CH198454A - Accounting machine. - Google Patents

Description

  

  Accounting machine. . The present invention relates to an accounting machine capable of effecting balance reversals and in which the complement of a negative balance formed in the addition-subtraction mechanism is, by an uninterrupted cycle of mul operations. tiples, transformed into an effective balance which is printed as a final total or as a subtotal (intermediate total).

   In the machine according to the invention, the uninterrupted cycle of multiple operations, necessary for the transformation of the complement and for the printing of the effective negative balance, always comprises the same number of operations, whatever the function performed by. machine, final total or subtotal.



  It is thus possible, in the machine according to the invention, to control, in both cases, final total and intermediate total (also called subtotal), a very large number of operations at determined times, always the same, and this in such a way that the control differs as little as possible from one case to another and that the corresponding components are considerably simplified.



  The appended drawing represents, by way of example, an embodiment of the machine forming the subject of the present invention. In; this drawing: Fig. 1 schematically represents the key: vier of the machine; Fig. 2 is a side view of the cross section; Fig. 3 is a similar view of a drive bar and the trigger members that it controls;

         Fig. 4 is a partial view of the elements preventing the inadvertent drive of the machine; Fig. 5 shows a detail of the coupling between the motor and the mechanism of the machine; Fig. 6 is a side view of the coupling members between a main shaft and a special mechanism operating in the event of a balance reversal; Fig. 7 shows some details of the driving of this special mechanism;

         Fig. 8 is a perspective view of the triggering, driving and control mechanisms; Fig. 9 is a side view of a row of upright keys, a differential mechanism, a printing sector and a section of corresponding totalisers; Fig. 10 shows a detail of a return member for a locking device; Fig. 11 represents the locking of a "Balance" key, when a negative balance appears in the machine;

         Fig. 12 to 14 show certain details of the overturning device for the shaft controlling the overturning operations; Fig. 15 is a side view of the left section of the machine; Fig. 16 is a side view of a mechanism for preventing the engagement of certain totalisers, during the transformation cycle, during a balance reversal;

         Fig. 17 shows a detail of the clutch mechanism of the add-subtract totalizer; Fig. 18 shows members designed to bring the stop pawls to zero in the inactive position; Fig. 19 is a side view of an actuating cam for an auxiliary accumulator; Fig. 20 shows a detail of the clutch device of the latter;

         Fig. 21 is a side view of a mechanism controlled by the "Sub-total credit balance" key; Fig. 22 is a front view of the "Credit Balance" and "Credit Balance Subtotal" keys; Fig. 23 shows the units controlled by the "Balance-arrears" key; Fig. 24 and 25 are details; Fig. 26 is a front view of a set of cams coming into action during the balance reversal;

           Fig. 27 is a side view of the cam actuating the addition-subtraction totalizer during a balance reversal; Fig. 28 is a detail of the credit balance key retainer. Actuation <I> of the machine. </I> - As shown in the drawing, the machine is actuated by a motor (not shown) connected to a driving part 60 (fig. 3 and 5) of a coupling, part mounted loose on a fixed axis 61 on which, moreover, is also mounted a driven part 62 of the coupling.

   The driven part 62 is however maintained in the rest position by a stop lever 63 pivoting at 64 and connected to a control lever 65. A branch directed upwards of the lever 65 ends in a fork engaged with a pin 66 carried by a connecting rod 67 whose right end (fig. 3) is guided on a fixed stud 68, while the left end is articulated to a plate 69 rotating on a shaft 70. A stud 71, carried by a arm 72 itself pivoting at 73, is normally located behind a heel of the plate 69 and thus maintains the stop lever 63 in the active position against the action of a res out 74.



  When pushing in a driving bar 75 guided by studs 77 and 78, a lever 80, connected to the driving bar by a connection constituted by a stud 79 moving in a longitudinal slot, pivots in the senestrorsum direction around a point 77 and in turn rotates, thanks to a pin 81, a lever 82 mounted loosely on the axis 73. The lever 82 comprises two fingers 83, 84 (FIG. 4) between which is engaged a bracket 85 of a slider 86 guided, by means of two longitudinal slots, on the studs of the aforementioned arm 72.

   A small spring 87 is interposed between the cursor 86 and the arm 72 and tends to maintain the square 85 in the position shown, between the fingers 83 and 84, so that the arm 72 is driven in the movement of the lever. 82, when it turns in the dextrorsum direction. During this movement, the pin 71 is moved away from the heel of the plate 69, so that the spring 74 (fig. 3) can tilt the stop lever 63 and disengage it from the shoulder of the driven part 62. The latter is then an action born by the driving part 60. The movement of the stop lever 63 is also intended, as will be seen below, to close the circuit of the electric motor.



  At the driven part 62 of the coupling (fig. 3) is fixed a crank pin 88 connected by a connecting rod 89 to an arm 90 wedged on a main shaft 91. By this means, a revolution of the part 62 in the senestrorsum direction is transformed in an oscillating movement, on approximately 60, of the arm 90 and of the shaft 91. This oscillating movement, first in the senestorsum direction and then in the opposite direction, of the shaft 91, is sufficient for the addition operations , subtraction and for the extractions of totals.

   In these operations, during the last quarter of the revolution, a boss 92 of the crankpin 88 meets a roller 93 carried by a lower extension of the arm 65 and causes the latter, as well as the stop arm 63, to pivot in the direction degtrorsum, so that the end of this lever 63 returns to the path of the shoulder provided on the driven part 62. On the other hand, the heel of the plate 69 acts on the pin 71, so that the arm 72 and the lever 82 return to the normal position, under the action of an arm 49 biased by a spring. The pin 71 maintains the parts in the position shown in FIG. 3, also when the boss 92 has passed the roller 93.

    



  At the moment when the arm 72 and the lever 82 pivot in the senestorsum direction, the lever 80 turns in the dextrorsum direction and returns the driving bar to its rest position. By the return movement of the plate 69 in the dextrorsal direction, its edge 94 acts on a pin 95 (see also fig. 4) of the cursor 86 and brings the square 85 into the recess in the form of a. L formed by fingers 88 and 84.

   Thus, if the drive bar 75 is inadvertently kept pressed at the end of the operation, the arm 72 can be brought back in the senestrôr = sum direction independently of the lever 82 and the pin 71 below the heel of the plate. 69: the machine cannot perform a second revolution.



       Keyboard <I> and differential </I> mechanisms. <I> - </I> The machine described by way of example has a keyboard (fig. 1 and 9) consisting of several rows of upright keys 101, a row of control keys 102 and an addition key . 103. When one pushes in an upright key 101 (fig. 9), a square 105 carried by the stem of the key comes, in the known manner, on the path of a corresponding shoulder 106 provided on a differential member 107. constituted by a rack.

    Each key also carries a pin 115 cooperating with an inclined edge of a hook forming part of a bolt 116 guided between rollers 117. When one of the keys 101 is depressed, the bolt 116 is first moved to the right. against the action of a res comes out 118, then, when the pin 115 has passed the point of the hook, to the left under the action of this spring 118, which is stretched between the bolt 116 and a second bolt 119 also guided between the ga lets 117. The key is now held in its depressed position.

   The pin 115 has, during this downward movement, also cooperated with an inclined edge of a recess of the bolt 119 and has moved the latter to the left: In this movement, the bolt meets a pivoting stop pawl 120 on a rod 121 and swings this pawl in the direction'series-trorsum so as to release the latter from a heel 122 of the rack 107. A spring 123 stretched between the bolt 119 and the pawl 120 maintains the latter in contact with the left end of the bolt.

   When no upright key is depressed, the purpose of the pawl 120 is to retain the heel 122 and hence the rack 107 in the zero position.



  The rack 107 is provided with a vertical slot 124 engaged with a roller 125 carried by a three-branch lever 126 that a spring 128 normally maintains in contact with a transverse bar 129 carried by two arms 130 fixed on a shaft 127 One of the branches of the lever 126 is connected, by a link 131, to a printing sector 58 corresponding to the. row stunned and articulated on an arm 132 mounted madly on a shaft 133.



  When the arm 90 (fig. 3) performs its oscillating movement defined above, its roller 134 slides in a cam track 135 in the shape of a $ (fig. 2) formed in an arm <B> 136 </B> fixed to the shaft 127. The latter therefore also oscillates with the transverse bar 129 (fig. 9), first of all in the senestrorsum direction, to then return to the rest position shown in fig. 9.

   In this movement, the transverse bar 129 drags, by means of the spring 128, all the levers 126 as well as the racks 107 until the latter are stopped by the square 105 of that of the keys 101 which will have been pressed into the row in question. The rotation of the lever 126 is transmitted to the printing segment 58 which then assumes the printing position corresponding to the digit of the pressed key. When the rack 107 is stopped by the square, the transverse bar 129 continues its course by loading the spring 128. On the same axis which carries the roller 134, there is - but on the other side of the arm 90 - another roller 164 (fig. 2 and 8) which cooperates with a gutter 137 formed in an arm 138 fixed on a shaft 139.

   On the latter are fixed two arms 140 (FIG. 9) carrying an alignment knife 141 extending over the entire width of the upright rows. Towards the end of the first displacement of the arm 90, the roller 164 causes the shaft 139 to vote in the dextrorsal direction and the alignment knife 141 engages in a toothing for locking the levers 126, to fix the exact position of the levers. racks 107 and printing segments 58.



  Immediately thereafter, the shaft 133 rotates in order to let the segments 58 strike the paper passed around a cylinder 56. The arm 90 carries a roller 110 (fig. 21) which is normally engaged - except in the reversals. balance - with a notch made in a connecting rod 111 pivoting at 112 on an arm 113 articulated to an arm 114 fixed to the shaft 133. A spring maintains an extension of the arm 113 in contact with the shaft 133.

   When moving in the senestorsum direction of the arm 90, the connecting rod 111 rotates the arms 113 and 114, the shaft 133 and a caliper 160 (fig. 9) in the dextrorsum direction for the purpose of tensioning a spring 161 stretched between the caliper 160 and a pawl 162 attached to each of the arms 132. When the springs 161 are sufficiently stretched, a retaining plate 149 which retains the arms 132, swings to release the latter and lets the springs 161 drive them. sectors 58 for the printing movement.

   The return of the arm 90 to the normal position has the effect of rotating the shaft 133 in the senestorsum direction and a transverse rod 151, carried by the caliper 160, returns the striking arms 132 to their rest position shown in FIG. . 9. On the other hand, the alignment knife 141 is moved away from the teeth and the transverse bar 129 can, on its return. return the jacks 126 and the racks 107 to the initial position. A little before the return of the mesh rings 107, the various bolts 116 are moved to the right to recall the keys 101 pressed.

   The bolts 119 are then also returned to the normal position, so that the zero stop pawls 120 resume. position of fig. 9 in which they retain the racks 107 at the zero position.



  <I> Mechanism </I> addition-subtraction <I> and tota- </I> <I> readers. </I> - The machine shown has several totalizers. In the drawing, we have indicated one addition-subtraction totalizer no. 1 and three addition totalizers no. 2, no. 3, no. 4 (fig. 9). Each rack 107 is provided with two teeth intended to act respectively on the addition-subtraction totalizer No. 1 and on the addition totalizer No. 2. An auxiliary rack 155 is intended for. act on totalizers no.3 and no.4.

        For additions, the pinions of the selected totalizer (s) mesh with the racks 107 and 155 once the latter have completed their first movement to the right - that is to say to the rear of the machine - and remain engaged during the return movement, so that the pins in question rotate by a number of teeth corresponding to the value of the key pressed in the row considered. The pins are disengaged once the racks are back to the initial position.



  For subtractions, the pinions of to talisator no. 1 are engaged with the meshes 107 before their first displacement to the right, so that, during this displacement, the pinions turn in the opposite direction to the previous case. These pinions are disengaged at the end of this movement to the right, before the return of the racks to the initial position.



  For totals extractions, the gears of the selected totalizer are engaged exactly as in the subtractions and rotate, in the opposite direction to that of the additions, until they are stopped by a suitable stop. At this time, the crankshafts 107 and the sectors 58 are stopped at the corresponding position and the amount accumulated in the totalizer in question can be printed by the sectors 58; the totalizer was simultaneously reset to zero.

    In the case of a final total, the pinions are disengaged before the return of the racks 107 and remain at the zero position, while in the case of a subtotal or intermediate total, the pinions remain engaged during this movement. return and are returned to the original position corresponding to the amount already accumulated.



       Clutch <I> of the </I> totalizers. - We will briefly describe the mechanism for clutching and disengaging the totalizers, in particular that of the addition-subtraction totalizer no.1. The axle carrying the pinions no.1 is supported by an oscillating frame consisting of flanges 157 ( fig. 17) and a transverse rod 159, this frame being able to oscillate around an axis 158.

   Each flange 157 is provided with a roller 165 engaged in a cam track 166 formed in an arm <B> 167 </B> fixed, on the other hand, to an arm 169 connected by a connecting rod 170 to a lever 171 ( fig. 15). This lever 171 is mounted idle on a clutch plate 173 fixed on the main shaft 91 and carries, on its hinge pin with the connecting rod 170, a drive pawl 174 held, by a spring 175, in contact. with a stop of the lever 171. An upper extension of the pawl 174 cooperates with a stud 176 carried by an elbow lever 177 pivoting at 178.

   The pin 176 is, on the other hand, engaged with the forked end of a connecting rod 179 (fig. 15 and .16), the lower end of which is articulated to a lever 180 pivo both in 181. On the other branch of the lever 180 is fixed a shoe 182 cooperating with a curved edge 183 of the plate 173.



  When the carriage of. the machine is in the position corresponding to the selection of the addition-subtraction totalizer no. 1, a suitable stop has the effect of lifting the connecting rod 184 (fig. 15) at the lower end of which a pawl 185 is articulated in 186 The pawl 185 therefore swings in the senestorsum direction and is moved away from the path of a heel of the crank lever 177.

   Plate 173 is animated, in addition, subtraction and extraction of totals, with an oscillating movement, first in the degtrorsum direction (Figs. 15 and 16) and then in the opposite direction.

   At the start of the first movement, the curved edge 183, leaving the shoe 182, moves the lever 180, the connecting rod 179 and the angled lever 177, so that the angled lever 177 swings in the senestrorsum direction to move the lever away. stud 176 of the path of the pawl 174 of the pawl. During movement of the plate 173 in the downward direction, the flywheel lever 171 rotates in the senestorsum direction around its pivot point 172 up to. that a square 189 of the plate 1 "13 abuts against the foot 188 of the pawl 174,

   thus forcing the lever 171 to participate as a result of the oscillating movement, in the degtrorsum direction, of the plate 173. This movement of the lever 171 then results, through the intermediary of the connecting rod 170, by the rotation of the arms 169, of the shaft 168 and of the cams 167 which, in their turn, thanks to the cam tracks 166 (fig. 17), produce the engagement of the pinions of the totalizer no. 1 with the cams <B> 107, < / B> but only once they have reached the position corresponding to the key pressed.



  'Once the racks have returned to the initial position, which occurs at the same time as the return movement of the plate 173 in the senestorsum direction (fig. 15), a square 190 of this plate acts on a edge of the lever <B> 171 </B> and lowers, via the connecting rod 170, the arm 169 and the shaft 168 in the dextrorsum direction to disengage the pinions of the totalizer no.1. At the end of the return of the plate 173, the ridge 183 acts on the shoe 182 to return, by the parts described 180, 179, 176, 177, the pawl 185 to its initial position.



  If the carriage is brought into a position which corresponds to the non-addition in the totalizer No. 1, the pawl 185 remains in its locking position and prevents the various movements which have just been described. Therefore, as the plate <B> 173 </B> swings, the square 189 escapes the pawl 174, so that no rigid connection is made between the plate 173 and the lever 171 and the connecting rod 170 does not exert any traction on the clutch arm 169.



  If, instead of the automatic selection by the carriage, the addition key 103 (fig. 1 and 15) is pressed, the pawl 185 is brought, by means not shown but known, to the inactive position, as in the previous case.



       Substraction. - The subtraction key is located in the row of keys 102 (fig. 1 and 15) and its rod has a notch 191 into which a square 192 provided at the end of a small lever 193 pivoting in 194 can enter. press the key, the square 192 engages in the notch under the action of a spring 1.95 and therefore pivots in the dextrorsal direction by driving, through a stud 196, a lever 197 mounted idle also on axis 194.

   The vier <B> 197 </B> ends below with a roller 198 which then acts on an inclined edge of a lever 199 pivoting into 200. <B> It </B> results in the ends of two stop pawls 201 and 202 are brought into the path of the lower branch of lever 171, as shown in phantom in fig. 15.



  At the start of the oscillation in the dextrorsal direction of the plate 173, the end 203 of the lever 171 meets the pawl 201 at the start of the oscillation movement, so that the clutch movement (rotation of the shaft 168 in the senestrorsum direction) occurs before the first displacement of the mesh <B> 107. </B> During this displacement, the pinions rotate in the negative direction by a number of teeth corresponding to the key pressed and the amount dialed on the keyboard is then recorded subtractively in number 1.

   Once the pinions are engaged, the end 203 of the lever 171 escapes the pawl 201 and slides on the pawl 202, as shown in phantom in fig. 15. Once the racks 107 have completed their first movement towards the rear of the machine, the plate 173 already begins to return in the senestorsum direction and, in this movement, the end 203 attacks the pawl 202 from the right. , which makes turn, by the intermediate parts,

   the shaft 168 in the dextror- sum direction to disengage the No. 1 sprockets. Immediately afterwards, the arm 193 (fig. 15) is made to pivot to allow the subtraction key 102 to be recalled under the action of its spring, the lever 197 also returning to the initial position thanks to its res out 211.



  Fig. 11 shows the pinion 204 of the totalizer no. 1, occupying the upper decimal row. As can be seen, this pinion cooperates with an additive transfer pawl 205 and a subtractive transfer pawl 206. In fact, these pawls act on the teeth of a plate 207 integral with the pinion 204. In the subtractions, the additive transfer pawl 205 is moved away from the path of the plate 207 while the subtractive transfer pawl 206 is brought on this. path. A carryover mechanism of this kind is also provided in all decimal rows.



  We have just seen that by pressing the subtraction key 102 (FIG. 15), the lever 197 swings in the dextrorsal direction. This movement is communicated by a connecting rod 208 to an angled lever 209 pivoting at 215 (see also FIG. 8) and a roller 216 of which is then separated from a hook 217 articulated to a lever 218 fixed on a reversing shaft 219. As a result of the lowering of the roller 216, a spring 220 causes the hook 217 to fall, which grips a roller 221 carried by the articulation axis of the connecting rod 170 and of the arm 169.

   When at the start of a subtraction operation, the arm 169 turns in the senestorsum direction, the roller 221 drives: the hook 217 ,. lever 218 and shaft 219 in the dextrorsum direction. until a square 210 of the lever 218 comes to be placed on the path of a heel 222 of a stop pawl 223. The latter pivots freely at 224 and can, under the action of a spring 225 , turn in the dextrorsum direction. so that the heel 222 comes into contact with the square 210 and maintains the lever 218 and the shaft 219 in the inverted position.

   For this position, the projecting part 226 of the shaft 219 (fig. 11) moves away from the jaws 227 of the subtractive transfer pawls 206, so that these pawls can come, under the action of their spring, on the path of the plates 207. If simultaneously, the projecting part 226 has the effect of removing the additional transfer pawls 205.



  Towards the end. of the return movement of the plate 173 (fig. 15) in the senestrorsal direction, a pin 228 carried by this plate that comes into contact with a lever 229 ft voting at 181 and causes it to swing in the dextrorsum direction so that its other branch, terminated by a roller 230, turns the pawl 223 in the senestrorsum direction to move the heel 222 away from the square 210.

   The shaft 219 and the lever <B> 218 </B> can therefore, under the action of a spring 231, resume their normal position of addition in which the square 210 is stopped by the shoulder 232 of the - pawl 223.



  <I> Extraction of the </I> totals. - Totals extraction operations are analogous to subtractions, -with the exception that the amount keys, which could have been pressed inadvertently, are automatically recalled at the start of the operation. In addition, the additive transfer pawls alone remain in the active position.



  When the "Balance" key is pressed in row 102 (fig. 1 and 15), a notch 278 is placed on the path of a bracket 279 provided at the end of a lever 280 pi voting at 281, this lever then tilting in the dextrorsal direction under the action of a spring 282, driving a pin 283 and, consequently, a lever 284 also pivoting at 281.

   A pin 285, disposed at the lower end of lever 284, then acts on an edge of a control lever 286 which also swings in the dextrorsum direction. The lever 286 engages a roller 287 of the subtraction lever 199, so that the pawls 201 and 202 are, as in the previous case, brought on the path of the foot 203 of the lever 171. As in the subtractions, at the beginning of dextrorsum rotation. of the plate 173, the foot 203 meets the stop of the pawl 201, so that a rigid connection is made to produce the clutch of the selected totalizer (number 1 in the particular case) before. departure of.

    racks. During the movement of the latter, on the right according to fig. 9, the pinions 204 turn in the senestrorsum direction (or in the dextrorsum direction according to fig. 14) until; that a tooth of the plate 207 abuts against the transfer nose 205 which stops the pinions and, consequently, the racks and the printing sectors 58 on the figures recorded in the totalizer.

   When the racks 107 have completed their first movement, the foot 203 meets the pawl 202 at the start. of the movement. return of the plate <B> 173 </B> and disengages the pinions 204. The return of the racks therefore has no effect on the pinions which remain at zero. Towards the end of the total operation, the arm 280 (fig. 15) is made to pivot in the senestrorsum direction, so that the lever 284, under the effect of a spring 288, can be brought to the initial position. , releasing the stop pawls 201 and 202. Simultaneously, the "Balance" key is recalled by its own spring.



  If the "Balance" key is pressed at the same time as the "Subtotal" key of the same row, the pieces are arranged so that the arm 280 is tilted to the initial position immediately after the racks 107 have completed their first. movement. Consequently, the pawl 202 is already out of reach of the foot 203 and the pinions 204 remain engaged with the chain rings during the return movement of the latter. It is only after this movement that the pinions are disengaged, by the same means as in the case of an addition.



       <I> balance reversal. </I> - The machine shown allows negative balances to be drawn: or what in accounting is more commonly referred to as a credit balance. This is the case where, for example, a <B> de </B> account holder pays more than his debit. If at this time the balance is drawn, there is a reversal or a credit balance. The you: sateur addition-subtraction then presents the complement of this balance and, in order to be able to print the effective balance, it is necessary to transform this complement into a number readable in clear. In the machine described, either a "Credit balance sub-total" key 331, or a "Credit balance" key 332 is used (fig. 1).

    If any of these keys is pressed, the ma chine performs four continuous operations. In the case of a sub-total, the supplement to the credit balance is, during the first operation, extracted from totalizer no. 1 at the same time as it is additionally transferred to an auxiliary accumulator. During the second round, this complement is extracted from the auxiliary accumulator and re-entered subtractively in the totalizer no. 1 previously reset to zero, so that the latter then contains the actual balance.

   During the third operation, this effective balance is again extracted from totalizer No. 1 and transferred to the auxiliary accumulator so that, in the fourth operation, it can be reintroduced subtractively into totalizer No. 1, which is reset to zero. At the end of the cycle of the four operations, the initial supplement is again in the totalizer. The actual balance is printed during the fourth operation of the cycle, when it is extracted from the auxiliary accumulator.



  If the "Credit balance" key 332 is pressed, a cycle of four operations is also triggered and the first three are exactly the same as in the previous case. On the other hand, during the fourth operation (- ration, the effective balance extracted from the auxiliary accumulator to be printed, is not reintroduced subtractively into No. 1, so that the latter remains at zero.



  The various mechanisms controlled by the keys 331 and 332 will now be described. The "Credit balance" key 332 is guided at its lower part by a pin 333 (fig. 22 and 23) and, towards the middle, by a pin 334. A spring 335 tends to pull the key upwards in the position shown in FIG. 23, wherein a heel is in contact with the underside of the keyboard table 76. The stem of the "Subtotal Credit Balance" key 331 is guided by studs 336 and 337 (Fig. 21) and also engages stud 333.

   A spring 338 normally holds the key up.



  When the keys 331, 332 are in the rest position (raised position), the studs 336 and 337, carried by the key 332, are in contact with the upper ends of the guide slots of the key <B> 331, </ B> so that this, when pressed, always drives key 332.

   On the other hand, the latter can be pressed independently of the other. A plate 339 (fig. 19, 22 and 23) is mounted to the lower part of the key 331 and is guided by the pin 333. This plate is provided with a pin 340 through a longitudinal slot of the key 332 and Also serving as a support pin for a coupling pawl 341.

   A spring 342 (fig. 19 and 22) tends to rotate this pawl in the senestorsum direction to keep a square 343 in engagement with one notch of the key 332. A second pin 344 passes through the plate 339 and on the pin is mounted a sleeve 345 whose diameter is approximately equal to that of. stud 344 (see in particular fig. 22).



  When the key 332 is depressed, the pawl 341 drives the plate 339, and the pin 344 (fig. 22 and 23) meets a pawl 346 pivoting on the pin 333 and causes it to swing in the senestorsum direction, against the action of a spring 347, to move a hook of this pawl away from a bracket 348 provided at the end of a lever 349 pivoting at 70. The lever 349 is connected by a connecting rod 350 to an elbow lever 351 fixed on a shaft 352 (see also fig. 8).

   When the pawl 346 is moved away from the lever 349, a spring 353 rotates the shaft 352 in the dextrorsum direction until a roller 354 carried by the lever 349 is in contact with the periphery of a cam 355. This is part of a set of cams integral with one another (fig. 26) and mounted on a sleeve 356 rotating on an axis 73.

   It will be seen later that the rotation of the shaft 352 in the dextrorsum direction also has the effect of selecting the totalizer No. 1 for a total extraction.



       When an presses the "Creator Balance" key 332, the wafer 339 is pulled down and the sleeve 345 (Fig. 21, 22) meets an extension of a. another pawl 357 normally retaining a bracket 358 of a lever 359 mounted loosely on the shaft 70.

   The lever 359 is thus released and pivots in the dextrorsal direction under the action of a spring 365 until its roller 366- comes into contact with a cam 367 forming part of the aforementioned assembly (fig. 26).

       The lever 359 is connected by a link 368 (fig. 3) to a pin 369 of the lever 80, so that, when rotating in the dextrorsum direction of the lever 359, the lever 80 turns in the opposite direction to put the lever. machine running -in the same way as in the case where the drive bar 75 is used.



  As stated above, the boss 92 of the crankpin 88 (FIG. 3) acts on the roller 93 of the lever 65 at the end of each operation, to return the stop lever 63 to its stop position. In the event of a balance reversal, the machine must perform a cycle of four successive operations. It is therefore necessary to prevent the stud 71 from coming to be placed behind the heel of the plate 69.

   For this reason, when the lever 359 pivots in the dextro @ rsum direction, the latter moves away from a pin 1369 (fig. 3) carried by a pawl 370, the hooked part of which 372 retains, thanks to a res out 371 , the stud 71, when the latter is moved away from the plate 69.



  The lever 359 also carries a pin 373 (fig. 21) engaged in a longitudinal slot of a connecting rod 374 articulated at 375 to the coupling rod 111. If therefore the lever 359 ft votes in the dextrorsum direction, the ac coupling link 111 swings so as to disengage from the roller 110 carried by the arm 90 and to be notched on a frozen stud 376.

   The disengaging of the printing shaft was thus operated during the first three operations of the cycle caused during a balance reversal.

   Towards the end of the third round of the cycle; the lever 359 is returned in the senestrorsal direction by a boss of the cam 367 and a spring 377, stretched between the lever 359 and the connecting rod 374, is thus tensioned and brings the coupling rod 111 back into engagement with the roller 110, so that the printing press is again engaged for the fourth operation of the cycle, operation during which the printing of the effective balance takes place.

   The pivoting in the senestorsum direction of the lever 359 also has the effect of distancing the çliqüet 370 from the pin 71 (fig. 3). However, as the tilting of this cli = quet does not take place until the moment when the bolting 92 leaves the roller 93, the pin 71 returns to its active position only at the end of the fourth operation.



       Actuation <I> of </I> set of cams. </I> - The set of cams shown in fig. 26 is actuated as follows: the pin 337 (Fig. 6), carried by the "Credit balance" key 332, is engaged in a substantially horizontal slot of a coupling pawl 378 articulated to. an arm 379 fixed on the shaft 91.

   This pawl has a notch 380 capable of gripping a pin 381 carried by a slider 382 guided by the shaft 91 and the axis <B> 73. </B> The object of the pawl 378 is to connect this slider 382 with shaft 91., so that at each operation, that is to say four times in the case of a balance reversal, this cursor receives a back and forth movement.



  The slider 382 carries two advancing pawls 383 and 384 (fig. 7) whose pins are engaged in perforations of the slider and which are connected by a spring 385. This res out holds the pawl 383 so that its beak can cooperate with four convenient round-tail shaped notches 386 in one feed ratchet 387, while one tooth of the other pawl 384 is engaged with one of four teeth of a second feed ratchet 389.

   The two ratchets 387 and 389 are separated by a plate 390 (fig. 26) and are both integral with the aforementioned cams 355 and 367, as well as with a cam 391 serving to engage the clutch. auxiliary accumulator.



  When slider 382 moves to the left (fig. 7), pawl 383 advances the cam group approximately 60 in the senestrors.um direction, while on return the tooth of pawl 384 acts as a counter ratchet and complete this rotation of about 30.

   The advance of the group is therefore about 90 for a whole revolution of the main shaft and four turns of the latter are necessary for the group to make one revolution. A resilient pawl 392 prevents backward movement of the ratchets 387, 389. The dovetail-shaped notches of the <B> 387 </B> ratchet are intended to prevent runaway of the cam set when the bosses cams are opposite the rollers carried by the elastic levers 349 and 359.

   A tooth 393, directed downwards (fig. 7), of the pawl 383 serves, in combination with the periphery of the ratchet 387, to separate the pawl 383 from the ratchet, towards the end of the movement towards the left, in order to per put the complementary rotation under the action of the pawl 384.



  The "Credit balance" key 332 (fig. 3) remains pressed until the end of the fourth operation of the cycle. At this moment, it is released and returned by the spring 335. As a result of this return, the coupling pawl 378 releases the stud 381 (fig. 6), so that the slider 382 only operates as long as one of the keys 331 or 332 is pressed.

    In its normal position, the pawl 378 presses by a nose directed downwards against the stud 381 and maintains the cursor 382, so that at rest of the machine the stud 381 is just in front of the notch 380.



  <I> Retainers for the </I> <I>, .Credit balance "and </I>" Subtotal <I> balance cred- </I> <I> <I> editor "keys. </I> - These keys are fitted with brackets 395, 394 (fig. 21, 23 and 28) co-managing with a locking pawl 396 pivoting at 397 under the action of a spring 398.

   If the key 332 is pressed alone, the square 395 only comes to be placed below a heel 399 of the pawl 396, leaving the spring 398 to bring the heel 399 into engagement above the square 395 which prevents the return button. If keys 331 and 332 are pressed together,

      the brackets 394 and 395 come to be placed below the heel 399 which retains the keys in the depressed position. In the event that the "Credit Balance" key 332 is depressed on its own, a stop surface 400 of the pawl 396 further comes to be placed below the bracket 394 to prevent the use of the "Sub- key". total credit balance "331.

    The pawl 396 further comprises a heel 401 (Fig. 21) intended to cooperate with a stud 402 of a pawl 403 (Fig. 25). The latter is mounted on the hinge pin 112 between the coupling rod 111 and the arm 113; a spring 405 normally maintains it in contact with a stud 404 of the arm 113.

    During the. first three operations of the balance reversal cycle, the connecting rod -d'ac coupling 111 is, as we have seen, out of engagement with the arm 90. During these operations, the pawl 403 remains in its normal position , so that the pawl 396 is also locked in the locking position to maintain the keys 331 and 332 in the depressed position.

       Towards the end of the third operation of the cycle, the coupling rod 111 is again engaged with the roller 110 and, at the start of the fourth operation, the connecting rod 111 is lifted so that the pin 402 is placed on the top. above the heel 401 for, during the downward movement of the connecting rod, to tilt the pawl 396 including: the bracket 399 is away from the pressed key (s).



  To maintain the locking pawl 396 in the release position, in the event that one of the keys 331 or 332 was inadvertently held down at the end of the cycle, another pivoting pawl 406 (fig. 23 and 28) was provided. at 334 on the frame and a spring 398 (see also fig. 21) connects to the pawl 396. Under the action of this spring, the upper end of the pawl 406 is in contact with the upper edge of a heel 407 of the pawl 396.

   When the pin 402 of the pawl 403 acts on the shoulder 401 of the pawl 396 and swings the latter in the dextror- sum direction, in the release position, the heel 407 -vent is placed above the pawl 406 which thus prevents the return of the pawl 396 under the action of the spring 398, when the stud 402 exceeds the heel 401 towards the end of the fourth operation, and this until the keys 331 or 332 have been fully recalled.



  When the keys are returned, a pin 408 (fig. 23), carried by the rod of the peat 332, acts on the pawl 406, causes it to pivot in the senestrorsum direction to move it away from the ta-Ion 407. A this moment, the pawl 396 can, under the action of its spring, resume its position of contact with the square 395.

      To prevent the machine from being triggered before the "Credit balance" key 332 is fully depressed and rusty, the articulation pin 375 (fig. 21) between the connecting rod 111 and the connecting rod 374 is engaged in a slot curved formed in a connecting rod 409 whose lower end is articulated to the lever 65. Thus, when the pawl 357 is moved away from the lever 359 and the connecting rod 374 is moved to the right, the upper edge of the connecting rod 409 is brought below a stud 415 carried by a plate 416 integral with the locking pawl 396.

   The stud 415 therefore prevents the upward movement of the connecting rod 409 and; consequently, the release movement of the lever 65, as long as the key 332 is not fully depressed and the pawl 396 has not taken its locking position in the senestorsum direction, because during this movement, the pin 415 is moved away from the connecting rod 409, so that the lever 65 can tilt and trigger the machine.



       <I> control mechanism for the addition-subtraction </I> totalizer. - As we have seen, when the "Credit balance" key 332 (fig. 23) is pressed, the pawl 346 is released from the lever 349, so that the latter, as well as the shaft 352, can turn in the dextrorsal direction according to fig. 23 (in the senestrorsum direction according to fig. 15).

   On the shaft 352 is fixed an arm 417, an edge 418 of which cooperates with a pin 419 of the lever 284, the latter then tilting in the dextrorsum direction (fig. 15) to, as in a previous case, bring clicks 201 and 202 on the path of lever 171 and select totalizer no. 1 for a total take. A lug 420, integral with the arm 417, can act on a pin 421 of the lever 197, to produce the selection of the addition-subtraction totalizer,

       for a subtraction operation. At the start of the first operation of the cycle, the periphery of the cam 355 (Fig. 23) is such, however, that the pin 420 does not yet come into contact with the stud 421.



  The zero stop pawls 120 (fig. 9) are, in the case of a balance reversal ,. Spaced from their locking position in the following way: When lever 286 (fig. 15) turns in the dextrorsum direction, it acts on a pin 323 carried by a lever 307 (fig. 18) which turns in the senestrorsum direction, this which brings another pin 308 of this lever out of the path of the pawl 309 mounted loosely on a cur seur 291. In this case, the action of a spring 301 a. the effect of engaging a notch 316 of the pawl 309 with a roller 317 carried by an arm 318 pivoting at 319.

   Under the action of a spring 322, this arm 318 is in contact with a roller 321 carried by a disc 303 wedged on the main shaft 91. When this disc 303 rotates in the dextrorsum direction, the arm 318 rocks in the same direction and move cursor 291 to the left. An extension of this slider ends with a roller 292 secured in a fork of an arm 293 fixed on a shaft 294.

   On the latter is also pinned an arm 295 including a stud 296 coop @@ re with inclined edges of each of the two bolts 116 and 119 arranged in the rows of upright keys. The displacement of the bolt 119 has the effect, as we have seen, of bringing the corresponding stop pawl 120 to zero in the inactive position. This movement is caused during the four cycles of a credit balance subtotal and only during the first three operations of a credit balance total.

   During the fourth operation, the pawls 120 must naturally also be put in the inactive position, but it is another device - described later - which is used for this purpose.



       The racks 107, moving to the right (fig. 9) turn the pinions of totalizer no. 1 to their zero position, the position at which they are stopped.

   Immediately thereafter, a boss 422) (fig. <B> 19) </B> of the cam 391 acts on rollers 423 of an arm 424 fixed on the shaft 70 which then pivots in the senestrorsum direction. On this shaft are fixed, on the other hand, two arms 425 and 426 (FIG. 20) provided with cam tracks 427 which cooperate with rollers 428 carried by the flanges 429 of a frame pivoting on the shaft 108.

   This frame carries the pinions 430 of the auxiliary accumulator which must be engaged with teeth 431 (fig. 9) attached to the racks 107. By tilting in the senestrorsum direction, the arm 425 (fig. 20) meets, by its stud 432, an alignment knife 433 (fi-. <B> 9) </B> which is thus moved away from the pinions 430 once these are engaged with the chain rings 431.

   Alignment knife 433 pivots on swing frame 429 and is hand held in contact with sprockets 430 by a spring. During the backward movement of the chain rings <B> 107, </B> the pinions 430 (which were at zero) turn in the senestrorsum direction to register the complement of the credit balance, the complement which was previously in the totalizer no.1 .



  Towards the end of the first operation of the cycle, a small diameter portion 434 of the cam 355 (Fig. 23) produces, in cooperation with the rollers 354, a further rotation of the shaft 352 in the dextrorsal direction, so that the lug 420 (fig. 15) acts on the pin 421 and causes the lever 197 to pivot which, as we have seen, engages the totalizer no. 1 on the subtraction. The large diameter part 422 of the cam 391 (fig. 19) keeps the pinions 430 of the auxiliary accumulator in engagement with the racks, during the movement towards the right (fig. 9) of the latter, during of the second operation of the cycle.

         The pinions 430 therefore rotate in the dextrorsum direction until a long tooth abuts against the frame 429 (which corresponds to the zero position) and simultaneously stops the racks.

   The complement of the credit balance is therefore retransmitted to the addition-subtraction totalisaterir, but this time subtractively. Before the racks 107, during the second operation, return to their initial position, the large diameter portion 422 of the cam 391 (fig. 19) leaves the roller 423 allowing a spring 435 (fig. 20) to return them. arms 425 and 426, as well as the shaft 70 in the dextrorsum direction, to disengage the pinions 430 from the auxiliary accumulator of the racks 431.

   Towards the end of the second operation, the cam 355 (fig. 23) returns the shaft 352 in the se- nestrorsum direction, from which the lug 420 (fig. * 15) moves away from the stud 421, but does not prevent moreover the edge 418 to act on the pin 419 and to engage the totalizer no. 1 on a total extraction.



  During the third operation <B> of the </B> cycle, the actual balance is therefore extracted "from totalizer no. 1 - and while the racks 107 are stopped at the square value position; a second boss 436 of the cam 391 (fig.-19) acts on the roller 423 to engage the auxiliary accumulator Consequently, when the racks 107 return, the effective erediting balance is transferred to the auxiliary accumulator.



  During the first operation of a balance reversal cycle, the boss 436 of the cam 391 meets a bracket 437 of the pawl 341 which is thus disengaged from the notch in the key 332, which allows the wafer 339 to move, under the action of spring 342, independently of the "Credit balance" key 332.

   The result is that the pawl 346 (fig. 23) returns under the square 348 of the lever 349, but only when the latter, as well as the shaft 352, are returned in the senestrorsüm direction by a wise bos 438 of the lever. cam 355, towards the end of the third operation. By this rotation of the ar bre 352, the edge 418 (FIG. 15) of the lever 417 is moved away from the stud 419, so that the levers 284 and 286 are able to resume their rest position.

   Consequently, during the fourth operation of the cycle, the addition-subtraction totalizer, which was at zero during the third operation, is not engaged with the racks <B> 107 </B> and remains at zero. The return of the lever 286 has the effect of allowing the lever 307 (fig. 18) to return to its initial position under the action of the spring 310 and. To move the notch 316 of the coupling pawl 309 of the roller 317 away from so that the disc 303 remains without action on the cursor 291 during the fourth operation.



  To bring the stop pawls to zero 120 in the inactive position during the fourth operation of the cycle, in the case of a total credit balance (since it is necessary that the racks can be moved to allow printing) , the following device is used:

    During the third operation - of a total balance-credit, the boss 436 (fig. 19) of the cam 391 acts on the roller 423 and turns the shaft 70 and the arms 425 and 426 in the senestrorsum direction according to the figs. . 8, 19 and 20 and in the direction. dextrorsum according to fig. 18, which engages the pinions of the auxiliary accumulator with the racks 431.

   In this movement of the arm 426 (FIG. 18), an inclined ridge 460 acts on a roller 461 of the lever 307 which then swings in the direction. 'senestror- s.um to engage the notch 316 with the roller 317. During the first part of the fourth operation, the coupling pawl 309 remains in the active position and the slider 291 is pulled to the left according to fig. 18 to act, as described above, on the pawls. stop at zero 120.



  By the upward movement of the plate 339 (fig. 23), the pawl 357 (fig. 21) is also released and hooks below the bracket 358 of the lever 359 when a boss of the cam 367 comes, at the end of the third operation, - to return this lever to the normal position.

   The spring 377 is then tensioned and the roller 373 slides without action in the slot of the connecting rod 374, since the - coupling rod 111 cannot, at this moment, take its active position .-. When ', towards the end of the third operation; the: roller 110 is located opposite the notch of the connecting rod 111, - the spring 377 tends to rotate this connecting rod in the dextrorsum direction to release it from the fixed pin 376 and engage it with the roller 110 The printing unit can therefore operate during the fourth operation.



  The boss 436 of the cam -391 (fig. 19), keeps the auxiliary accumulator engaged during the fourth operation, so that the pinions 430 of this totalizer are set to zero by the racks 107. The value côrltenue'dàns l The auxiliary accumulator, that is to say the effective power, is transmitted to the racks and - to the printing sectors 58.

         (fig. 9), the latter printing this value on the paper passed around the cylinder 56. Once the pinions 430 have been brought to zero, the boss 436 leaves the roller 423 (fig. 19), so that the spring 435 (fig. 20) can return the arms 425, 426 in the dextrorsum direction to disengage the auxiliary accumulator and return the alignment knife 433 to its locking position.

    Returning to its normal position, towards the end of the third operation, the lever 359 (fig. 3 and 21) moves the pawl 370 away from the pin 71, so that the latter can come back to be placed behind the heel of the insert. 69 when the latter, towards the end of the fourth operation, is tilted by the edge 92 of the arm 88. The pivoting of the pawl 370 takes place only when the edge 92 has left the roller 93, so that the machine stops only at the end of the fourth operation.



  During the downward movement of the coupling rod 111 (fig. 21), during the fourth operation, the pin 402 acts on the shoulder 401 of the pawl 396, which moves away from the square 395 (fig. 28. ), which allows the "Credit balance" key 332 to be recalled by its spring. Once the key is recalled, the square 343 of the pawl 341 (Fig. 19) can fall back into the notch of the key 332, so that the wafer 339 is at. again made integral with key 332.



       Subtotal <I> credit balance. - </I> We will now describe the cycle of operations in the case of a sub-total after balance reversal. The only difference between a subtotal and a total is that, during the fourth operation of a subtotal cycle, the addition-subtraction totalizer is engaged on subtraction instead of remaining disengaged, as in the case of 'a total.

   During this fourth operation, the actual credit balance, extracted from the auxiliary accumulator to be printed, is simultaneously recorded subtractively in the addition-subtraction totalizer which thus contains, at the end of the cycle, the complement of the credit balance primarily. found in the machine. When the "Sub-total credit balance" key 331 is pressed (fig. 21), the key 332 is dragged and the pawl 396 hooks above the brackets 394 and 395 to hold the keys. sunken.

   The plate 339 (fig. 19 and 23) acts on the pawls 346 and 357 which, in turn, release the levers 349 and 359 as in the previous case. The subtotal key 331 carries another pawl 439 (FIG. 21) which, under the action of a spring 440, can be hooked under a stud 336. When the key 331 is not. not depressed, a finger 441 of the pawl 439 is in contact with the underside of the table 76 and maintains the hook 439 out of reach of the stud 336, which moreover makes it possible to press the "Credit balance" key 332 independently of key 331.

   On the other hand, when the key 331 is pressed, the finger 441 is moved away from the table 76 and the spring 440 causes the pawl 439 to switch which comes, as we have just said, to catch on the stud 336 in order to connect the two keys 331 and 332.



  The "Credit balance subtotal" key 331 carries a pin 442 (fig. 23 and 27) able to cooperate with an L-shaped recess 443, made in a pawl 444 pi voting at 445. When the sub-total key 331 is not depressed, the hand pin 442 holds, in combination with the vertical portion of the L-shaped recess 443, an extension of the pawl 444 below a small roller 447 of the pawl 346. If therefore the key 331 is not depressed, the pawl 444 cannot act on the pawl 346 which itself operates as described previously for the case of the total.



  By depressing key 331 (subtotal), stud 442 reaches the horizontal part of the L-shaped recess. and a torsion spring 446 causes the pawl 444 to tilt in the senestorsum direction, which causes its extension on the path of the roller 447, in order to prevent the return of the pawl 346 under the action of its spring 347 when the plate 339 traced back.



  As we have just seen, the first three transactions of a subtotal cycle are exactly the same as those of a total credit balance. However, towards the end of the third cycle operation, in the case of the subtotal, the boss 438 of the cam 855 returns the shaft 352 to the normal position and the pawl 346 (which is held inactive by the pawl 444) cannot hold lever 849 in normal position. As a result, this lever swings again in the dextror- sum direction to bring the roller 354 into contact with the cam 355.

   The portion 448 of this cam has the same diameter as the portion 434 and consequently produces a new rotation of the shaft 352, at an angle such that the lug 420 (fig. 15) actuates the lever 197 for bran dear totalizer # 1 on subtraction. The pinions of totalizer no.1 are then engaged at the start of the fourth operation and the amount extracted from the auxiliary accumulator, that is to say the effective balance, is therefore subtracted from zero in the addition-subtraction totalizer which contains now, again, the complement of the credit balance.



  In the last part of the fourth operation of a sub-total, a pin 449 (fig. 23 and 27), carried by the cams 355, acts on an extension 450 of the pawl 444 to tilt the latter in the direction dextrorsum and release the pawl 346. In the shown position of this pawl, the roller 447 prevents the senestrorsum rotation of the pawl 444, under the action of the spring 446, when the pin 449 leaves the extension 450. At the end of the fourth operation, a wise bos 451 of the cam 355 acts on the roller 354 and returns the lever 349 to the normal position.

   The keys are recalled as in the case of a total and the two keys 331 and 332 are disconnected when the finger 441 (fig. 21) of the pawl 439 abuts against the table 76.



  <I> Blocking of the </I> credit <I> balance </I> keys. - In the machine shown, the credit balance keys remain blocked as long as there is no balance reversal. They are only released when the totalizer pinion does not 1, in the upper decimal row, change from "0" to "9", a passage which simultaneously locks the "Balance" key of row 102 ( fig. 1).

   If, following a balance reversal, an amount greater than the "credit balance is added, then the upper gear goes from" 9 "to" 0 "in the positive direction, which blocks the credit balance keys and releases the "Balance" key.

       Since when resetting the add-subtract totalizer, in the case of a positive balance, the upper decimal pinion does not change from "9" to "0" in the positive direction, but returns to zero in the negative direction, the locking device of the "Credit balance" key is not brought into the active position. We will see later that this locking mechanism becomes active by recalling the "Credit balance" key.



  At the end of a credit balance subtotal operation, the complement of this balance is found in the addition-subtraction totalizer and the "Balance" key must be blocked and the "Creditor balance" key must be blocked. unlocked. It is therefore necessary, when the "Sub-total credit balance" key is pressed, to deactivate the device which recalls the locking mechanism by the return of the "Credit balance" key.

   If, during the subtraction, the pin 204 (fig. 11 and 12) of the upper decimal row goes from "0" to "9" in the negative direction, one of the transfer teeth of the plate 207 swings the return pawl 206 in the dextrorsum direction to move the bracket 454 away from the boss of a transfer lever 455 pivoting at 456. At this moment, a spring 457 causes the lever 455 to pivot in the dextrorsum direction until that its foot 458 comes into contact with the caliper 452.



  When the addition-subtraction totalizer is disengaged, the caliper 452 swings in the dextrorsal direction in the position shown in fig. 13, in order to effectively carry out the tens carryovers.

   In this movement, the caliper drives the transfer lever 455 under the action of the spring 4D.7, a heel of this lever at this time raising a bracket 459 of an arm 465 fixed to the reversing shaft of balance 466 which therefore turns in the senestrorsum direction. The shaft 466 carries, on the other hand, an arm 467 (fig. 8, 11 and 15) connected by a connecting rod 468 and a slide 469 to a latch 471 pivoting at 281. The latch 471 comes, by its lower bracket higher 472, engage in a notch 473 of the "Balance" key 102, thus blocking this key against any depression.



  As the balance overturning shaft 466 rotates in the dextrorsum direction (Figs. 2 and 8), an arm 474 moves a connecting rod 475 which in turn causes a locking pawl 476 (Fig. 23) to swing. the heel 477 is moved away from the square 395 of the "Credit balance" key 332. It can therefore be seen that the "Credit balance" key is released at the same time as the "Balance" key is locked.



  In the event that an additional amount is introduced into the previously reversed totalizer No. 1, the balance reversal shaft 466 (fig. 14) is brought back to the normal position, in the known manner, in order to release the "Balance" key. "and lock the" Credit balance "key. Indeed, by the passage of the wheel 204 of the upper decimal row, from "9" to "0" in the positive direction, one of the transfer teeth moves the square 478 apart from the transfer pawl 205, a pro longing of the reset pawl 480, which is in contact, under the action of a spring 481, with the caliper 452.

   When the latter, after disengaging the addition-subtraction totalizer, tilts in the dextrorsum direction, the heel 479 of the pawl 480 meets, under the effect of the spring 481, the square 483 of the arm 465 which returns the shaft 466 to the normal position, which unlocks the "Balance" key and locks the "Credit Balance" key.



  In total credit balance operations in which only a return to zero of the upper decimal pinion occurs, the following mechanism is provided to return the balance reversal shaft 466 to the normal position: pressing the "Credit balance" key 332 (fig. 32 and 24), the square 395 is placed below the heel 485 of a return arm 486 guided, by means of a longitudinal slot, by the stud 397 and maintained normally, by spring clip 487; in the lower position shown in fig. 24.

   As the square 395 moves below the heel 485, a spring 488 swings the arm 486 in the sensory direction, which brings the heel 485 above the heel 395. When, during the fourth operation of a balance reversal, the ratchet. 396 tilts, as has been explained with reference to FIGS. 21 and 28, the spring 335, which is a little stronger than the spring 487, recalls the key 332 and drives the arm 486, as seen in FIG. 23.

   In this movement, a square 489 of the arm 486 causes the pawl 476 to pivot in the senestrous direction and moves it away from the inactive position according to FIG. 24 to bring it into the active position according to fig. 23. The pawl 476 in turn drives the connecting rod 475 and the balance reversal shaft 466 which, as explained above, unlocks the "Balance" key.



  During the operation which immediately follows the balance reversal cycle, the arm 90 pivots in the senestorsum direction and its nose 490 acts on an arron die 491 of the arm 486 which is thus separated from the square 395 The spring <B> 487 </B> returns the arm 486 to the normal position according to fig. 24. When the arm 90 returns to the initial position, in the dextrorsal direction, the spring 488 brings the upper end of the arm 486 back into contact with the square 395.

   When, in the balance reversal cycle, the coins in question assume the position shown in fig. 24, the arm 90 moves the heel 485 away from the square 395 at each operation. However, on the return of the arm 90, the heel 485 has each time placed itself above the square 395 and this also during the last. nth operation of the cycle, before the pivoting of the pawl 396.



  In order that in the credit balance subtotal operations the locking pawl 476 remains in the inactive position of FIG. 24 and that the. "Balance" key remains locked. "Sub-total" button 331 carries a pawl 492 (fig. 21) which. by a spring, is in contact with the guide pin 334. When the key 881 is depressed, the pawl 492 is removed from the pin 334 and can turn in the senestrorsum direction until a nozzle comes into contact with a nipple 493 of arm 486.

    At the moment when the edge 490 of the arm 90 acts, during the first operation of the cycle, on the arm 486, by moving the heel 485 away from the square 395, the stud 493 slides on the hook of the pawl 492 which comes s' hook on this stud to keep the arm 486 out of the path of the square 395. Like the pawl 492, when recalling the keys 331 and 332, the hand holds the heel 485 out of reach of the square 395 until, this that the latter has left the path of the heel 485, the arm 486 is not driven by the key 332 and cannot bring the pawl 476 into the active position. This pawl must therefore remain in the position of FIG. 24.

   When, during the return movement of the key 332, its bracket 395 has moved away from the path of the heel 485, the pawl 492 is released from the stud 493, due to its contact with the stud 334.



  It is sometimes desirable to transfer, into one or more totalizers, the amount that is printed during the credit balance transaction. For the position corresponding to the column where this balance is to be printed, the paper holder includes a selection cursor which is intended to prepare the selection, in addition, of a totalizer, number 2 for example, accumulating new balances. Given. however, as the sum of these new balances must be used for a specific control, it is appropriate to accumulate both positive balances (debit) and additional negative balances (creditors).

   Therefore, totalizer # 2 must be engaged on addition during the first operation of the cycle following a balance remittance (whether total or subtotal) to record the balance complement. But, with the carriage remaining in the same position throughout the cycle of the four operations, totalizer no.2 would be engaged at each of these four operations, if the following mechanism had not been provided to prevent this engagement: When carriage 55 (fig. 2) 'is brought into the "Balance" column, a cursor 510 mounted on a slide 494 lifts a connecting rod 497 (fig. 16), by means of a lever 495 pivoting at 496.

   The connecting rod 497 switches a lever 498 which is located away from a control lever 499, a pin 500 of which cooperates with a nose of the connecting rod 179. During the first operation of the balance reversal cycle, the edge 188 of the plate 173 causes the lever 180 to tilt, when this ridge leaves the shoe 182, which allows the lever 499 to turn in the senestorsum direction under the action of its spring, the pin 500 then being moved away from the upper extension of 'a drive pawl 501.

   As, during the dextrorsum rotation of the plate 173, a square 503 contacts the foot of the pawl 501, a rigid connection is produced between the plate 173 and a connecting rod 504 which produces, via an arm 505 and a shaft 506, the clutch of tota lizer no. 2 with the racks 107, once the latter have completed their first movement towards the rear of the machine. During their return to the front, they communicate to this totalizer the value of the complement of the credit balance, which complement is therefore recorded additively in the totalizer No. 2, which corresponds to the subtraction of the actual balance.



  Towards the end of the first operation of the cycle, the plate 173 returns in the senestrorsum direction, acts on the shoe 182 to move the connecting rod 179 upwards and to reset the control lever 499. As the lever 498 is in the inactive position during the other operations, the clutch movement of the totalizer no. 2 must be prevented during the following three operations. For this purpose, the arm 114 (fig. 2 and 8) fixed to the shaft 133 acts by a pin 507 on a connecting rod 508 articulated to a bracket 509 mounted idle on the shaft 257.

   The other end of the caliper 509 comprises a stud 515 (fig. 8, 15 and 16) engaged in a longitudinal slot of a connecting rod 516 suitably guided on a stud 517. A spring 518, stretched between the stud 515 and the connecting rod 517 normally maintains (fig. 15 and 16) the right end of the longitudinal slot in contact with the pin 515.



  During the first operation of the cycle, the rotation of the plate 173 in the dextrorsum direction produces, as we have seen, a downward movement of the connecting rod 179. By this movement, a pin 519 located at the upper end of this connecting rod 179 is placed on the path of an extension 520 of connecting rod 516. As the coupling rod 111 for the printing unit (fig. 21) is disengaged during the first three operations, of the reversal cycle of balance, neither the shaft 133, nor the arm 114 and consequently the stud 507 move. For this position, an extension 521 (fig. 2 and 8) of the connecting rod 508 is on the path of a pin 522 of the arm 138 which, as seen above, controls the rack alignment knife. 1st 107.

   When, towards the end of the rotation of the arm 90 in the senestrorsum direction, the ga let 164 rotates the arm 138 in the dextrorsum direction, the stud 522 pushes the connecting rod 508 towards the rear of the machine and rotates the machine. bracket 509 in the dextrorsum direction, fig. 8 (in the sense senestrorsum, fig. 1.5 and 16).



       Since at this moment the connecting rod <B> 179 </B> is in its lower position, the pin 51.9 prevents the displacement to the left (fig. 16) of the connecting rod 516, so that the pin 515 does not causes that to slide in the longitudinal slot of this connecting rod, by pulling the res exits 518. At the moment when the plate 173, towards the end of the first operation, returns to the initial position, the connecting rod 179 moves upwards and releases the connecting rod 516 that the spring 518 can pull to the left. The extension 520 is then located below the pin 519 and prevents the tilting of the control lever 499 during the last three operations of the cycle. Totalizer no. 2 therefore remains disengaged during these operations.



  The caliper 509 (fig. 10) is connected to an arm 523 pivoting on the shaft 257 and in contact with a roller 268 of a connecting rod 269, so that this connecting rod is moved to the right when the caliper 509 rocks. in the dextrorsum direction. The connecting rod 269 carries a pin 270 serving as a guide for a pawl 271, a bracket 273 of which is in contact with a notch of the connecting rod 269, thanks to the action of a res out 272.

   When the shaft of the printing unit 133 rotates in the dextrorsum direction, an arm 246 integral with this shaft causes a lever 275 to pivot at 276 by means of a roller 274, and the end of this the sinker 275 slides on the pawl 271, which lends itself elastically, to come to the right of this pawl. When the arm 246 returns, the lever <B> 275 </B> returns the connecting rod 269 to the normal position, as well as the caliper 509 and the associated parts. This rearming takes place only during the fourth operation, since it is only towards the end of the third operation that the print shaft 133 operates.

   An elastic pawl 525, arranged at the. lower part of lever 523, is used for. lock this arm in each of these extreme positions.



  In the machine described, means are provided to prevent operation. when the carriage is not exactly in the desired column. A locking device has therefore also been provided preventing any of the two credit balance keys from being pressed if the carriage is not properly positioned. The carriage being in the position of a given column, the selection cursor 510 (fig. 2) acts by a boss on a lever 528. (fig. 3) connected by a rod 529 to an arm 530 fixed on an axis 531 on which is wedged, on the other hand, an arm 532 engaged with a stud 533 carried by a latch 534. When the connecting rod 529 is lifted, the latch 534 is spaced from a square 536 carried by the release lever 80.

   At this moment. drive bar can be used. On the other hand, if the carriage is not exactly in the desired column, the rod 529 is not raised and the latch 534 remains in the locking position.



  The arm 532 is connected by a spring to. a pawl 539, pivoting at 397, and normally disposed below the square 395 of the "Credit balance" key, preventing this key from being depressed. When the carriage is in the desired column, the rod 529 is lifted as previously described and the arm 532 swings in the senestorsum direction by dragging the pawl 539 which is released from the square 395. Moreover, if the pawl 539 was not foreseen, the keys 331 and 332 could be pressed, without however starting the machine.

 

Claims (1)

CLAIM Accounting machine carrying out balance reversals and in which the complement of a negative balance formed in the addition-subtraction mechanism is, by an uninterrupted cycle of multiple operations, transformed into an effective balance which is printed as a total final or as a subtotal, characterized in that the uninterrupted cycle of multiple operations, necessary for the transformation of the complement and for the printing of the effective negative balance, always comprises the same number of operations, whatever the function executed by the machine, final total or subtotal. SUB-CLAIMS 1 Machine according to claim, characterized in that the operations constituting an uninterrupted cycle are four in number. 2 Machine according to claim and sub-claim 1, wherein the additional balance is transformed into an effective balance by means of the addition-subtraction totalizer and an auxiliary accumulator, characterized in that the effective balance which, during the cycle, is in the addition-subtraction totalizer, is then extracted from the latter, both in total and in sub-total, then transferred to the auxiliary accumulator (430), for. be extracted for printing only in the case of the total, but both for printing and for a subtractive transfer in the add-subtract totalizer, in the case of a subtotal. 3 Machine according to claim, in which the transformation of the <B>. </B> complement of the balance is obtained by means of a set of special cams performing a single revolution during the cycle of multiple operations, characterized in that than the set of special cams (355; 367, 391) is coupled by means of a pawl (378) with a control cursor (382) by means of the same selection member, and this both for a total operation and for an operation of subtotal. .4 Machine according to claim and sub-claim 3, characterized in that, for the transformation of the complement into effective balance, it comprises two selection members constituted by two keys (331, 332), one of which (332) can be used alone, while the other (331) can only be brought into the active position in combination with the first (332). 5 Machine according to claim and sub-claims 3 and 4, characterized in that the rod of the second key (331) is used for printing the credit balance subtotal and is guided by longitudinal slots on studs ( 336, 33'7) carried by the rod of the first key (332), which is used to print the total credit balance. 6 Machine according to claim and sub-claims 3 and 4, wherein the members controlled by the set of cams normally remain remote from the latter, thanks to retaining pawls, and in which said bare rete pawls are tilted into position inactive by pressing the reverse keys. ment balance (331, 332), characterized in that said retaining pawls - (346, 357) are tilted by means of a. plate (339) normally coupled to the credit balance key (332), but which, during the balance reversal cycle, returns to its normal position, independently and before the recall of the credit balance key (332) . 7 Machine according to claim and sub-claims 3, 4 and 6, characterized in that the return of the wafer (339) occurs during the penultimate operation of the cycle, so that members of clutch (349-352, 417, 420) for the addition-subtraction totalizer are kept in the normal position for the last operation of the cycle. 8 Machine according to claim and sub-claims 3, 4, 6 and 7, characterized in that the depression of the credit balance subtotal key (331) prevents, by means of a locking pawl (444) , the retention of said clutch members (349-352, 417, 420) before the start of the last operation of the cycle, so that the addition-subtraction totalizer is subjected, during this last operation, to the action of the corresponding control cam (355). 9 Machine according to claim and sub-claims 3, 4 and 6 to 8, characterized in that said. The locking pawl (444) is held in the inactive position when the creditor balance subtotal key (331) is not depressed, to be released by depressing said key. 10 Machine according to claim and sub-claims 3, 4 and 6 to 9, characterized in that the locking pawl (444) is, when the credit balance subtotal key (331) is pressed, automatically brought into inactive position during the last operation of the cycle, so that one of the retaining pawls (346) can return to its active position. 11 Machine according to claim and sub-claims 3, 4 and 6, characterized in that the triggering of the machine is produced by a mechanism (359, 368, 369) biased by a spring (365) and by the fact that the Depression of the credit balance key (332) is prevented if the cart is not. not exactly in the desired column. 12 Machine according to claim and sub-claims 3, 4 and 5, characterized in that, by pressing the sub-total credit balance key (331), the latter is coupled to the credit balance key ( 332) by means of a coupling pawl (439) and this for both directions of movement. 13 Machine according to claim and sub-claims 3, 4, 5 and 12, characterized in that said coupling pawl (439) is normally retained in the inactive position, that is to say when the subtotal key credit balance (331) is not depressed, by the fact that it is in contact with the underside of the keyboard table (76). 14 Machine according to claim and sub-claims 3, 4, 5, 12 and 13, characterized in that by depressing the credit balance subtotal key (331), the coupling pawl (439) engages under a stud (336) of the credit balance key (332), over which the credit balance subtotal key (331) is guided. 15 Machine according to claim and sub-claims 3 and 4, characterized in that a retaining pawl (396) is provided for the two keys (331, 332), one of which (332) is used for printing. of the total credit balance and the other (331) at the printing of the subtotal credit balance, this pawl engaging either by an edge (399) with brackets (394, 395) of the two keys (331, 332 ) respectively, either by said edge (399) with the square (395) of the credit balance key (332) and by another edge (400) with the square (394) of the credit balance subtotal key (331). 16 Machine according to claim and sub-claims 3, 4 and 15, characterized in that the retaining pawl (396), released during the last operation of the cycle, is maintained in this position by means of a stop pawl (406), when the credit balance key (332) is held down. 17 Machine according to claim and sub-claims 3, 4, 15 and 16, characterized in that the retaining pawl (396) coo father with the stop pawl (406) which is held by means of a stud . (408), in the inactive position by the credit balance key (332), when the latter is in its raised position. 18 Machine according to claim and sub-claims 3, 4 and 15, characterized in that, after releasing release members (357, 359) of the machine, the starting is however prevented if the retaining pawl (396) is not in the active position. 19 Machine according to claim and sub-claims 3, 4, 15 and 18, characterized in that the release of said release members of the machine has the effect of bringing on the path of a stud (415) of the pawl retaining (396) a push rod (409) connected to a stop lever (63) of the engine clutch. 20 Machine according to claim and sub-claims 3 and 4, wherein the remittance of the balance produces the locking of a balance key and the release of a credit balance key, characterized in that the recall of the credit key. credit balance (332) again produces the normal blocking of the balance key. 21 Machine according to claim and sub-claims 3, 4 and 20, characterized in that the return movement of the credit balance key (332) drives a pawl (486) which, in turn, brings into the active position a locking member (476) of this key. 22 Machine according to claim and sub-claims 3, 4, 20 and 21, characterized in that said pawl -. (486) comes, by a bracket (489), into engagement behind an inclined edge of the locking member. (476). 23 Machine according to claim and sub-claims 3, 4, 20 and 21, characterized in that said pawl (486) is released from the credit balance key (332), during the first part of the operation which follows the recall of the credit balance key (332). 24 Machine according to claim and sub-claims 3, 4 and 20 to 23, characterized in that a stop pawl (492) is brought into the active position by depressing a subtotal key credit balance (331), this pawl preventing any connection between the first pawl (486) and the credit balance key (332). 25, Machine according to claim and sub-claims 1 and 2, characterized in that the clutch of the auxiliary accumulator (430) is produced by a mechanism also serving to prepare the release of the stop pawls. to zero (120), during that of the operations in which the addition-subtraction totalizer is engaged neither on total nor on subtraction. 26 Machine according to claim, in which at least one individual totalizer selected by the carriage accumulates the supplement to the credit balance during the reversal cycle, characterized by the fact that this individual totalizer is only engaged during the first operation of the cycle, although the carriage remains in the same position for the entire cycle. 27 Machine according to claim and sub-claim 26, characterized in that, during the first operation of an overturning cycle, a stop member (516, 520) for a driving pawl (501) of the mechanism. The clutch (502-506) of the individual totalizer is brought into an active position from which it is released only during the last operation of the cycle. 28 Machine according to claim and sub-claims 26 and 27, characterized in that the actuating device of the stop member (516, 520) is actuated during the first operation of the cycle, only once a control organ (499) has itself taken its active position. 29 Machine according to claim and sub-claims 26, 27 and 28, characterized in that the stop member (516, 520) is connected to its drive mechanism (509) by means of a spring (518 ) and is maintained in the inactive position by the control unit (499) when the latter comes into the active position. 30 Machine according to claim and sub-claims 26 to 29, characterized in that the drive mechanism (509) of the stop member (516, 520) is held elastically in each of these extreme positions. 31 Machine according to claim and sub-claims 26 to 30, characterized in that the drive mechanism (509) is held in its extreme positions by a pawl (524, 525) biased by a res out.