of the shaft 120 from its rest position, until the reader finger 123, 124 hits one of the shoulders 39e, 39f is thus determined by the numerical value recorded in this designation of the reader rotor.



  On the reader finger 123, a displacement pawl by notches 125 is articulated on a pin or rivet 126 (see in particular FIGS. 5 and 9) and is actuated by a tension or tension spring 127. This spring tends to cause a pawl 125a of the pawl 125 towards an edge of the reader finger 123.

   The latter is actuated by a tension spring 128, one end of which is fixed to a pin 129 on the finger itself and the other end to a pin 120a of the shaft 120. The spring tends to move the reader in the direction of the arrow C, but it is normally prevented from doing so by a tooth <B> 125th </B> of the pawl 125 which is engaged in one of the teeth 122. A U-shaped contact member 130 is articulated on the shaft 120 (FIGS. 1 to 3, 5 and 5A).

    This member is attracted to its resting position by a spring 130a (fig. 5A) and, in this position, a finger 130b of this member engages against the shoulder 48g (fig. 5A and Sp) of the member. 48 U-shaped.



  When the shaft 120 rotates counterclockwise according to fig. 1, the projection 125a of the detent pawl 125 abuts against the shoulder. 130 and is thus caused to rotate clockwise according to 1a. fig. 9.

   The tooth 125c is then disengaged from the corresponding tooth 122 and the spring 128 pulls the reading finger 123 a certain distance in the direction of the arrow C until the reading finger is stopped again due to a second tooth. 125b of the pawl 125 which abuts against the same tooth 122 from which the tooth 125c has just been released.

   When the reader finger 123 is moved (clockwise in fig. 1) back to its rest position, the spring 127 pulls the pawl backwards in the next counterclockwise direction. fig. 9; so that its tooth 125b is released from the tooth 122 just mentioned, and the reading finger is pulled a certain additional distance to the left by means of the spring 128 until the tooth <B> 125th </B> attacks the next tooth 122.

    When the shaft 120 has once undergone a reciprocating rocking movement (first counterclockwise and then in the same direction as these needles according to fig. 1), the finger drive 123, 121 has been moved axially by one notch, that is to say by the same distance as the axial distance between two drive disks 39.

    The tilting of the finger 123 back and forth with a view to a read operation also has the consequence of moving the projection 12-1 (In finger from one notch from one drive disk 39 to the next disk. , the reader rotor 34 is stationary during the reading operation, but the reader finger itself <B> 123, </B> 124 is moved step by step simultaneously with the actuating rotor 32.



  A special release or restoration arm 131 (FIG. 3), articulated on a fixed axis 132, is provided to return the finger 123, 124 to its rest position (on the extreme right).



  When the two rotors 32 and 34 are being erased or disengaged, the arm 131 is actuated by the drive and erase arm 91 (fig. 3 and 16) to rotate counterclockwise. a following my being, fig. 3.

   The forked end 131a (bed arm 131 grips an edge of the reading finger 123, which is thus returned to its position (the extreme right rest when the arm 131 is caused to oscillate counterclockwise. shows, as we have just indicated. When the key 20 (fi - #) -. 17) is depressed, this has the effect of disengaging or erasing rotors 32 and 34 as well as (read finger 123.



  At the right end of the shaft 120 is fixed an arm 133 (end. 3, 5, 17 to 19, <B> 27A </B> and 27B) that a tension spring tends to pull in the direction <clockwise, following the fi-. 17 to 19. In addition, a segment. toothed <B> 135 </B> is articulated on the axis 188a which is fixed on the end plate 188. The axis 188a. and the shaft 120 have a common axis. This toothed segment comprises three projecting shoulders 135a, 135b and 135c intended to strike, respectively, against the edge of the arm 133 and. against a surface 137. and a correction lever 140.

   The surface 137a is provided on an oscillating arm 137 which is articulated on a fixed axis 136 and which comprises a mortise in which slides a finger 138 of the arm 1.33. The surface 137a constitutes a cam on which the shoulder 135b slides when the shaft 120 rotates. Said surface prevents the shoulder 135b from leaving the arm 133 as a result of the rapid oscillating movement which occurs. During these movements, the toothed segment 135 thus follows exactly the movement of the arm 133. A tension spring 139 is. fixed between the arm 133 and the toothed segment 135.

   The paw <B> 135th </B> projecting out of the toothed segment attack, when the segment is, in the rest position, the shoulder 140a of the corrector arm 140 which is mounted so as to be able to oscillate on a fixed shaft 1-11. A tension spring 142 tends to move this arm in the direction of clockwise according to FIG. 17. However, this movement is normally prevented by a flange 1-10e provided on the correction arm 140 resting on the shoulder. <B> 135th </B> of the toothed segment 135.



  The teeth of segment 135 are constantly meshed with a 1.43 counter gear rotating on a 1-1-i axis mounted on a large arm 1-15. The reading device consisting of the reading finger itself 123, 124 (fig. 1 and 19), the shaft 120 (fig. 17 and 19) as well as the elements 133, 135, 1-13 is of such dimensions that The counter gear 143 rotates forward one notch (one tooth.) when the finger protrudes 12-1. player (fig. 1 and 19) abuts against a player disc 39 in which the number 1 has been placed (see fi, -. 6).

   If the drive disc 39, in the denomination in question, has been placed on the number 2, the gear 1-13 is. moved two notches, and so on, always at. provided that at the start of its rotary movement the toothed segment 135 rests with its projection <B> 135th </B> on the shoulder 1.10a of the correction arm 140 (see fi, -. 274; this is the position! Of the correction arm).

    But if, at the start of its rotary motion, the toothed segment 135 rests with its projection 135e on the shoulder 140b (see fig. 27B; this is the position - of the correction arm), the toothed segment has been moved. back exactly one notch (or one tooth) from the counter gear 143, so that the distance between the arm 133 and the protrusion 135a of the toothed segment is reduced to almost zero.

   When the reader finger 124 is in the rest position (fig. 1), the distance between this finger 124 and the shoulder 39e on a reader disc which is placed on the 0 corresponds to the rotation of a tooth of the toothed segment ( or, in practice, slightly more).

    This means that when the protrusion <B> 135th </B> of the toothed segment comes into contact with the shoulder 140b and that the reading finger 124 moves towards a drive disc 39 set to 0, the gear 143 is caused to rotate by 1 + 0 = 1 notch ; for a disk drive set to number 1, gear 143 rotates in a similar way by 1 + 1 = 2 notches, etc.

         When a disk drive is put on the number 9, said gear then performs 9 + 1 = 10 notches - -Lin full revolution <B> (3600). </B>



  Against the gear 143 is riveted a cam disc 146 against the periphery of which rests an installation slide 147 (see also Figs. 20, 21 and 28g to 28C). This slide comprises pins 148 penetrating into oblong grooves made in the large arm 145 so that the slide is movably mounted on said arm and that it is biased by a tension spring 149 (FIG. 19) to remain in motion. contact with the periphery of the cam disc 146.

   The latter has three different rays <I> a., B </I> and c, and the slide 147 can thus take three different positions <I> a, b, </I> c determined by said radii (see Figs. 28g, 28B and 28C, respectively).



  Position a (fig. 17, 18 and 28g) corresponds to the 0 notch rotation of gear 143 or else, which is the same as it is, 10 notches from its rest position. Position b (fig. 28B) corresponds to the rotation of 1 to 5 notches, from the rest position, of the gear in question. while if the gear has been turned 6 to 9 notches, the slide reaches its position c (fig. 28C).



  This slide is provided with a protruding shoulder 147a which, when the slide is in its position a (fig. 17,18 and 28g), actuates the shoulder 150a of an arm 150 which is articulated on the axis 136. The slide also comprises a shoulder 147b which actuates the projecting shoulder 151a of a small slide 151 which is mounted in a movable manner on pins 152 fixed on the oscillating arm 140. A tension spring 153 tends in maintaining the slide 151 in its zero position.

   The shoulder 151a is actuated by the shoulder <B> 147b </B> of the slide 147 only when the slide 147 is in its position b, which is visible in FIGS. 19 and 28B. The positioning slide 147 also includes a projecting part 147e which, when this slide is in its position b (fig. 19 and 28B) or c (fig. 28C), actuates two arms 154 (fig. 19), 155 (Fig. 18) and swing them counterclockwise when the arm 145 is raised (clockwise).

   Finally, the positioning slide 147 has a fourth shoulder 147d which can be hooked onto a hook or pawl 156 articulated on an axis. <B> 157 </B> attached to the arm 145 and which is actuated by a tension spring 149. The two arms 154, 155 are. mounted on a shaft 158.

   One end of a tension spring 159 is attached to lever 154, the other end of this spring being attached to finger 160 of multi-turn key 14. This spring tends to engage the edge of the arm 154 against the finger 160, as will be seen in FIGS. 18 and 19.

   If the arm 154 is tilted counterclockwise (by the positioning or installation slide 147, following the process described above) according to fig. 18 and 19, this movement is transmitted to the toueh # 3 14 of the multirotations minus by the spring 1.59. A finger 161 (fig. 18), which is riveted to the button 15 of the multirotations plus, attacks the edge of the arm 155 under the action of a tension spring 162 which serves to transmit the movement of the arm 155 to the + button. 15.

    The arm 150, which is articulated on the fixed axis 136, is arched in the shape of a U and carries at its opposite ends (fig. 16) an arm 150b which acts on an impulse lever 163. When it is. caused to rotate counterclockwise according to fig. 16, this lever determines the stop. of the rotor 32, in a well-known manner, in its complete cycle position as well as the start of the displacement by notch of this rotor.

    On an axis 164 is mounted an elbow lever <B> 165 </B> which is held in its normal position by a hairpin spring 166, and whose two elements rest in two directions, on a 1.67 axis spun on the arm 150 as well (read on a protruding latch 168 on the angled lever 165. The latter can therefore be held elastically in both directions.



  An axle 169 is riveted to the cam disc 146 attached to the counter gear 143. When lifting (clockwise according to Figs. 17 and 18) as described in detail below, the large lever 145 on which the shaft 144 is mounted for the cam drive, this axis 169 is moved upwards in the direction of the elbow lever 165. However, if this cam disc 146 is in its zero position (fig. 17 and 18), the angle lever 165 is not actuated.

   But if the cam disc <B> 165 </B> is. in another position (for example, in the position shown in fig. 19) and that it is. caused to rotate back to its zero position, while the lever 145 is in its raised position, the pin 169 acts on one of the surfaces 165a or 165b of the angled lever 165 regardless of the direction of rotation. As a result of the foregoing, the lever 150 is raised, which determines, as indicated above, the stopping of the actuator 32 in its full cycle position, as well as its shift by one. notch.

       <I> Tooth </I> counter <I> and device </I> actuation <I> of the tachometer. </I>



  On a shaft 171 rotating in the frame 170 of the machine (FIG. 23) is fixed a counting tooth 172. This shaft is provided with a peripheral groove into which penetrates a plate 173 which prevents displacement. axial of this shaft. The shaft 171 is permanently connected with the shaft 174 of the tachometer actuator. The shaft 171 follows the rotation of the shaft 174, but, at the same time, the screwdriver coupling allows the necessary axial displacement of the shaft 174 relative to the shaft 171 which cannot move.

   The counting tooth or actuating device 172, which always turns in the same direction, as well as the tooth of the quotients or actuating device of the tachometer integral with the shaft 174, advances the gear 143 one tooth for each revolution of the shaft 174 when the lever 145 is in its up position, and, for this reason, the counter gear 143, mounted on this lever, is in the orbit of rotation of the counting tooth 172. But when the large lever 145 is in its lowest position, the counter gear 143 is not actuated by the counting tooth 172.

           Drive mechanism <I> with the reading finger. </I> By means of a gear 176 (fig. 22), a shaft 175 is coupled directly to the actuating motor of the calculating machine and it turns clockwise (fig. 17 to 19). On this shaft 175 is fixed a disc 177 which is provided with teeth (Figs. 22 and 17). The disc is keyed on the shaft 175, the rotation of which it follows. A spring washer 178 prevents axial displacement of the disc 177. The shaft 175 rotates in a bush 179, another sinet neck 180 being mounted on the previous one.

   Cam discs 181 and 182 are riveted to this second bearing 180. Lever 137 engages cam disc 181 (Figs. 22 and 17-19) and large lever 145 engages cam disc 1.82. At the right end of the outer pad 180 is fixed a disc 183 on which is articulated a coupling pawl 184 (fig. 17) via a pin 185.

    A tension spring 186 tends to pull the coupling ratchet 184 to engage it on the tooth 177 driven by the operating motor of the machine, and when these two members are. When engaged, the disc 183 and the cam discs 181, 182, which are rigidly connected with said disc, are connected to the shaft 175 driven by the motor during machine operation, so that the discs cam oscillate the two arms 137 and 145.



  However, the coupling pawl 184 is kept locked normally, in its rest position, that is to say outside the tooth 177, by a stop pawl 187 (fig. 17 and 22) which, thanks to to a protruding tongue 187a, blocks said pawl 184. The stop pawl 187 is articulated on a pin 189 fixed to the end wall 188 of sheet metal (fig. 17) and it is actuated by a spring of traction 190 which keeps it in its locking position.

   When the stopper 187 releases the coupling pawl 184, the disc 183 as well as the cam discs 181, 182 turn about half a turn, after which they are stopped by the stop hook 191 which , via a protruding ear 191a, attacks the coupling pawl 184 and releases the latter from the toothed disc 177.

   The stop pawl 191 is articulated on a pin 192 fixed to the end wall 188 of sheet metal (fig. 22) and it is normally maintained in its locking position (in engagement with the coupling pawl 184). thanks to a. tension spring 193, but it is however released from this position with said coupling pawl when the lever 150 is lifted and a pin 194 fixed on this lever abuts against the edge of the stop pawl 191. On the large lever 145, a stop pawl 195 of the counter gear 143 is articulated on a pin 196 (FIGS. 18 and 19). This stop pawl is attracted towards the gear 143 by a tension spring 197.

   One end of this spring is fixed to the pawl 195 and the other end is integral with the frame of the machine (the terminal pa king 188 in sheet metal) and therefore this spring serves at the same time to keep the lever 145 lowered against the Say that to cam 182. The gear pawl 195 is released from the gear 143 by the cam disc 182 acting on a contact surface 195a of the S-shaped pawl 195. To start the automatic multiplication, the operator presses the key <B> = </B> 17 which then actuates the oscillating arm 198 (fig. 3 and 4) which is articulated on a fixed axis 199.

    Normally, this oscillating arm is maintained in its rest position shown in fig. 3 and 4 by a 200 mistletoe spring. stretched between said arm and the oscillating arm 102. Now, when the arm 198 is tilted, consequently (the lowering of the key 17, an axis 201 is made to act riveted to said arm on a rod 202 which is articulated on a fixed axis 203. During this operation, the edge of the rod 202 abuts against a finger 70 and the arm causes the locking member 106 to tilt so as to make it come into contact with the worm surface 45a .



  The right end of the connecting rod 202 has the form of a fork 202a surrounding the lower end of a multiplication lever 20-1 (fig. 3 and 17). When button 17 is lowered, arm 204 therefore swings counterclockwise (fig. 17) on the lever. <B> 115 </B> on which it is articulated, so as to lift a link 205 which is articulated on a pin 206 riveted to the lever 204. This link now lifts the front end (or clockwise (fi-. 17) on the lever 187, the foureliue end of which maintains the rod 205 with which it cooperates.

   At the same time, the link 205 also raises the hook 156, since the link strikes the cambered pawl 156> a. of this hook. 11 at its lower end, the rod 205 is surrounded by the end fork of the release lever 207 (Figs. 3 and 17), which is articulated on a pin 108 and has two leading edges 207a and 207b. These edges are actuated by the protruding ear 208a. a lever 208,

   'the latter being articulated on an axis 209a which is fixed on a flange on the extreme left wall 44 of the drive rotor 34 (see Figs. 5 and 26). The lever has a circular mortise in which a finger 209 engages on the same flange in order to guide the lever. By means of its other end, the lever 208 is in contact with the reader finger 123 which actuates this lever 208 when it is moved in an axial direction.



   <I> Selector </I> more -,) jtoiiis.



  A plus-irioins selector 211 can pivot on an axis 210 (fig. 3 and 4) fixed on the. base plate 104 and it is actuated by a spring. traction 212 which tends to rest the selector against the correction lever 140 if the latter is in its position - # - indicated in dotted lines in fig. 4.

   But if the correction lever 140 is in its position - indicated in fig. 3, a doin @ t 213 riveted to the selector 211 comes into contact with the rim of a cavity 104a formed in the plate 104 (FIG. 4). When the correction lever 140 is in the linen position; net 135c rests on the shoulder 140a of this lever, as shown in FIG. 17. But in the position - of the correction lever, the linen watches <I> 135th </I> rests against the shoulder 1-10b of this lever.

   The different positions of the elements 1-10, 211 are also shown in figs. 3 A and. 3B.



       qur axis 213 is. an articulated organ of verroiiilla; re \ _ '14 (fin. 3 <B> A </B>, 31; and 4) the upper end of which penetrates into a cylinder provided on a lever 215, the latter being mounted in a movable and, to a certain extent, tilting manner, on pins 216 fixed on the base plate 104.

   The rear end of the locking member 214 has a tab 214a (see also fig. 24) which, for certain positions of the locking member, blocks the key 15 of the multirotations plus so as to prevent it. to be lowered.

   A leg 198a. returned upwards, provided on the lever 198, enters a cavity (the rod 21.5 when the machine is engaged for automatic division (minus), as indicated in phantom in fig. 3.

   When the operator lowers button = 17, this button hits lever 1.98 (fig. 4) and swings this lever counterclockwise, which has the effect of moving rod 215 in the direction arrow H. The locking member 214 then takes positions III and IV, respectively (FIG. 3B) depending on whether the correction lever 140 is in its position -f- or in its position -. Thus, if the correction lever 140 is in the - position, the button <U> - </U> 15 est. locked (position III in fig. 3B).



  For normal multiplication (positive multiplication or more), the reverse lever 217 (fig. 3 and 2: 3) of the tachometer actuator is in its rear position shown in solid lines. (, that is to say respectively the lower position in fig. 3 and the left position in fig. 25), and now acts on the contact surface 215a of the lever 215, the latter being thus tilted towards the rear in the ma chine to its position indicated in solid lines on the fi--.

   3 and 4, and it is kept in this position, blocked against any longitudinal displacement (that is to say in the lateral direction of the machine) by the engagement of the pins 216 in the front parts (the upper parts at the end 4) buttonholes pre seen in the lever.

   At the same time, the lever 215 leaves the projection 198a. When the lever 215 is in this position, the locking member 214 takes respectively the position I or II according to fi-. 3A, depending on whether the correction lever 140 is in its + or - position.

   It is evident from fig. 3A, that the + key is stopped when the correction lever 140 is in its - position, but that it is free when said lever is in its -f- position. It should be noted that key - 14 is never actuated by the locking device. Fashion. <I> of </I> foractio11.lienrent. During a calculation operation,

   the devices described operate in the following way Assuming that the number 97 042 must be multiplied in the positive direction by a multiplicand of arbitrary value (within the capacity limits of the machine), we first set the number 97 042 as multiplier by means of the keys 0 to 9, as has been explained under the heading Placing the multiplicator, and then placing a multiplier, as described under the heading Placing the multiplicand. During this operation, the release lever 19 must be in its left position in order to ensure the correct direction of advance by notch of the two wheels 32 and 34.

   The operator then lowers key = 17 by hand.



  As stated above, the lever 187 is released from the coupling pawl 184 which rocks to engage the tooth 177. The lowering of the key 17 by the sign = also determines the oscillation of the.

   arm 20-1 clockwise as shown in fig. 17, so that its protruding leg 204a lifts the finger 218 (fig. 16 and <B> 17), </B> which closes the contacts of the electric motor in the well-known manner, so that the motor starts and drives, via the coupling 177, 181 which has just been engaged, the disc 183 and the cam discs 181, 182 (fig. 22). During this operation, the cam disc 182 (fig. 19) moves the stopper 195, thus releasing the counter gear 143.

   At the same time, the cam disc 181 oscillates the cooperating lever 137, and this lever switches the lever 133 via the finger 138 in the direction of clockwise according to FIGS. 17 to 19 (the tension spring 134 holds the lever 137 against the cam disc 181). When the arm 133 has lowered the shaft 120 of the device. drive in this way and by an amount slightly more than one notch, the arm 133 strikes, during its clockwise movement, the shoulder 135a, so that the toothed segment 135 begins to be tilted in. clockwise.

   At this moment, the shoulder 135b slides on the surface 137a, so that, during the entire rocking movement, the shoulder 135a rests against the lever 133. Thus, the toothed segment does not leave the lever 133. Consequently Quent, the shaft 120 switches the reader finger 123, 124 towards the first disk drive which is about to be h1. In the example chosen, this drive disc is set to the numeric value 2.

   During the. rotation of the toothed segment 135, the shoulder 135c releases the flange 140e of the correction lever 140 shortly before said segment has rotated by one notch and the lever 140 is lowered by the spring 142 in the direction of the needles d 'a watch to its position - in which the projection 135c contacts the contact surface 140b.



  When the reading finger 123, 124 is stopped by the shoulder of the reading disc which corresponds to the numerical value 2, the counter grading 143 has dared sir a distance corresponding to two teeth. The slide 147 moves to its position b (fig. 28B). After a time corresponding to that which would be necessary for the reader finger to move against the reader disk in order to read the numerical value 9 there, the pawl 195 is released from the cam disk 182 and. it is tilted by its spring 197 which engages it on the counter gear 143 and blocks the latter.

   At this time, the cam disc 182 swings the large lever 145 in the clockwise direction according to FIG. 17. The coupling pawl 184 is gripped by the lever 191 so as to disengage the coupling 184, 177 and stop the cam discs 181, 182. The counter gear has now rotated two teeth in the opposite direction. pours clockwise (and it got stuck in its new position). Since the. slide 147 is now in its position b, its lever 147a has passed near the protrusion 150a without the ner action (when the lever has been tilted clockwise).

   But the projection 147b of the slide 147, through the internal of the small slide 151, actuates the correction lever 140 and returns it to its + position. The shoulder 147e of the slide 147 lifts the levers 154, 155. Since the locking member 214 is in position I (Fig. 3A) and thus the -f- key is not locked. , this key as well as key X16 respectively follow the oscillating movement of levers 154 and 155.

   According to the well-known method, the rotor of the aeteration device 32 will start to rotate; . Therefore, the counting tooth 172 also rotates in a positive manner, i.e. counterclockwise in FIG. 17 and thus begins to count for the counter gear 143 returning to zero, one notch for each revolution of the shaft 174 of the counter actuator.

    When this gear completes the last notch of rotation, the finger 169 (fig. 18) which is rigidly connected to said gear, abuts against the left or front lever 165a so that the lever 150 is tilted upwards and, consequently, Key as described above under the heading of Reader Device, disengages the motor of actuator 32, and the latter stops in its full cycle position and begins automatic movement by step.

   Finger 194 lifts hook 191 (counterclockwise in fig. 17), so that coupling 184, 177 is re-engaged and cam discs 181, 182 engage. again to turn. Now, the cam disc 181 lifts lever 137 (clockwise) (pulls the drive finger 123, 124 back to its home position.

    However, the right side of the cam 181 first oscillates the lever 137 further in the clockwise direction looking at the fi '. 17, which determines, in the manner indicated above, under the heading Disposal device, by means of the elements 125a, 131 (fig. 1), the shift of one notch of the reader finger 123 , 124. Meanwhile, the segment (attempted 135 was stopped by the shoulder 140a (fig. 18).

   The large lever 1.15 drops again (counterclockwise, fig. 18) and the gear counter 143 is. again engaged with the toothed segment 135. When the coupling pawl 184 is. weary near the locking lever 187, the finger 145 has kept the lever 204 up, butting against the rim of said arm 204 and thus the cam discs 181, 182 are not stopped in their rotation, since the arm <B> 187 </B> cannot release the coupling pawl 184.



  The arm 145 cannot fall back to. again until the tip of the coupling pawl 184 has passed through the projection 187a. The drive finger 123, 124, which has been shifted one notch in the meantime, is now dragged by the spring 134 towards the shoulder of the next drive disc which is placed on number 4. The counter gear 143 is now advanced. four notches and the actuating device 132 performs four turns in a similar fashion, after which it is stopped and shifted one notch exactly like the finger, drive 123 (the drive rotor 34 remains stationary throughout 'read operation).

   The toothed segment stops again when it abuts against the shoulder 140a.



  Now the next digit, which is a zero in the example chosen, is read from the read rotor 34. Therefore, the slider 147 is in position a during the read operation. The rim or protrusion 140c of the correction lever 140 then attacks the protrusion <B> 135th </B> over and thus prevents the correction lever 140 from falling again, since the toothed segment 135 does. not moved from its resting position.

   When the large lever 145 is then lifted, the shoulder 147a of the slide 147 bu \ e against the shoulder 150a, so as to move the actuator 32 by a notch. Since levers 154, <B> 155 </B> are not actuated, the actuating device 32 does not restart. With hook 191 having been lifted by finger 194, coupling 177, 184 remains engaged and therefore the next number, which is 7, is picked up in drive rotor 34.



  During this operation, the counter gear is. tilted seven notches in an analogous manner, and the slide 147 is therefore placed in its position c. The arm 140 falls again, but will not be raised again, because, when the slide is in its position c, its shoulder 147b passes through the projection 151a without actuating the latter. The levers 154, 155 are again tilted outwards by the projection 147c, but, since the lever 140 is in its position (see fig. 34 and 3B), the + button 15 is blocked, while , on the other hand, the key 14 is actuated.

   The actuator 32, therefore, begins to rotate in the negative direction (see arrows in fig. 1), that is to say clockwise in figs. 1 and 17. The counting tooth 172 now turns clockwise and thus returns the counter gear 143 to zero in the opposite direction, that is to say 10 - 7 = 3 notches, and when this has taken place, the lever 165 stops the machine again, as described above. The tachometer now shows the following digits: 99997042.



  When the toothed segment 135 moves back in a counterclockwise direction, it is stopped by the shoulder 140d and thus it is stopped in a position which is offset by one tooth from the previous rest position. of the segment (the projection 135c being against the shoulder 140a). Now, when the last digit, which is 9, is read in the reader rotor 34, the counter gear 143 is consequently switched by 1 - + - 9 = 10 notches, that is to say by one. full tour.

   Due to this, the slide 147 assumes its position a, and when the large lever 145 is lifted, it only performs notch shifts of the actuator 32. The toothed sector 135 is then stopped again by the 'shoulder 140b. During the notch-shifting operation (to the left in fig. 3 and 5) of the reading finger 123, 124, an operation which now takes place, the reading finger abuts against the lever arm 208 which is tilted into the clockwise and which oscillates the arm 207 in the same direction according to FIG. 3.

   Thanks to this, the spring 207c, which has held this lever and, by that very fact, also the rod 205 in the coupling position, is put under tension. The rod 205 (FIG. 17) is thus released from the pawl 187 which is pulled by the spring 190 towards its actuating position to release the coupling pawl 184. However, the latter is not released as long as said pawl has not passed through the projection 187a and a new read operation is not performed.

   During this operation, the reader finger 123, 124 abuts against a shoulder 44a (fig. 1, 3 and 5, and 5a) of the end wall 44 of the reader rotor. This shoulder has the same height as the shoulder 39th of zero on the drive disks 39. As a result, a read operation for the value 0 takes place. When the toothed segment <B> 135 </B> now cooperates with the shoulder 140b, the counter gear is thus tilted by 1 - + - 0 = 1 notch during this reading operation.

   Consequently, the slide 147 takes its position b, the lever 140 oscillates counterclockwise according to FIG. <B> 1.7 </B> and the actuator performs one + rotation and then stops. The coupling pawl 184 continues its rotation, but is gripped by the lever 187 and is released; it stops with the lever 145 in its lower position and the lever 137 in its rest position. The toothed segment is now stopped by the shoulder 140a.



  It may be worth mentioning that when the machine is set for minus multiplication, the main actuator rotates in the + direction when the lever 140 is in its - position (the 135th protrusion resting against the shoulder 140b), while said actuating device rotates in a negative rotation or - when the arm 140 is in its position - + - (fig. 18), that is to say exactly the opposite of the case occurring for the multiplication phis. So during multiplication less,

   the additional value of the product is recorded in the accumulator or recorder. In other words, the product is automatically subtracted from the number already stored in the accumulator or product recorder.



       Since the arm 208 is articulated on the drive rotor 34 and thus follows this rotor, when the latter is. offset by notch, and, moreover, when the edge 207b (fig. 3) of the lever 207 in its released position is parallel to the shafts 40 and 120, as a general rule, the disengagement takes place (the manner in which has just described since one digit more than the number of digits placed in the reader rotor is read. This operation (the additional reading takes place against the shoulder 44a (fig. 1, 3, 5 and 5A). however an exception.

   The calculating machine shown in the drawing has eight number wheels in the tachometer, as well as eight drive discs 39 in the drive rotor 34. 5i a number like 99,999,999 is now placed in this drive rotor and the the machine is started up (after placing a multiplicand, for example), the numerical value 9 is perceived on all the disk drives 39.

   Therefore, the main actuating device and the tachometer actuating device perform one rotation - in the first (lowest) denomination, and when multiplying more, the number 9 appearing. on all number wheels of the tachometer. All of the following denominations in the drive rotor are now perceived as 7 -r 9 = 10 and, therefore, the main actuator 32 (as well as the tachometer actuator) will only be shifted in steps. or laterally without there being rotation.

    The abbreviated multiplication, in this case, takes place according to the following scheme:
EMI0021.0015
    However, there is no denomination k in the tachometer for the necessary correction revolution (rotation more after shifting d) -in notch towards the eighth denomination), but the machine must count ten revolutions in the eighth (highest) denomination E in order to obtain the correct result.

   To this end, the lever 207 is provided with a contact surface (cam surface) 207a (Fig. 3), and the projection 208a. on the lever 208 is in front of this projection 207a when the maximum number (the digits, i.e. eight in the example in question, is set in the drive rotor 34.

   We see from the fi; -. <B> 3 </B> that the projection 207a is so high that the reader 123 must, by means of the lever 208 and its projection 208a, remove the lever 107 at the location of the projection 207a, already when the reader finger 123 is moves to the play position at the last drive disc 39 (far left), when the drive finger 723 is shifted its last notch to the left. From the calculation example described in detail above, it. East.

    It is clear that this notch movement of the reader finger 123 does not take place until the coupling pawl 1.84 has passed close to the projection 187a. The uppermost drive disc 39 (far left) is thus raised and. the counter gear 7.13 turns ten notches. If the. slide (fi. 17) must be functional- It now as in the other cases, it will move first to its position b, then to its position c and finally it will return to its position a.



  However, immediately after reading the last digit in drive rotor 34, lever 207 swung link 205 counterclockwise (Fig. 17). The upper edge of said link passes freely near the projection 156a on the pawl 156 when the lever 145 moves back.

   When, during the last reading operation, the slide 147 reaches its position b (fig. 28B), the stop pawl 156 drops back (clockwise, fig. 17) and engages. the projection 1.47d, so that the slide 147 is prevented from returning to the position a by the position c. However, when lever 207 and therefore lever 205 are in their rest position, the upper edge of lever 205 moves pawl 1.56 counterclockwise (Fig. 17) and prevents commitment. of this pawl against the shoulder 1-17b on the slide 1.47, the blocking of which is thus prevented.

   Consequently, the slide 147 is now hooked or locked in its position b. When during operation of the machine the arm 145 is raised (clockwise), the correction lever 140 is raised to its position -f-. This determines the start of the actuator 32 following + rotations and, when it has completed several turns, it is disengaged and all the elements of the drive rotor return to their key rest position in the manner described above.

   When the lever 145 was raised, the counter gear 143 was in the zero position (position a), the finger <B> 169 </B> being directed upwards, although the slide 147 has been locked in its position b. Thus, the finger 169 moves upward passing between the levers 165a and must travel a full revolution before tilting the stopper (ball joint) 165, which determines the lifting of the stopper lever. <B> 150 </B> which stops the machine.



  When the automatic multiplication is finished, the multiplicand can be read on the recording or exposure device, the multiplier on the tachometer, and the result on the results recorder or accumulator.



  It should be observed that if, after having completed the multiplier (see Installing the multiplier above), the X16 key is not lowered, the = 17 key being lowered in its place, the machine performs an automatic multiplication with one and the same factor _ (that is to say the multiplier set), in the rotor 32 as well as in the rotor 34. Thus, the machine performs the operation of squaring the number posed.



  If it is desired to multiply a number of different multiplicands with one and the same multiplier, the latter is first placed at the same time on the rotors 32 and 34 and the actuating rotor 32 is deleted by pressing the X16 key. . Then, the first multiplicand is set and the product is calculated automatically, when the key 17 is pressed. When this operation is completed, only the actuating rotor 32 is released and cleared by lowering the key X16, the remaining multiplier. placed unchanged in the reader rotor 34, but the reader finger has been returned to its zero position.

   It is convenient to disengage the tachometer simultaneously by means of the clearing lever B (fig. 3); whether the accumulator must also be released (by means of the release lever A) depends on whether or not it is desired to accumulate the different and successive products in the accumulator. Now a new multiplicand is placed in the actuating rotor 32 by means of the number keys 0 to 9 and, when the key = 17 is lowered again, the new multiplication is carried out automatically with the same multiplier res both in drive rotor 34. This process can be repeated any number of times with other multiplicands.



  If the button 20 (fig. 17) is depressed, the actuating rotor 32, as well as the reading rotor 34, are released.



  In this way, the machine has only one keypad and one exposure indicator or recorder mechanism. However, it can perform all of the automatic multiplication operations indicated above.



  There is a link to indicate that the foregoing description referring to the plus multiplication applies in the same way to the minus multiplication. Note, however, that in the minus multiplication, the rotations take place in the opposite direction than in the case of the plus multiplication. Thus, the + rotations in the plus multiplication correspond to the - rotations in the minus multiplication; likewise, the rotations - of the multiplication plus correspond. at rotations -f- of the multiplication minus. The shift to carry out a multiplication takes place in a well-known manner with a shift button 219 (Fig. 25).



  The machine shown can perform the addition and subtraction operations, with automatic erasure of drive rotor 32 and also drive rotor 34 after each operation, as well as automatic division operations. The machine can also perform semi-automatic and fully hand-controlled multi-fold operations.

 

Claims (1)

CLAIM Calculating machine for automatic multiplication, comprising two actuating devices, one for the multiplier and the other for the multiplicand, characterized in that between the two actuating devices is arranged a control member (147) for the device <the actuation (read multi plicand (32), this member (the control (147) being able to be placed, by the actuating device of the multiplier (34), in three positions representing an absence of rotation) , a positive rotation and. negative rotation for the multiplicand actuator (32) to actuate the multiplicand to perform an abbreviated automatic multiplication. SUB-CLAIMS 1. Calculating machine according to claim, characterized in that said control member (1-17) is actuated and adjustable by a cam disc (1.16) comprising three different radii, ie one for each of the three positions. control. 2. Calculating machine according to claim, characterized in that said member <B> (the </B> control (1-17) is placed in the position of positive rotations, for the number values 1, 2, 3 and 4, while it is placed in the position of negative rotations for the numeral values 6, 7, S and 9. 3. Calculating machine according to subclaim 2, characterized in that the control member can be placed in the position of positive rotations for numeral 5. 4. Calculating machine according to subclaim 2, characterized in that said control member can be placed in the position of negative rotations for the number value 5. 5. Calculating machine according to claim, characterized in that 'it can also be set for the fully automatic negative multiplication, this negative multiplication also being abbreviated. 6. Calculating machine according to claim, characterized in that, for a positive multiplication, when the multiplicand actuator (32) has carried out a negative calculation for a denomination of the multiplier, the value transferred by the gold control gane (1.47) from the following denotnbia.tion said actuator. of the multiplier is increased by one unit. 7. Calculating machine according to claim, characterized in that, for a negative multiplication operation, when the positive multiplicand actuation device ('? Has performed a positive calculation for a denomination of the multiplier, the value transferred by l The actuator (147) from the following denomination of the actuator (34) of the multiplier is increased by one unit. Calculating machine according to claim, characterized in that a cam disc (146) acts directly on the control member (1-17) and brings this control member (147), before the shape of an adjustment slide, towards the three aforementioned control positions, said adjustment slide acting, in these positions, on various operating means (150, 151 and 154, 155) in order to drive the actuating device of the multiplicand (32) respectively towards the positions (the non-rotation, positive rotation and negative rotation for this denomination of the multiplier. 9. Calculating machine according to subclaim S, characterized in that said cam disc (146) as well as the adjusting slide of the control member (147) are arranged on a lever (145) which can , be raised and lowered in order to cause said slide to act on the aforementioned actuating means (1.50, 1.51 and. 154, 1.55).