CH297896A - Accounting machine equipped with recording means. - Google Patents

Description

  

  Accounting machine equipped with recording means. The present invention relates to an accounting machine provided with recording means.



  In one of its particular embodiments, the machine is provided with a number of recording tapes. individual and provided with devices enabling the selection, according to varying needs, of the individual recording tape (s) which should. receive data printing. Her goal is. provide a means of varying the normal selection of printing hammers so as to allow. the machine to adapt easily to new and different accounting systems.



  The accounting machine being, the object (the invention comprises several printing hammers mounted side by side, groups of discs provided with notches capable of being brought into position under the control of control keys in order to co-operate with scanning devices to normally determine which of the printing hammers should operate in correspondence with which control keys are depressed.

   This machine is characterized by at least one additional disk for each group of disks, this additional disk being movable by a device adjustable by hand in order to vary the combination of notches presented to the scanning devices. according to the position given to said device adjustable by hand, so that the normal selection of the printing hammers is changed.



  A preferred embodiment of this machine will be. used for banking work and in particular for the work of their control services, according to which a list is prepared from the various documents which are distributed and where the deposits are verified for the establishment of a control of ba launches at the end of each day.



  The banking supervisory department keeps an exact account of all transactions going through. bank. Usually, these transactions come from daily mail; provincial mail or transit banks, including pools of local banks as well as sums collected or paid by the bank's counters and finally the pools received from provincial banks.



  Many banks require that their lists of checks or amounts paid by another bank be accompanied by a printed slip of checks paved by that bank, when those checks are. return born to the bank on which they are drawn.



  Therefore, to meet this demand and other needs of the bank, one can establish an execution form of the machine which prints individual slips of groups of stations, immediately supplies, to. the day's operations close, precise machine printed results, which printed results are on individual record tapes that can be attached to the various bundles of checks returned to the banks on which those checks are drawn.



  In addition, many banks also desire to keep control documents of the number of days of delay that go to debit from various banks in the banking pool area, outside the local pool area.



  One can provide, for this purpose, an embodiment of the machine which ensures the possibility of varying the selection of recording tapes which are intended for. receive the printed information, so that some bands can. be put at. share and the information kept in the various banks, so that they are debited for their costs. for the number of days of delay which must be counted to them.



  The appended drawing represents, by way of example, an embodiment of the accounting machine which is the subject of the invention.



       Fig. 1 is a schematic view of its keyboard.



       Fig. 2 is. A sectional view of the machine, taken to the right of one of the rows of upright keys, and shows that row along with the corresponding differential mechanism, part of a web selection and a web feed mechanism.



       Fig. 3 is a section of the machine, taken on the. right of the second row of transaction keys, or row 3, and shows the row with associated differential mechanism.



       Fig. 4 shows a detail of a cam device for releasing the selection members from the web feed and a printing hammer selection means for the selection operation and for returning said means to. their normal position after selection.



       Fig. 5 is a sectional view of one of the individual recording tape mechanisms and shows a tape feed mechanism, a printing mechanism and a slide feeding the paper to guide it down and back. so that it is thrown out of the machine from the rear. Fi-. 6 is a detail view showing <B> the </B> triggering. a method of exploring the paper during the operation of the machine.



  Fi-. 7 is a detail view showing one of the printing hammers of one of the bands and part of the selection mechanism therein. associate.



       Fig. 8 is a detail view showing interlocking devices intended to prevent the machine from being triggered when one of the recording tapes breaks and also when one of the recording tapes is withdrawn from said machine.



       Fig. 9 shows, in detail, part of an interlocking mechanism to prevent printing when the machine is turned off at. the. due to the breakage or the need to renew the recording tape.



       Fig. 10 is a view showing two of the means associated with two of the recording tapes, which ensure the locking of the release mechanism of the machine, to prevent the latter from being released when a tape has been withdrawn.



       Fig. 11 schematically shows (only two are visible) a plan view of the recording tape frames.



       Fig. 12 is a plan view of a serving mechanism. to change or vary the selection control of the bands, control obtained by means of keys.



       Fi;% 13 is a side elevation of the same mechanism.



  <U> Fi-. </U> 14 est. a fae-siniilé from an award-winning strip.



       Fig. 15 is a schematic view showing the various groups of control discs which cooperate with. selection of recording tapes for operation.



       Fig. 16 est. a table of control disc groups, showing how these disc groups have notches which are used in the control for the selection of the various selection bands.



  Described in general terms, the machine represented comprises several totalizers in which various amounts can be accumulated or broken down, depending on the accounting systems for which the. machine was built. In the present case, the totalisers are established to receive the various items and many constituents of the current transactions of a bank.



  This machine has a well-equipped control mechanism with internal gears, the purpose of which is to simultaneously register, under the control of the keys, on groups of printing devices, the amounts and the rerisei \, @ nments so that the printing can be done on one of several individual tapes that can. have been selected through the transaction keys command, in order to receive the printing of this data.



  The machine shown is. equipped with ten individual bands framed in movable frames which contain these bands, so that the frames can be easily taken out of the machine to allow paper replacement, if necessary.



  The machine keypad includes the usual rows of upright keys.



  There are three rows of transaction keys for selecting the different totalisers for the distribution of transactions to be recorded and one row of keys for total operations.



  The keys of row 4 (fig. 1) are intended to enter the debits (the various local banks and. Transit banks and also to take note (read the cash collected by the three cashiers. The first key of the row 3 is used to enter the debits of a local bank, the next four keys are for the transit banks, the next key for the cashier's cash and the three lower keys for the accounts of (ledger. At each of the keys N 5 1 and 10 to $ 1 corresponds to an individual record strip on which the amounts debited at the various banks and cash registers will be printed.

    



  Inside the machine, a mechanism controlled by one of these ten keys selects that of the individual bands intended to receive the printing of the amount of the transaction.



  Before these debits are entered, the total amount of a bundle or debit is first entered on the balance totalizer by pressing the corresponding amount keys and the phis key at the top of row 2, when the transaction concerns. a client's account.

   This total amount is carried to the positive side of the scale totalizer, and as each of the various rates is entered into the machine it can be broken down into any one or all of the ten totalizers associated with the first ten tou ches mentioned, that is to say the nine. keys of row 4 and the. top key of row 3, and these individual amounts are. subtracted from the scale totalizer so that when the entry of the various sums of that particular set is complete, the scale totalizer is zero to prove that the total and the entries are correct.



  At the same time as the deposit. a customer has entered this bank verification machine, a deposit receipt, receives a print on the back and on this deposit receipt are indicated all the amounts of the deposit in question.



  Likewise, when a person comes to cash a check at the bank, that check can be inserted into the machine which then prints an amount verifying that of the check.



  When you want the keys. Row 3, 2, 3, 4 or 5 select one of the individual recording bands, just operate a hand adjustable mechanism to vary or change the control of the row 4 keys and the top key row 3, so that the top five keys in row 3 and the top five keys in row 4 can: control the selection of the various individual bands instead of all key keys in row 4 and only. one of the keys in row 3.



  <I> Frame. </I> The main machine frame comprises a left side flange 60 (fig. 2 and 3) and a right side flange (not shown), which are attached to its base 61 and , moreover, reinforce each other by the intermediary of several transverse frames, rods and struts. The base 61 rests and is attached to four printing frames 62, only two of which are visible in FIGS. 2, 3, 5 and. 12.

   These printing frames are held together by tie rods 66 (fig. 2 and. 5) of which only one is visible in this case. The four printing frames rest on the plate of a sub-base 67 (fig. 5).



  The machine itself, as well as its printing mechanism, are. contained in a box 70 (fi; -. 2) provided with the necessary hinged openings to allow access to certain parts of the machine, these openings being fitted with closures to prevent unauthorized persons from gaining access to the internal parts of the machine. .11 drive mechanism.



  The machine is normally operated electrically by a motor and it is. start using one of the mo tric buttons arranged in row 1 or in rows 2, 3 and 4. These buttons and their use will be. explained in detail later.



  When one of these motor keys is lowered, a key locking shaft 71 (fig. 2, 3 and 8) is subjected to the action of a spring, not shown, which turns this. shaft in the dextrorsuin direction to actuate a clutch mechanism which connects the machine motor to a main drive shaft 72 housed in the left side flange 60 and in the side flange (the right.

   The movement (this key lock shaft 71 simultaneously operates a switch mechanism which closes the circuit to the motor, which then drives the main control shaft 72.



  When the machine has completed the desired number (the c @ -cles to complete the kind of operation to be performed, the key lock shaft is returned in the senestorsum direction to release the enibra \ aO, ineanisine, e and at the same time open the electric motor switch. (Vary. 1. The machine keypad is schematically shown in fig. 1.

   At the far left is a row (the <B> 75 </B> keys which are used to control the printing of each desired indication and ten rows of amount keys 76, then three rows of transaction keys 77, 78 and <B> 79 </B> respectively qualified as row 21, row 3 and row 4.



  The total of an elient's deposit is dialed with the amount keys 76 and the plus key in the row? is lowered: the machine completes an operation whereby the deposit total is entered on the scale totalizer and also on the group totalizer.



  It is. then makes a distribution of the various elements composing the total of the deposit which has just been entered, the operator typing in the amount of each coin and lowering those of the appropriate keys among the eighteen transaction keys in rows 3 and 4.

    The transaction keys in row 4 and the. key, top of row 3 transactions, in addition to the selection of totalisers in the usual manner, also control the selection (the bands for special individual lists, as described below, after which the amount of each check is printed on these individual bands.



       A. the far right is the row of totals control called row 1, which has six 80-85 keys. The first four keys of 80-83 are used: to control the machine to extract the totals and sub-totals of the totalizers associated with the keys in rows 3 and 4. Key 84 is provided for the sub-total of the balance totalizer and print the amount of an error to show if this error is a + or - error.

   The 8: 5 key is in the add position and is used with the -19 and -20 keys in row \? and with all the keys in rows 3 and 4.



  The present machine has three groups of totalizers including two addition groups. while the third group carries an addition-subtraction or totalizer (the balance, also known as a cross. The addition totalizers of the different groups and the balance totalizer are selected for engagement with the controls by means of the buttons in rows 2, 3 and 4 (fig. 1).



  The way the transaction keys 77, 7 8 and 79 and the totals keys 80-85 control the operation of the various totalizers is. known and is not described in detail here. <I> Rows of uprights and corresponding </I> differentials.



  Fig. 2 is a cross-sectional view of the machine key taken just to the right of one of the key rows of upright keys; it also shows the associated differential mechanism, which is described. as a key representative specimen all rows.



  The post keys 76 (Fig. 2) are mounted in a key frame 96 supported by key rods 97, 98 which extend between the main frames of the machine. By lowering one of the keys 76, a stop pawl is switched to zero, for the denomination in question, in the senestrorsum direction, which moves it away from the path of a reset claw 100 , which is freely mounted on the hub of an upright differential drive 101 supported and rotatable on a hub 102 which extends between two similar upright differential support plates 103 (only one is.

   visible), which plates are in turn supported by rods 104 and <B> 105 </B> extending between the main frames (the machine. Each of the upright differentials has a pair of support plates 103 and a tie rod 106 extends between the center holes of hubs 102, so as to unite all of the post differentials into a compact whole.



  ['ne slot made at. the front end of the claw 100 engages with a lug of the arm of a release latch 107 capable of pivoting on an extension of a trainer 101 .. The arm 107 and an analogous arm <B> 108 < / B> both support a differential latch 109 for the radial displacement movement. A spring 110 pulls the arms 1.07, 108 and. The latch 109 rearward to normally hold the leg 111 of the latch in place. on a differential pusher 113 supported and able to pivot on the hub of the driver 101. A connecting rod 114, capable of pivoting, connects the pusher 13 to a lever 115 which can pivot 116 on the left plate 103.

   The lever 115 carries rollers 117, 118 which cooperate respectively with the periphery of cams 119, 120 fixed on the main control shaft 72. By lowering. one of the upright keys 76, the end is placed on the path of the rounded surface 121 of an extension, of the arm 1.07.



  For addition operations, the main shaft 72 and. the cams 119, 120 completed feel a revolution in the dextrorsum direction, forcing the lever 115 to tilt the pusher 113 first in the dextrorsum direction and then in the opposite direction so that it returns to its position. normal position. During its first movement, the pusher 113, via the shoulder 112 in association with the foot <B> 1111 </B> of the latch 109; drives in its movement. the latch and the driver 101 in the dextrorsum direction until the rounded edge 121 comes into contact with the rod of the. key down 76.

   At this moment, the arm of the lock 107 pivots, as does the arm 108, in the senestorsum direction to release the foot 111 from the shoulder 112, so as to interrupt the movement. of the driver 101 and to position the latter relative to the lowered button of the uprights 76. The release movement of the latch causes its rounded extension 122 to engage with that of the notches 123 which corresponds to it and made in a plate 124 fixed between the tie rod 104 and the upper extension of the left support plate 103.



  When the latch 109 has been released from the shoulder 112 on the pusher 113, the latter continues its movement in the dextror- sum direction without interruption, which has the effect of bringing an arcuate edge 125 under the foot 111 of the latch. 109, which maintains the extension 122 of the latch 109 in a notch 122 corresponding to the lowered amount key.

   When the lever 115 and the push button 113 reach the. end of their initial movement in the dextrorsum direction, a roller 126 carried by the lever 115 engages with an arcuate edge 127 of the underside of a connecting rod. upright 128, pivoting at 130 on the driver 101 and pushes an upper edge of the connecting rod 128 into contact with the hub of the driver 101 to position the connecting rod 128 in proportion to the lowered upright key 76.



  The connecting rod 128 has a slot 13l which engages with a lug 132 of a connecting rod 1.33, of which. the upper part is articulated to a segment. alignment. 131- mounted on one of the tubes of a series of telescopic tubes 135 supported by a shaft 136 centered in the side frames of the machine. The lower end of the. connecting rod 133 is hinged to. a segment. 137 mounted freely on a 1.38 shaft centered in the side frames of the machine.



  The segment. 137 carries a lug 139 in engagement with a cam slot of a zero elimination cam 140, pivotally mounted at 141 on a free segment gear 1.42 on a shaft 143, which is carried by the side frames. The teeth of segment 142 mesh with the outer teeth of an inner-outer ring gear 1-14, of which the inner teeth are. meshed with a pinion which drives a square shaft.

   The square shaft, in turn, drives similar pinions in mesh with the inner teeth of gears that can be segregated to gear 1.1.1, the outer teeth of these gears being calculated to drive wheels with denomination characters. corresponding in each row of the column printing mechanism, with the aim of (printing it on bands forming the individual lists which will be described later.



  In order to align the differential mechanism and the character wheels which it sets up, each of the segments 13-1 is provided with a series of notches 147 with which a fixed alignment device 1.48 engages. on a tree 149.



  The alignment device 148 is disengaged from the notches 1.47 during the differential positioning of the character wheels and, after they have been brought under the control of the keys and through the differential mechanism, the alignment device is again brought into engagement with notch 147, thus definitively aligning the character wheels.



  The return movement, in the senestrorsum direction, of the pusher 113, causes a ridge 150 to come. engaged with a lug 151 of the trainer 101 which is returned to its normal position. During this movement, the foot 111 of the bolt returns to its normal position above the shoulder 112 of the pusher 113. <I> Totalizers. </I> The machine shown has two groups of addition totalizers of known type, one group 158 being arranged at the rear (or 1V 2) and the other, 159, at the front (or N 3).

    In addition, it includes an addition-self-distraction totalizer or balance totalizer on group 157 (or N l.).



  As is usual in key machines of this type, the coaches 101 are divided into three toothed sectors shown at 160, 161 and 162 in FIG. 2. Sector 160 actuates the addition-subtraction totalizer or balance totalizer of group N 1. Toothed sector 161. actuates totalizers 1.58 of group N 2 and toothed sector 162 actuates totalizers 159 (read group before or N 3.



       In the addition operations, the wheels of the selected totalizer (s), as the case may be, are engaged with their respective sets of control toothed sectors 160, 161 and 1.62, once the drivers 101 have completed their setting movement. in place in the dextrorsunr direction under the control of the upright keys.



  The return movements of the coaches 101 impart a rotational movement to the corresponding wheels of the selected and engaged totalizer (s), in proportion to the. value of the amount keys 76 lowered, to record the correspon ding amount. keys down.



  In operations (subtraction, the corresponding subtraction wheels of balance totalizer 157 are engaged with teeth 160 of driver 101 just as in addition operations and the return movement of the control rotates the addition wheels 157 of the balance totalizer in reverse order.



  When no button of uprights 7 6 of a row (fig-. 2) is. lowered, the pawl. off. at zero 99 remains in the path of the claw 100 and, following the initial movement of this claw imparted by the driver 101, engages the claw and disengages the latch 109 of the pusher 113 to bring the driver to the zero position . After this one has. been set to zero, the roller 126 places la, connecting rod 128, la. connecting rod <B> 133 </B> and segments 134, 137 in position. corresponding, as shown in fig. 2. At the end of any operation, the trainer 101. is always returned to its position as described above.

   However, the connecting rods 133, the alignment segments 134 and the printing mechanisms which they control, remain in the positions acquired at 1a. end of the following machine operations.



  The usual tens carryover mechanism is. provided for negative and positive carryovers from a decimal order to. superior decimal order <B> laughing. </B>



  <I> Keys of </I> transactions.



  Row 2 transaction keys 77 have various features. The No Delay and Delay keys both control the addition of the negative side of the balance key totalizer and the printing of amounts.



  The -19 and - 20 keys both control the addition of the negative side of the scale totalizer and the. -19 key controls addition in one group total, while the - '' 0 key controls addition in another key group total. The release recall key is used to release the Delay and No Delay keys. The lock release key is used to release the machine for operation when an error has been made.

   The + key and the + 79 and + 20 keys all determine the addition on the phis side of the balance totalizer and furthermore the + 19 key determines the addition in the group total, as well as the + 20 key which determines the addition in the total of groups.



  The + 19 and + 20 keys are used to register many varieties of transactions or credits which pass through the machine in the control department. For example, a letter of credit. can. come from a provincial bank; she can. to have gone through the. machine in conjunction with the + 19 or + 20 key, then divided into successive and classified operations as required. But the. key + 20 is used in particular to check the deposit accounts of customers of the bank and the. key + 19 is used for all other types of credits which must be distributed and debited to the various accounts using the keys in rows 3 and 4.



  Here is a key example of the use of key 77 to release the lock. The operator first enters the deposit. total, for example 100 francs, and this deposit. consists of three checks, one for 50 francs and two for 25 francs. For the first operation, the employee registers 100 francs and presses down the + 20 key of row 2, which selects the positive wheels of the addition-subtraction totalizer on group N 1, so that this amount is entered as addition, and at the same time it selects a group totalizer from group N 3. This constitutes an operation.



  The deposit of 100 francs is then distributed. For example, he can. get that two key checks come from. from Local Bank 1 and the other check from Local Bank 2. The next step is for the employee to enter the amount. 50 francs for the 50-franc check and lower the key in row 4 for Bank 1, which triggers the machine. By this, the amount of 50 francs is subtracted. of the scale totalizer and added to the totalizer selected by the Local Bank 1 key of row -1.



  Then, the operator registers the 25 francs and lowers the key. Local bank 1, which causes the 25 francs to be subtracted from the balance totalizer and its addition to the selected totalizer. In the third phase, that is. 25 francs which should be recorded, but it is assumed that the operator makes an error between 26 francs and lowers the key of the local bank 2. This provo que la. subtraction of the 26 francs from the balance totalizer, leaving a balance of 1 franc at the minus side of it. The operator does not know that an error has been made and therefore continues to enter the amount. total. of the deposit. for the next person.

   When the total deposit has been entered on the amounts keypad, the operator lowers it. key -f- 20, in the known manner, but the triggering of the machine is prevented because the balance totalizer is not at zero. As a result, the operator then lowers the. error key 81 which sub-totals the balance totalizer and the amount of 1. franc is, coming from the negative side of this totalizer, printed on the usual verification tape.



  The sum of 1 franc is then entered by the keyboard and it is lowered. row lock release button. 2, in binination wedge with the -i- 20 key of row 2, so that 1 franc is. added to the scale totalizer, which brings it down to zero.



  All keys in rows 3 and 4 and. some of the keys in row 2 are motor keys and trigger the machine when they are lowered to make distributions. The known differential mechanisms associated with these rows of keys are. in principle similar and. it suffices to give a brief description for the row of keys 78.



       Keys 78 (Fig. 3) are supported on a key frame 165 resting on rods 97 and 98. Lowering one of the keys 78 is done. swing a zero stop pawl 166 out of the path of the forward end. a ga iffe 167 pivoting on the hub 168 of a differential arm supported and rotatable on a lug 170 which extends between identical support plates 171 mounted on the rods 104, 105. The claw 167 is provided, on its front end, with a slot engaged with a lug of a pivoting lever 173. on one arm 169.

   This lever 173 is. connected by a connecting rod 175 to. a latch arm 17-1 which pivots on the differential arm 169. The upper end of the arm 174 has a foot 176 cooperating with a shoulder. 172 of a pusher 177 which, with each operation of the machine, performs a movement. regular in the dextrorsal direction then in the opposite direction. A spring 161 maintains. the foot 176 of the latch arm l.74 engaged with the pusher 177.

    This rotates at 170 and is connected by a connecting rod 178 to a lever 179 pivoting at 180 on one of: plates 171. The lever 179 carries rollers <B> 1.81, </B> 182 which respectively cooperate with the periphery of 'a double cam 183, 184 fixed on the main control shaft 72.



  By pressing one of the keys 78, its lower end is brought on the path of a forward extension 185 of the lever 173, whereupon the movement. of the machine drives the cam 183, 181, as previously described, this cam revolving in the dextrorsum direction for an addition and subtraction operation, which causes the lever 1.79 and the pusher 177 to reverse in the dextrorsum direction. . The foot of the lock 176 then drags with it the differential arm 169 and the claw 167 until the extension 185 of the lever 173 comes into contact with the end of the pressed key 78.

   When this movement takes place, the lever 173 is tilted in the senestorsum direction and the connecting rod 175 likewise rotates the arm of the latch 171, the foot 176 of which is <U> disengaged </U> from the shoulder. of the pusher <B> 1.77. </B> L n linked rounded <B> 18.6 </B> of the extension of the. connecting rod 175 engages in a suitable notch of a series of alignment notches 187.

   These notches 187 correspond to the differential positions of the differential of the row of transactions and are cut in a plate 1.88 supported by a key extension of the plate <B> 171. </B> and by the rod 104. The differential mechanism is. thus positioned in relation to the lowered transaction key 78. After the red worm arm 171 has been disengaged from the shoulder 172 of the pusher 177, an arcuate ridge 189 of the periphery of the pusher 177, in cooperation with the sole of the foot 176, locks the latch in the corresponding notch 187 to retain the differential mechanism in its position.



  When the lever 179 approaches the end of its initial movement in the dextror- sum direction, a roller 190 carried by this lever comes together with the inner face 191 of a connecting rod 192, pivotally mounted on the differential arm 169 and forces its arched top edge to. contacting a notched portion of hub 168 to place connecting rod 192 in a corresponding position. to the key (the transactions 78 lowered. The rear end of the connecting rod 192 envelops a lug 19jî of a connecting rod 194 articulated to an alignment segment 195 fixed on superposed sleeves 135 supported by the shaft 136.

   This segment lies. alignment 195 is provided with alignment notches 147 cooperating with the device. 148 alignment described. previously and which is mounted on the shaft 149. This alignment device 148 which aligns the differentials of the amounts also aligns the differentials of the transactions. The connecting rod 194 is also hinged to a print transmission segment 196 attached to the shaft 138. The connecting rod 1.94 transmits the differential position of the connecting rod 192 to the alignment segment. 195 and also to segment 196.

   Segment 195 is connected to a control mechanism which moves the set of wheels of the group N 2 totalizers to select the appropriate totalizer according to the. button 78 which is in line with the corre sponding coaches 1.01, in the known manner.



  The segment 196 (Fig. 3) is connected by a connecting rod 197 to a segment 200 of which. the teeth are meshed with the outer teeth of an external-internal gear 201 similar to. gear 144. Gear 201 is connected for its movement. to the character wheels and indicators of the second row of transactions through its internal teeth in association with drive sprockets mounted on a square shaft and with the other internal-external toothed gears.

      The mechanism just described transfers the differential position of the connecting rod <B> 192 </B> to the character wheels and indicators of the. second row of transactions, and as a result, a symbol characteristic of the lowered transaction key 78 is printed on the tape selected from the individual lists. This differential mechanism also controls, by a means described below, the. selection of different individual recording tapes. <I> Device </I> printing <I> and its </I> command.

    All of the printing mechanism actuating cams are actuated by a printing drive shaft 202 (Figs. 3, 4, 5 and 6) which receives its movement from the main drive shaft 72 in the following manner. Vante: On the shaft 202 is mounted a gear 203 (fig. 3) engaged with a gear 204 mounted on an axis 205 of the base 61. The graining 204 is engaged with a gear 206 mounted on a shaft 207 in axial alignment with the drive shaft 72 of the machine. The ratio of the gears 203, 204 and 206 is such that a revolution of the drive shaft 72 also corresponds to a revolution of the printing drive shaft 202.

   The shaft 207 is, connected to the main shaft 72 by a clutch mechanism (not shown) which operates during the totals printing operations to release the shaft 207 from the main shaft 72 during the first. cycle of this kind of operations. Recording tapes.



  The selection of the ten bands which are controlled by the keys 78, 79 can be changed or varied under the control of two differentially adjustable members, in a manner which will be described later.



  These bands are mounted on the front of the machine, from which they can. be removed to allow easy replacement of the paper roll when it is. out of print. Plus, banks can. obtain, when they need them for replacements, frames containing a new supply of strips of paper.



  Part of these bands and part of the frames which support them are shown schematically in FIG. 11, as well as a section of one of the frames in fig. 5. In addition, a portion of one of the printing bands with the printed data is shown in fig. 14.



  The reference number 212 is given to all the individual bands, since the frames are all the same and the mechanism for operating the hammers on the bands, as well as the mechanism for feeding them, are similar for each of them. -this. The ten frames for individual bands are. supported by a plate 213 (fig. 5 and 10) fixed to the bottoms of the printing frames 62 of the machine. On top of the plate 213 are fixed ten U-shaped guides 214, one for each of the individual frames, which guides have side edges 215 including the object. will be explained later.

    By referring. in fig. 5 and 1.1, we see that each of the print frames is. com posed of side plates 216, 217 joined together seemingly near their lower edges by rods 218, 220 and near their upper edges by rods 221, 222_, 223 and, 224. Ires rods 218, 220 rest on top flanges 215, and lugs 225, one in each of the plates 216, 217, pass. under these ledges. The plates 216, 217 are also for views of flanges 226 which pass under the re edges 215.



  Consequently, the band frame is protected against lateral movement as well as against anything. upward movement, the flanges 226 preventing movement. lateral and also opposing any movement of the frame which would tend to lift it. In 230 (fig. 5) of the. plate 217 pivots a latch 231 biased by a spring. and provided with a spout 232 intended to hook onto the rod 66 when the frame is. in operating position.



  To remove the frame from the machine, the operator simply lowers the front end. lock 231 to release spout 232 from rod 66, after which the entire frame can be removed from the machine.



  The strip feed 212 is provided by a feed roller 233 (FIG. 5) from which the strip passes over rollers 234 mounted on the rods 221 and. 223 then around a rod 222, on a knurled supply roller 235 mounted on the. rod 224 and under a knurled tension roller 236, carried by a lever 237 which pivots at 238 on the side plate 217 and held in contact with the strip of paper by spring. 239. The strip of paper 212 is then passed over a guide plate 240 and under a saw plate 241 whose function is to allow the strip to be detached by the operator when the list of checks has been completed.



       When the strip 212 is not loosened, it is passed between the plate 240 and the saw blade 241 through the hole of a cover 242 which extends downward and rearward under the sub- bases 67, at the back of the machine.



  The cover 242 is held in position by a latch 243 actuated by a spring engaged with a lug 244 which the guides 214 carry.



  When he. Desires to detach the strip 212, the operator grasps the handle or button 2-15 at the top front of the cover 2-12 and advances it, which releases the paper between the plate. saw 2-11 and the top of the cover, thereby allowing the strip of paper 212, of the. detach and remove it from the cover 242. The bottom and the rear parts of this cover are supported between the guides 246 (fig. 5).



       hzterrlocking between <I> the </I> frames <I> to </I> bands <I> and </I> <I> the </I> mechanism <I> of </I> décleiicheiiieiit <I> de the </I> machine. An interlocking mechanism is provided to ensure that all web frames are locked in their desired position before the machine is released for operation.



  This mechanism is shown in particular in FIGS. 8 and 10 and partly in FIG. 5. A slide 250 can slide through slots 251 and lugs 252 in each of the U-shaped guides 21.1. A spring 235, connected to the slider 250 and to a pin of the guide 211, maintains the slider 250 in the position indicated in FIG. 10, when the tape frame is removed from the machine. Each slide 0 is. provided with a raised edge 254.



  Swiveling on a rod 255 carried by the frames to. bands 216. 217 is found a lever 256 connected by a slot and lug 257 to a lever 258 itself rotating on a rod 259 which also rests on these frames. The lever 258 carries a finger. 249, which, when the frame is placed in the machine, comes into contact with the raised edge 254 of the slide 250 and pushes the latter rearwardly from the position of FIG. 10 to that of fig. 8, which brings the lugs 252 to the front end of the slots 251.



  The lever 258 has an arm 260 which, when the frame is slid into the machine and locked in its normal operating position, engages a lug <B> 261 </B> of a lever 262 pivoted on a rod 263 carried by the printing frames and place this lever 262 in the position indicated in fig. 8, in opposition to the tension of a spring 261.



  For each of the band frames there is a lever 262 which cooperates with the arm 260 of their respective frame. The lever 262 carries a lug 265 which normally is in contact with the upper edge of an arm 266 fixed on a shaft 267 carried by the printing frames. Each of the levers 262 corresponds to an arm 266 fixed to a shaft 267. These arms are all kept in contact with their respective lugs 265 by means of a spring 268 attached to an arm 269 which is. also fixed on shaft 267.



  Also set at. the shaft 267 is an arm 270 provided with a lug 271., which is normally in contact with the underside of a finger 272 of a lever 273 pivoted at 274 on one of the printing frames. A spring 275 maintains normally. the. lower faee of finger 272 in contact. with the lug 271 of the arm 270.



  The upper end of the lever 73 rests normally to the left of the flange 280 of a lever 281 mounted on a shaft 282 supported by the frames of the machine. Hinged to lever 281, a connecting rod 283 is. connected to an arm 284 fixed to a shaft 285 supported by the frames of the machine. The shaft 285 also carries an arm 286 provided with a lug 287. Mounted loose on the shaft 285 is an arm 288 maintained in contact. with the lug 287 by a spring. This arm 288 is. connected by a connecting rod 290 to a plate 291 fixed to the worm shaft of the keys 77.



  The arm 286 carries a finger 292 which is in contact with a transverse bar 293 of the machine to maintain the members in their normal position.



  The mechanism described. works as follows: When the machine is. triggered in the manner previously described., the worm shaft of the keys 71 rotates in the dextrorsum direction (fig. 8), whereupon the connecting rod 290 rotates the arm 286 in the same direction, bringing the arm 284, by through the connecting rod 280, to tilt the lever 281 always in the same direction, so that the edge 280 is. moved down and to the right of the upper end of lever 273.



  The dextrorsal movement of lever 281 can occur freely when all of the individual frames have. been inserted and locked in their normal position in the machine, ready for selection and operation.



  However, in the event that one of the banded frames is not completely locked in position or if it is not at all in the machine, the corresponding lug 261 does not encounter any obstacle and the spring 264 does tilting lever 262 in the dextrorsum direction, the lug 265 rotating the associated arm 266 and shaft 267 in the senestorsum direction, which rocks the arm 270 and moves the lug <B> 271. </B> down away from the underside of the finger. 272 of lever 273.



  As the lug 271 is moved down, the spring 275 rocks the lever 273 dextrorsum, thereby placing the upper end of it just below the r edge 280 of the lever <B> 281 < / B> and it follows that this cannot be moved in the dextrorsum direction. Therefore, the connecting rod 283, the arm 284 and the entire related mechanism. the plate <B> 291. </B> included, are maintained in their normal position of fig. 8, thus preventing the machine from being triggered.

           Control <I> of </I> déeleizehewaeïi.t by <I> the </I> individual bands.



       Assuming all tape frames are in their correct position and. locked on the machine, each band, by a means which will be described, exerts a control on the shaft 71 of the release of the machine.



  As long as the bands are all properly inserted into each of their frames and they are. in the normal position, the key locking shaft 71 can tilt in the dextrorsum direction to release the machine. But if one of the individual bands 212 breaks or the paper supply is exhausted, the absence of a band opposes this movement of the shaft 71 and 1a. machine cannot. be triggered.



  Leaving. of the feed roller, the strip 212 passes behind a plate 301 (fig. 5 and 8) supported by the frames 216 and 217. This plate 301 carries a hole 302 and, opposite this hole and in contact with the strip 212 , there is a rim 303 integral with the lever 256 mentioned above. This flange 303 is normally held against the strip 212 in the position indicated in wire. 5, 6 and 8 by the pressure exerted by the spring 253 on the levers 258 and 256.



  If the strip breaks, the flange 303 enters the hole 302 and the lever 256 is pivoted in the senestorsum direction by the pressure of the spring 253, the flange 254 acting. through the finger 249 to rock the lever 258 in the dextrorsum direction and move down the arm 260 of the erl-ot 261 carried by the lever 262, which allows the res out 264 to rotate the lever 262 in the dextrorsum direction and, consequently, the arm 266, the shaft 267 and the arm 270 in the opposite direction.

   In this way, the pin 271 is. lowered and the spring 275 rocks the lever 273 in the dextrorsuin direction and comes to place its upper end directly under the flange 280 of the lever 281, thus blocking any movement of the key locking shaft 71. As a result, the machine does not can be triggered when one of the individual webs 212 is broken or when the feed roll is exhausted and there is no paper in front of port 302.



  Of course, while the web 212 is fed by means which will be described later, it is desirable to move the approaching edge 303 away from the tape to avoid rubbing.



  The device used to move the approach edge 303 away from the. band 212 during supply consists of a double cam 304, 305 (fig. 6) threaded on the printing control shaft 202. This cam cooperates with rollers 306, 307 respectively, carried by a lever 308 connected by a hub 309 with one arm 310 which pivots on a shaft 311 supported in the printing press. A connecting rod 312 connects the arm 310 to another arm 318 fixed on the shaft 263. The latter also carries several fingers 319 arranged to be in contact with an er-ot 320 of each of the levers 256.

      The movement of the cams 301 and 305 is adjusted such that when the individual bands 212 are advanced, the connecting rod 312 is moved to the right, doing so. thus down move the arm 318, the shaft 263 and all the fingers 319 in the senestrorstim direction until the fingers 319 engage with the lugs 320 and tilt all the levers 256 in the dextrorsum direction to move the edges apart. exploration 303 of each band 212.

   When the advancement is completed, the cams 304, 305 return. the fingers in the position shown, on which the levers 256 repreiiiient their position indicated in fig. : 5, 6 and 8.



       Mée # nisme cl'avancey) ient <I>de<B>la</B> </I> band. Swivel. on the. rod 224 (fig. 5) is an arm 333 carrying an advancing pawl 334 pushed by a spring and cooperating with a ratchet 332. The arm 333 is articulated, by a lug and slot connection 335, a supporting rod 336 sliding through a slot 337 on a lug 338 which is on the frame with individual bands 217. A res out 339 pulls on the. connecting rod 336 so that the right-hand end of the slot 337 makes contact with the lug 338 when the members are in their normal position.

   A stopper ratchet 340, supported by the frame 217, cooperates with the ratchet 332 to prevent any recoil movement.



  The connecting rod 336 carries a lug 341 which, under normal circumstances, is not connected to a slot 342 made in the front end of a connecting rod 343 articulated at 344 on an arm 345 fixed on an arm 346, which is supported by the printing frames 62. A connecting rod 347 (fig. <B> 2) </B> connects the arm 345 to a lever 348 pivoted on both the shaft 311, and carrying rollers 350 and 357 which cooperate with cams 352, 353 respectively fixed to the print drive shaft 202. When one of the individual bands is selected to operate, as will be described later, the corresponding connecting rod 3-13 can swing freely.

    in the senestrorsum direction on the pivot 344, so that the notch 342 engages with the lug 3.11. When this engagement is established and during one revolution of the machine, the cams 352, 353 swing the arm 345 first in the dextrorsal direction, then in the opposite direction, to return it to its normal position.

   This movement. of arm 345 moves connecting rod 336 to the right (fig. 5), which rocks arm 333 and causes pawl 334 to rotate ratchet 332 and feed roller 235 to move web 212 after the impression was made there. This im pression is. carried out by means of character wheels 355 which are put in place and actuated by means of the internal gear 144 (fig. 2) under the control of the upright keys 76 to the.

   known manner, after which the printing members described later are actuated to produce an impression of the character wheels 35 :) on the selected strip 212. Only a pair of cams 352, 353, a lever are provided. 348 and a link 347 for all of the individual bands 212. However, the arm 345 repeats for each band used on the machine.



  When a given band has been selected, the connecting rod 343 rotates in the senestror- sum direction by an arm 356 which is selectively controlled to tilt in the secestorsum direction. This arm 356 carries a lug 357 engaged with a slot 358 of the connecting rod 343.



  The arm 356 pivots on a shaft 359 supported by the printing frames and is secured to a hub 360 (fig. 5 and 7) to which an arm 361 is also attached. The latter carries a finger 362, normally held against. a lug 363 of an arm 364 (FIG. 2) fixed to the shaft 359. Arms 356, 361, 364 are provided for each strip.



  In the normal position of the components, the lug 363, by its contact with the finger 362, maintains the arms 361, 356 in the positions indicated in FIG. 2 and 5, so that the lug 357 keeps the notch 342 of the connecting rod 343 out of engagement with. the lug 341 of the advancement rod 336.



  At the appropriate time, during operation, the shaft 359 and the arms 364 rotate first in the senestorsum direction and then in the opposite direction to their normal position. During the first of these movements, the arms 356 are, by a means described below, selectively lowered by means of springs 365, which is due to the fact that the lugs 363 are separated from the fingers 362. The arms 356 cause the vote to be taken. in the same way the connecting rods 343 by means of the lug-slot connections.



  To rotate the shaft 359, the latter carries an arm 370 (fig. 4) _ connected by a connecting rod 371 to an elbow lever 372 which carries rollers 373, 374 cooperating with cams 375, 376 fixed to the shaft. print control 202.



  The dextrorsal movement of this shaft and of the cams 375, 376, as a result of the movement which has just been described, causes the arm 370 and, consequently, the shaft 359 and the arms 36-1, to tilt, first in the senestrorsum direction to release the pins 363 of the fingers 362, then in the opposite direction to return the organs to their normal position.



  <I> Printing device </I> <I> for individual </I> tapes. A printing hammer is. associated with each of the individual bands to perform printing using type wheels 355 (Figs. 2 and 5). A mechanism operates and controls these hammers.



  Each printing hammer 381 (fig. 5 and 7) is capable of pivoting on a rod 382 supported by the printing frames 62. The hammer 381 is connected by a connecting rod <B> 383 </B> to a lever 384 pivoted on the shaft 263 mentioned above. The lever 384 carries a finger 385 normally held against the spacer 66 of the printing frame by the weight of the hammer, so as to hold the latter in its normal position for which it is located below the rollers 234 of the frame. tape, so that it does not interfere when removing the frame. This lever 384 carries a lug 386 cooperating with a notch 387 of a connecting rod 388 articulated to an arm 389 fixed to the shaft 311.

   For each of the hammers 381, there is provided a lever 384, a connecting rod 388 and an arm 389.



  To cause printing with the hammers 381, the arms 389 are tilted first in the dextrorsum direction, then in the opposite direction, by means of a lever 390 (FIG. 5) bearing. rollers 391, 392 which cooperate with a double cam 393, 394 fixed on the printing control shaft 202.



  The cam 393, 394, via the lever 390, rotates the arms 389 first in the dextrorsal direction, then in the opposite direction, until. their normal position. Before the execution of this movement of the arms 389, a finger 397 of each of the arms 319 (FIG. 6) comes into contact, while it is tilted, with a lug. 398 placed on the corresponding arm 384. and rotates it in the senestrorsum direction to move the lug 386 away from below the notch 387 of the connecting rod 388.

   Once the pin has been put in position; the connecting rod 388 which has been selected pivots in the sec- nestrorsum direction on the arm 389, so that the notch 387 engages the lug and a dextrorsum movement of the arm 389 to its normal position causes the lever 384 either. tumbled in the senestorsum direction, thereby forcing the connecting rod 383 to rock the hammer 381 to print on the web with the character wheel 355. After printing, the fingers 399 of the arms 319 return the arms 384 to their position normal of fig. 5.



  A 395 link is. connected to each of the connecting rods 388 as well as to the corresponding arm 361, which is tilted in the senestror- sum direction by the spring 365 when the lug 363 is released from the finger. 362. By means described later, this arm 361 rotates by selective control, so that only the connecting rod 388 which is selected to print on the selected web 212 is lowered to engage with the lug 386.



  In the event that a strip 212 breaks or the supply roll is depleted after the machine has been tripped and before the hammer 381 operates, a ledge 395 (fig. 9) is pushed under a ridge. 396 (the arm 356 when the lever 262 is tilted in the manner described above, which prevents any senestrorsal movement of the arms 356 and <B> 361. </B>



  Therefore, under these conditions, neither a hammer nor a web feeder can be selected. <I> Selection </I> device <I> (the </I> bands.



  The device used to select which of the ten individual hammers should. function and the belt advancement mechanism is controlled by the keys of rows 1, 2, 3 and. 4 shown in FIG. 1.

   In addition, several differentially adjustable members by hand are liable, when they are set to certain positions, to vary the control of the selection of the individual bands, control depending on the keys (rows 1, 2, 3 and 4. selection of the bands for printing and for advancement, ten groups of selection disks are provided, provided with notches which can be placed differentially under the control of the keys of rows 1, 2, 3 and 4 .

         In addition, to vary this command using the keys, there are two additional disks in each of the groups. These additional disks can. be placed differently. under the control of several differentially adjustable organs by hand and which are. described later.



  The ten selective disk groups for the ten individual list tapes are shown schematically. in fig. 15, each disk group being indicated by the tape number that the group controls. Some have six drive disks and others have only five, as we can see. by fig. 15 and also by the table of fig. <B> 16. </B> Positioning.

   of these discs is made, for all, by means of a drive mechanism by internal-external toothing of a well-known type.



  The drive of this gear mechanism is shown in FIG. 3 in relation to keys 78 of row 3.



       Since the drive between the differential and the gear mechanism for the other rows of gears, namely rows 1, 2 and 4, is approximately the same as that shown in fig. 3 for row 3, it suffices to describe the latter.



  The shaft 138 (fig. 3) and the segment 196 being put in a differential position by the key differential ineanism in this figure under the control of the keys 78 of row 3, the differential movement called segment 196, as well as that a. previously described, the connecting rod <B> 197, </B> is transferred to the segment 200 and to the shaft 1-13, to which is also attached a graining segment 412 engaged with a gear 413 turning. on a rod 414.

   Attached to gear 413 is a gear 415 meshing with an internally-externally toothed gear 416 which drives a pinion 417 attached to a square shaft 418. On the latter is mounted a series of pinions 417 which drive pinions (not shown) but which, like the gear 416, cooperate with each of the key selection discs N 3 (FIG. 15) corresponding to each of the ten individual bands.



  In this way, when the selection disc N 3 to polish one of the bands is selected, all the discs N 3 for each of the other bands are simultaneously selected and put in the next differential position. the key key 78 of row 3 which has been lowered.



  Fig. 3 shows the shafts 420, 421, 422, 423 and 424 which are put into differential position by means of internal-external toothed gears 416 and pinions 417, under the control of rows 1, 3 and 4 and of the two members adjustable by hand described later. Thus, all the disks shown in fig. 15 are put in differential positions according to the keys of rows 1 to 4 which have been lowered and following. the. irise in hand position of the manual differential organ.



  The disks of fig. 15 are numbered according to the disks which cooperate with the various bands and hammers shown in the table of FIG. 16.



  Each disc has defined positions, designated from A0 to A9 inclusive and from BO to B9 inclusive, on which positions of the notches can be notched for the different selections. The disc N 1, shown at the left end at the bottom of fig. 16, is provided with notches at positions BO to. B6 only, because in row 1 it Wy has only six keys and a zero position.



  The arm 361 (FIG. 7) carries a finger 425 which is normally located opposite the position BO of the disc N 1. We have already seen that the arm 356 is integral with the arm 361 and. carries a sensitive or explorer finger 426 (fig. 5 and, 16) provided with a nozzle 427 which, normally, is located opposite the position BO of all the discs 2, 3, 4, 7 and 8, and another nozzle 428 which, normally, is opposite the position E10 of all these discs.



  When disks 1, 2, 3, 4, 7 and 8 have. been placed in a differential position and that a notch is in front of the spout 425 of the arm 361 and also of the spout 427 of the finger. .126, then when the shaft 359 has rotated in the secestorsum direction in the manner previously described, the two arms 356 and 361 rotate in the same direction under the action of the spring. 365 to couple the connecting rod 343 and. the ergot. of the web advancement rod 336 and also for coupling the connecting rod 388 with the lug 386 of the hammer operating lever 384.

   Consequently, this connecting rod 336 advances the web 212 and actuates the corresponding hammer 381, to produce a readable impression on the strip thus selected, by means of the character wheels 355.



  According to the table in, fig. 1.6, we notice that only the Delay and No delay keys 77 of row 2 and the zero position of this row 2 control the N 2 disks associated with each of the individual bands 212. Regarding the N 1 disk which is controlled by the keys of row 1, it is noted that in positions B0, Bl, B3, B4, B5, B6 a notch is provided on the disks associated with the ten bands 212.

   The corresponding N 3 disk. to bands Nos. 1 to 5 has a notch cut at position A9 for band N 1 and at position. A0 for bands Nos 2 to 5, and on side B a notch in positions 8, 7, 6 and 5 relating to bands 2, 3, 4 and 5 respectively. The group of discs N 4 ordered by row 4 corresponds only to the bands Nos 2 to 10 inclusive.



  On side A of each of the selection discs there is a notch on positions 1 to 9 respectively of these nine discs and on side B there is a notch on positions 0 of the four discs associated with bands 2 to 5 inclusive, as well as 'at positions 7, 8 and 9 of the disks corresponding to bands 8, 9 and 10 respectively.



  From the above description, it can be seen that if the operator wishes to select the. individual band corresponding to the local bank 6 which is on key N 1 at the ninth position of row N 3, he can press this key and the corresponding finger 428 will enter the notch of all the disks N 3 which, as explained above, are. controlled by keys 78 of this row 3. Since no other key is lowered and since all disks Nos 1 and. 2 have notches in positions 0 on their side B, the exploration finger 428 can enter the notch N 9 of the disc N 3.

   Therefore, the band N 1 selected by the key N 1 of the ninth position of. row 3 will be advanced and will receive an impression under the action of the corresponding 381 hammer. <I> Order of. Individual </I> <I> band selection device for </I> -raring <I> this </I> selection. Normally, key 1 of the ninth position of row N 3 and keys 10 to 18 of the. ninth to. the first position of row N 4 select the ten individual list bands.



  It is often desirable to modify this selection so as to be able to have other keys available to control the. band selection.



  For example, arrangements are made for keys 1 to. : 5 of row 3 and keys 1.0 to 14 of row 4 then select the individual bands and prevent keys 15 to. 18 of row 4 to select bands. Likewise, keys 1, 2 and 3 of row 3 and keys 10 to 16 of row 4 can select the ten individual bands: keys 1 and 2 of row 3 and keys 10 to 17 of row 4 can select bands; the N 1 key of the. row 3 as well as all the keys of row 4 can control the band selection.



  The device for varying the control of the individual bands by the keys of rows 3 and 4 is, as follows-. A lug -141 (fig. 12 and. 13) of the printing frame 62 carries a knurled wheel 4-12 adjustable to. the hand and provided with a moZ'eu -143 on which are engraved. characters 0 to 5. At the moveu 443 is fixed a gear 444 meshing with a gear 445 mounted on an axis 446 of the printing frame 62.

   The gear 445 is integral with a gear 447 engaged with a 1st gear rack. slide on rollers 449, 450 respectively supported by rods 451 and 4 <U> 5 </U> 9.



  Spacer and guide discs -153 are mounted on each side of the gear 447 on the axis 446, to keep the 1st rack .148 in correct alignment with the gear -1.17. This rack 448 is. meshed with a gear at. internal-external toothing 460, which drives a pinion 461 mounted on the cante shaft 423 (fig. 3) which, as indicated previously, drives all the selection discs N 7, one of which is associated with each of the ten bands individual.



  To the internal-external toothed gear 460 is fixed an alignment disc 462 cooperating with a pawl 463 urged by a res out and rotating, on a lug 464 of the printing frame. The notches made in the disc 46'21 are profiled such that the pawl. 463 engages with them whenever the rack 448 is adjusted either forward or backward to the left or to the right, as shown in fig. 13.



  It can be seen, from the above, that whenever the. 4-12 knurled wheel, differentially adjustable, is adjusted in accordance with its. zero position on any of its other positions 1 to 5, la. rack 448 is at the same time positioned and that, by means of the internal-external toothed gear 460 and of the pinion 461, the shaft 4'23 is also adjusted to the same degree to put each of the discs in position. selection N ^ 7 (fig. <B> 15) </B> corresponding to. each (the ten individual bands.



       Selection notches are. notched on the discs (the selection N 7 which has just been mentioned at the positions indicated in the table of fig. 7 6 and this clans the selection positions _l and. B. For example, the disc N 7 associated with the tape N 1 is notched with notches at positions 0, 1, 2, 3 and 4 on side A, but does not have notches at positions B of this disc. This notched notch on disc N 7 corresponding to strip N 1.

    indicates that, when the knurled wheel 442 is placed in positions 0, 1, 2, 3 and 4 and the notches of the other <B> Nos </B> 1, 2, 3, 4 and 8 discs (described later ) are. in positions where finger 428 (fig. 16) can enter, band N 1 is selected and this band operates.



  Regarding the disk N 7 associated with the tape N 5, it will be noted that * notches are notched on side A at positions 0, 1, 2, 3 and a notch on side B at the fourth position. This naturally means that, if the knurled wheel 442 and the other discs Nos. 1, 2, 3, 4 and 8 are, placed so that the notches are in front of the finger 427, the individual band N 5 is selected for operation. .



  Next to the knurled wheel 442 is another knurled wheel 465 which can be adjusted differently by hand and which is provided with a hub 466 on which are engraved the characters 0 to 5, similar to those engraved on the hub 443 of the wheel 442.



  By means 466 is secured a gear 467 in mesh with a gear 468 on the side of which is mounted a pinion 469 which is in engagement with a rack 470 sliding on rollers (not shown) similar to rollers 4-19 and 450, discs spacer 4-71, on either side of gear 469, being used to hold rack 470 in alignment with gear 469. Rack 470 also engages gear 472, which drives a pinion (not shown) mounted on the square shaft 424- (fig. 3) described above, on which the shaft are fixed all the pinions used to operate the selection discs N 8 in each of the disc groups shown in fig. 15.

    The gear 472 is integral with an alignment plate 473 bearing notches, cooperating with an elastic pawl -174 intended to keep the members in correct alignment.



  These selection discs N 8 are ten in number, as can be seen in FIG. 15, each of them being associated with each of the individual bands. These selection discs have notches in the positions indicated in the table in fig. 16 to vary the control of the selection of bands 1 to 10, under the control of the keys of rows 1 to 4, according to the positions on which the notches are cut in these discs N 8.



  The way the keys 77, 78 and 79 and the keys of the. row 1. control the selection of the different bands N g 1 to 10 has already been described. 'This selection occurs. when the hand adjustable wheels or knobs 442 and 465 are both set to their zero position.



  When these wheels 442 and. 465 are. placed on positions other than zero, they vary the control of the selection of bands 1 to 1.0 according to the positions on which the respective selection discs N s 7 and 8 are placed under the control of the mechanism shown in figs. 12 and 13.



  When the two wheels 442 and 465 are at their zero position, key N 1 of row 3 and. the keys N s 18 to. 10 of row 4 select. respectively the bands N s 1 to 10. This operation is carried out in accordance with the notches cut at the positions shown in the table of fig. 16.

   When the wheels 442 and 465 are rotated to their different positions, they vary the selection of bands 1 to. 10 or in other words they modify. control of the selection of these bands as it is. exerted by the keys of the. row 3 and row 4 following the notches cut at key positions various disks 1 to 4 and 7 and 8 of each of the groups of disks indicated in fig. 15 since, as explained above, a group of disks is associated with each of the individual tapes.



  Here is a first example to explain in detail how the adjustment of the wheel 442 modifies the normal selective control exerted by the keys of rows 1 to. 4. If the wheel 465 remains at its. zero position and that wheel 442 is. moved one notch from position zero., keys NB 1 and 2 of row 3 and keys 17 to 10 of row 4 then select bands 1 to 10 respectively. In fact, this means that the button 18 of row 4 is not. more able to select band N 2, while the \? of row 3, which normally does not select any band, now selects band N 2.



  It will first be explained why key 2 does not normally select any tape for printing. In schematic form, the following combinations of N notches and X bosses are presented to the upper finger 428 and the lower finger 427. Naturally, in the case of the fingers 425, the plates 1 present them with notches for the zero position and all total keys except error key 85 and, in particular in the system shown, disc 2 has notches at the zero position as well as for the No Delay and Delay keys, which makes . that it is not necessary to include disks 1 and 2 in this example tick diagram given here.



  When button 2 of row 3 is lowered in normal operation, with wheels 442, 465 to. position zero, the following positions are carried out:
EMI0018.0013
  
    Disk <SEP> 3 <SEP> Disk <SEP> 4 <SEP> Disk <SEP> 7 <SEP> Disk <SEP> 8
<tb> Finger428 <SEP> V (.18) <SEP> X (_lO <I>) <SEP> N <B> (</B> 10) <SEP> N (d0) </I>
<tb> Finger427 <SEP> <I> N (1: 8) <SEP> N (BO) <SEP> X '(BO) <SEP> N (BO) </I> The upper finger 428 being blocked by the plates 3 and 4 and the lower finger 427 being. blocked by plate 7, band N 2 will not normally be selected by key 2 of the. row 3.



  However, when the wheel 442 is rotated one notch to its position 1 and the key 2 of row 3 is lowered, the following positions are performed:
EMI0018.0014
  
    Disk <SEP> 3 <SEP> Disk <SEP>.; <SEP> Disk <SEP> 7 <SEP> Disk <SEP> g
<tb> Finger428 <SEP> <I> X <SEP> (AS) </I> <SEP> I <SEP> (A0) <SEP> _I '(- 11.) <SEP> N (: 10)
<tb> Finger <SEP> 427 <SEP> 1V (B8) <SEP> <I> N (BO) <SEP> N (Bl) <SEP> N (BO) </I> Given that the finger lower 427 finds notches on all four disks, lowering row 3 key 2 will select band 2.

        When key 18 is down and wheels 442 and 465 are. on the zero position, the following positions are carried out:
EMI0019.0001
  
    Disk <SEP> 3 <SEP> Disk <SEP> 4 <SEP> Disk <SEP> 7 <SEP> Disk <SEP> 8
<tb> Finger <SEP> 428 <SEP> N <I> (</I> 10) <SEP> <I> N <B> (A </B> 1) <SEP> N (d0) <SEP> N (A0) </I>
<tb> Finger <SEP> 427 <SEP> <I> N (BO) <SEP> X <SEP> (B1) </I> <SEP> Y (BO) <SEP> <I> N (BO) < / I> The upper finger 428 finding eneolies on the four discs, the button 18 selects the band N 2.



  However, when the -1-12 wheel is moved one step forward to position 1 and button 1.8 in row 4 is down, the following settings are performed:
EMI0019.0007
  
    Disk <SEP> 3 <SEP> Disk <SEP> 4 <SEP> Disk <SEP> 7 <SEP> Disk <SEP> 8
<tb> Finger <SEP> 428 <SEP> <I> N (A0) <SEP> N <B> (A </B> 1) </I> <SEP> X <I> (A </I> 1) <SEP> <I> N <SEP> (A0) </I>
<tb> Finger <SEP> 427 <SEP> <I> N (BO) <SEP> X (Bl) <SEP> N (B1) <SEP> N (BO) </I> The upper and lower fingers 427, 428 being blocked, button 18 does not this time select band N 2.



  By the schematic example above, one can realize, with the brief examples which follow, of the numerous combinations of installation of the wheels 442 and 465.



  With wheel 465 in its zero position and wheel 442 advanced to position 2, the keys 1,? and 3 of row 3 and. keys 16 to 10 respectively select the bands (1 to 10.



  The wheel 465 being in the zero position and the wheel 442 being. advanced to position 3, keys 1, 2, 3 and 4 of row 3 and keys 1.5 to 10 select bands 1 to 10 respectively.



  The wheel 465 being. to zero position and wheel 442 advanced to position 4, keys 7 to. 5 of the. row 3 and keys 14 to 10 of row 4 respectively select. bands 1 to 10.



  The wheel 465 being in zero position and the wheel 442 advanced to its position 5, the notches of the disks 7 and 8 are cut in such a way that the operation of the ten bands is stopped, that is to say that no keys touch rows 3 or 4 select a band when the wheels 442 and 465 are placed in the last of the positions mentioned above, i.e. when the wheel 465 is. to position zero and wheel 442 to position 5.



  The same belt selection by the keys of rows 3 and 4 (mentioned above) takes place when the wheel 465 is in its 0, 1 or 2 positions and the wheel 442 is respectively brought to its positions 1 to. 5.



  When the wheel 465 is brought to its 3 position and the wheel 442 is in its 5 position, the N key 10 of row 4 selects the N band 10, and operation. of bands 1 to 9 is stopped. In other words, the possibility to select is removed for keys 1 of row 3 and keys 18 to 11 of row 4.



       When the wheel 465 is. at position 4 and wheel 442 at position 5, keys 10 and 11 of row 4 select bands 10 and 9 respectively, while bands 1 to 8 are. disengaged, that is to say that they are not selected because the control of keys 1 and 2 of row 3 and keys 18 to 12 of row 4 is rendered inoperative.



  When the wheel 465 is at its 5 position and the wheel 442 is also at its. position 5, keys 11, 12 and 13 of row 4 select bands 10, 9 and 8 respectively and bands 1 to 7 are disengaged, that is to say they are not selected by the others keys in rows 3 and 4 because the special arrangement of wheels 465 and 442 enabled the selection of the bands controlled by these other keys.

 

Claims (1)

RD VENDICATION Accounting machine provided with recording means, comprising several printing hammers mounted side by side, groups of discs provided with notches capable of being brought into position under the control of control keys in order to cooperate with scanning devices to normally determine which of the printing hammers should work in correspondence with the control keys that are. lowered, characterized by at least one additional disc (7, 8) for each group of discs (1 to 4), this additional disc (7, 8) being movable by a device adjustable by hand (442, 465) in order to to vary the combination of notches presented to the exploration devices (425 to 428) according to. given position of said manually adjustable device (442, 465), so that the. normal selection of printing hammers be changed. SUB-CLAIMS 1. Machine according to claim, characterized in that each group of discs (1 â. 4) comprises two additional discs (7, 8) which are. movable with respect to each other by the device adjustable by hand, so as to vary the combinations of notches presented to the exploration devices (425 to 4 \ L8). \ 3. Machine according to claim and sub-claim 1, characterized in that the additional disks (7, 8) are fixed on a common shaft (423) which undergoes a differential rotation under the control of a rack (448, 470) adjusted using a wheel (442, 465) capable of being turned by hand.