EP0013294A2 - Multiple type disk printing mechanism for typewriters or printers - Google Patents

Abstract

Printing characters using a rotary element fitted with radial character tabs. The printing element (35) according to the invention, consists of at least two wheels (43) and (45) with radial carrier tongues, mounted on the same drive axis (51) and which can be selectively driven in rotation by the latter. Each wheel has a tongue-free sector which is brought opposite the printing position to allow printing by the character-carrying tongues of the other wheel with which a single striking hammer cooperates. The rotation of the routes and therefore the selection of characters is ensured by a motor (49). The printing element (35) is removably mounted on the axis (51) so as to be interchangeable. This arrangement makes it possible to increase the number of characters available without increasing the inertia of the printing element since only one wheel at a time is driven in rotation for the selection of the characters.

Description

Technical area

The present invention relates to printers or typewriters of the serial type with printing wheel and more particularly, it relates to a machine comprising several coaxial printing wheels with tongues carrying radial characters and a single hammer.

State of the prior art

Prior art series printers include those of the print wheel type with radial character tabs. The print wheel is rotated to place a desired character tab in the print position. A striking hammer is then actuated to apply the selected tab against the printing ribbon and the paper placed on a platen to effect the printing of the character. The wheel, the wheel drive system and the hammer are generally mounted on a carriage which is moved along the printing line to print the characters in series. These printers are often associated with character selection keyboards and in this case constitute typewriters. In the case of a typewriter, approximately one hundred different print characters are arranged on the print wheel and can be selected by pressing the keyboard. These printing wheels generally have a diameter of the order of 7 to 9 centimeters, diameter dictated in part by the number of characters to be carried by the wheel. However, it is often necessary to print special characters such as, for example, Greek characters or mathematical symbols. In this case, the operator must replace the element or print wheel bearing the conventional characters with a print wheel bearing the special characters which it is desired to print. The printing element bearing the classic characters must be replaced again to continue printing the normal text. When the printer is used in combination with a storage device, the print wheel must be changed during the automatic reproduction operation. To avoid this, it would therefore be advantageous to be able to have special characters or sets of characters on the same print wheel. However, each character-carrier tab added to the print wheel causes its diameter to increase, and inherently, its inertia, which requires the use of drive and selection systems for the wheel, heavier and more expensive. In addition, the carriage drive systems also become heavier in order to be able to drive the weight selection and wheel drive systems with increased weight. In addition, an increase in the number of characters on the wheel causes longer access times to the characters and therefore, reduces the operating speed of the printer, more particularly when it is used in automatic reproduction mode. Finally, as characters are added to the wheel, the character selection logic and drive system become more complex and more expensive.

Another desirable characteristic of the typewriter would be that it can exceptionally print large characters used for example for printing notes to be displayed on a board, speeches to be read in public or documents for people with vision scaled down. Large characters occupy a large area on the printing wheel and therefore lead to the use of wheels with increased diameter, weight, inertia and price and at a slower selection speed, as indicated above.

Statement of the Invention

In order to eliminate the drawbacks indicated above which affect the devices of the prior art and to produce a print wheel printer capable of printing selected characters from a large set of characters or large characters dimension, without significantly slowing down the progress of the printing process or excessively increasing the weight and the cost of the device, two printing wheels are coaxially assembled according to the present invention forming a single element printing and offering approximately twice as many characters as a printing element with a single wheel while having substantially the same inertia as the latter.Each wheel has a plurality of radial tabs character carriers and the selected tongue is driven by a hammer to strike the paper placed on a turntable. Each wheel has a window located between two tongues and of sufficient width to allow the passage of the hammer or a tongue. In operation the window of one of the wheels and the selected tongue of the other wheel are brought into the position of im pressure and the hammer is activated. The distance between the hammer and the tongue selected on one or the other wheel is kept constant by axially shifting the assembly of the two wheels along its axis of rotation. The printing element constituted by the two wheels is moved relative to the platen, from one printing position to the other, along the printing line, and the platen is turned in increments to ensure the printing of successive lines. The assembly of the two wheels constituting the printing element can be removed from the machine and replaced by another printing element.

• La Figure 1 est une vue en perspective d'une machine à écrire/imprimante comportant le dispositif d'impression à roues multiples de la présente invention.
• La Figure 2 est une représentation schématique d'un système d'impression à roue de l'art antérieur.
• La Figure 3 est une réprésentation schématique du système d'impression à roues d'impression montées coaxialement, de la présente invention.
• La Figure 4 est une représentation schématique du système d'impression de la présente invention en position décalée.
• La Figure 5 est une vue en coupe latérale des roues d'impression montées sur l'arbre d'impression lorsque l'impression est assurée par la roue arrière.
• La Figure E est une vue des roues d'impression prise depuis la platine.
• La Figure 7 est une vue en perspective du chariot porte-élément d'impression et du dispositif de sélection de caractères, en position de fonctionnement.
• La Figure 8 est une vue en perspective du chariot porte-élement d'impression et du dispositif de sélection en position de chargement par l'opérateur.
• La Figure 9 est un diagramme qui représente la séquence des opérations logiques lors du dispositif de sélection de roue d'impression de la présente invention.
• La Figure 10 est un diagramme qui représente les circuits logiques de commande de la sélection de roue d'impression.

Brief description of the figures in the drawings

• Figure 1 is a perspective view of a typewriter / printer including the multi-wheel printing device of the present invention.
• Figure 2 is a schematic representation of a prior art wheel printing system.
• Figure 3 is a schematic representation of the printing system with coaxially mounted printing wheels of the present invention.
• Figure 4 is a schematic representation of the printing system of the present invention in an offset position.
• Figure 5 is a side sectional view of the print wheels mounted on the print shaft when printing is provided by the rear wheel.
• Figure E is a view of the print wheels taken from the platen.
• Figure 7 is a perspective view of the print element carriage and the character selection device in the operating position.
• Figure 8 is a perspective view of the print element carriage and the selection device in the operator loading position.
• Figure 9 is a diagram showing the sequence of logic operations in the print wheel selection device of the present invention.
• Figure 10 is a diagram showing the logic circuits for controlling the print wheel selection.

Description of the invention

Referring now to the drawings and more particularly to FIG. 1 which is a perspective view of a typewriter or printer comprising the multi-wheel printing device of the present invention, it can be seen that the machine 11 comprises a device 13 and a cylindrical plate 15 on which is wound a print receiving medium such as the sheet of paper 17 which is printed by the printing device 13. The typewriter or printer 11 may also include a keyboard 19 which can be fixed to the front part of the chassis 21. The chassis 21 carries an axis 23 on which the plate is mounted 15. The plate can be turned manually using a button 25 or automatically by a drive motor 26 coupled to a gear train 27. Paper feed rollers 29 are arranged under the plate 15 and loaded by spring against it so that the rotary movement of the plate ensures the advancement of the sheet 17 upwards. Conventional paperweight rollers 31 apply the sheet against the platen to facilitate printing.

The printing device 13 comprises a printing element 35, a hammer mechanism 37 and a printing ribbon 39, all of these elements being mounted on a printing element carriage 41. The printing element printing 35 comprises a front printing wheel 43 and a rear printing wheel 45 each composed of a plurality of radial printing tabs fixed to a central hub 46. Each of the tabs carries a symbol or character not shown. The front printing wheel 43 has a sector or window 47 without tabs through which the hammer device 37 passes to apply a printing tab of the rear wheel 45 against the ribbon 13 and the paper 17.

When printing is provided by the rear wheel 45, the front wheel 43 is rotated so that its free sector 47 is aligned with the hammer device 37. The rear printing wheel 45 is rotated by a motor selection 49 until the tab bearing the character which one wishes to print is aligned with the hammer device 37, the free sector 47 and the printing position on the paper 17. The hammer device striking 37 is then actuated to cause the movement of the hammer (not shown) over a fixed distance through the free sector 47 and to apply the selected printing tab of the rear printing wheel 45 against the printing ribbon 39 and the paper 17 so as to ensure the printing of the selected character carried by the printing tab on the paper 17.

When the printing is carried out by the front wheel 43, a free sector (not shown) of the rear wheel 45 is aligned with the hammer device 37 and the character of the front wheel 43 which it is desired to print is arranged adjacent to the hammer device 37, in alignment with the free sector of the rear wheel (not shown) and the printing position on the paper 17. The hammer then applies the printing tab carrying the selected character, through the sector free from the rear wheel 45, against the printing ribbon 39 and the paper 17, to ensure printing. As will be seen below, the printing element 35 is offset on the printing shaft 51 of the selection motor 49 each time that a different printing wheel is selected in order to maintain constant the distance traveled by the print hammer and the tab selected to be applied against the paper 17.

After the printing of each desired character, the printing element carriage 41 escapes to the next printing position so that a line is printed in series. A cable 52 is fixed to the carriage 41, wound around pulleys 53 and 55 and connected to a motor 56 which, through it, drives the printing element carriage 41 in the direction of printing or Line break. The carriage 41 is mounted on two parallel support rails 57 and 59 which allow its movement.

Referring to Figure 2 which is a schematic illustration of a printing wheel system of the prior art, it can be seen that it comprises a plate 15 on which is wound a sheet of paper 17, a hammer device 37, a printing ribbon 39 and a printing wheel 65 provided with a hub 46. During the printing process, the ribbon impression 39 is lifted and brought into its position shown in dotted lines and the striking hammer device 37 is excited in order to cause the hammer movement 61 to the left to strike the selected printing tongue and apply it against the ribbon. printing 39. The tab and the printing ribbon then strike the sheet of paper 17 and cause the printing of the selected character. Once the hammer 61 has cleared from the print wheel 65, the print wheel can be rotated to select another character tab so that the next symbol can be printed during the printing cycle. next operation.

Referring now to Figure 3 which is a schematic representation of the coaxially mounted multiple print wheel system of the present invention. The printing element 35 comprises the front printing wheel 43 and the rear printing wheel 45. The rear printing wheel 45 is rotated so that its sector without character tabs or window is aligned with the position printing. In this position, the rear print wheel is essentially arranged in the free space located directly under the print ribbon 39 and does not affect the operation of the front print wheel 43. The front print wheel 43 is arranged exactly like the printing wheel 65 of FIG. 2 with respect to the plate 15 and to the hammer hammer device 37 and the printing is carried out in the same way. To make the selection of characters during successive printing cycles, the print wheel front 43 is rotated while the rear printing wheel 45 remains fixed in the position described.

In Figure 4, there is a schematic illustration of the coaxially mounted multiple print wheel system of the present invention when it is offset on its axis. In this offset position, the front printing wheel 43 has been rotated so that its free sector is aligned with the hammer device 37 and the printing position. The printing element 35 has been offset axially in the direction indicated by the arrow 67 from its position in FIG. 3, by a distance corresponding to the distance separating the front wheel 43 from the rear wheel 45. In addition, the wheel 45 has been rotated 180 ° from its position in Figure 3 in order to prepare for the selection of any particular printing tab. The assembly thus being arranged, the actuation of the hammer striking device 37 causes the hammer 61, which is now disposed in the free sector of the front wheel 43, to strike a selected character tongue of the striking wheel. rear printing 45 against the printing ribbon 39 and the paper 17. The selection of the printing characters for the rear wheel 45 is carried out by turning the rear wheel 45 while holding the front wheel 43 in a fixed position. Note that the distance between the hammer device 37 and the printing wheel used for printing remains constant. In addition, the distance between the selected printing tab and the printing ribbon 39 as well as the distance between the selected printing tab and the plate 15 remain constant. Thus, the same hammer device 37 as that used in the machines of the prior art, could be used with the present invention. In addition, as will be seen later, the character selection device of the prior art could also be used since the number of printing tabs and their relative positions on each of the printing wheels 43, 45 could be similar to the number and relative positions of the tabs of the printing wheel 65 of the prior art.

Now refer to Figure 5 which is a side sectional view of the print wheels mounted on the print shaft when printing is done from the rear print wheel. The two printing wheels 43 and 45 are made of flexible plastic material used for the manufacture of printing wheels of the prior art such as that used in the QUME Q series printers manufactured by QUME Corporation of Hayward, California, USA. The two printing wheels 43 and 45 are made integral by a crown 73 of the hub of the rear printing wheel 45 which fits into an annular groove 75 of the hub of the front printing wheel 43. This arrangement allows the relative rotation of the printing wheels while allowing, if necessary, their manual separation, with the application of a force greater than that exerted during normal operation of the machine.

The printing element formed by the printing wheels 43 and 45 slides freely on the printing shaft 51. A drive finger 77 is fixed to the printing shaft 51 and selectively engages in a slot axial 79 formed in the rear wheel 45 (see FIG. 6) when the printing element 35 is positioned for a printing operation carried out from the rear printing wheel. The drive finger 77 engages in a similar slot (not shown) formed in the front printing wheel 43 when the printing element 35 is shifted to the left on the shaft 51, as seen in Figure 5, to ensure a printing operation from the wheel front printing 43. The rotation of the printing shaft 51 thus causes the rotation of the printing wheel 45 via the drive finger 77 when the printing element 35 is in the position shown. in Figure 5. In order to prevent the front wheel 43 from turning with the rear wheel 45, a flat 81 of the hub of the front wheel 43 bears against a fixed stop 83. In a similar manner, when the element 35 is shifted to the left on the print shaft 51 to ensure printing from the wheel having 43, a flat 85 (see also Figure 6) of the hub of the rear wheel 45 bears against a stop fixed 87. Thus the rear wheel 45 cannot rotate when the drive finger 77 drives the front wheel 43 in rotation. not. By rotating only one print wheel at a time to select a character, the inertia of the selection system of the present invention is allowed to remain close to that of the single wheel systems of the art prior.

An offset control arm 89 engages in an annular groove 91 formed in the front wheel 43. The movement to the left of the offset control arm 89 causes the corresponding displacement of the printing element 35 on the shaft 51. Once the printing element has been shifted, it can be returned to its extreme right position by the return of the shift control arm 89. During this operation, the printing wheels must be each placed in their rest position so that the drive finger 77 aligns with the axial slot 79 made in the rear wheel 45 and with a similar slot (not shown) made in the front wheel 43.

Figure 6 shows the print wheels viewed from the printer stage. The rear wheel 45 is thus arranged over the front wheel 43 as seen in the figure and the two wheels are in the rest position, which allows the drive finger 77 to align with the axial slot 79 of the rear wheel 45 and with a similar slot (not shown) of the front wheel 43. The free sector 47 of the front wheel 43 is of sufficient size to allow the passage of the striking hammer 61 of FIG. 3 and the printing from the rear wheel 45. The free sector between the printing tabs 93 and 94 of the rear wheel 45 is substantially greater than the free sector 47 of the front wheel 43 to allow the positioning of the printing ribbon 39 of Figure 1 below the wheel 45, when the printing is carried out from the front wheel 43, (as has been said previously with reference to Figure 3). It will be noted that this free sector could be reduced if the ribbon was brought closer to the plate or kept constantly in the raised position. The free sector must be of sufficient size to allow the selected printing tab of the front wheel 43 to pass through it to strike the platen.

It will also be noted that the rest position of each wheel aligns the drive finger 77 with its associated slot. In addition, the free sector of each printing wheel is aligned with the hammer and the printing position.

Figure 7 is a perspective view of the carriage print element holder and selection system in operating position. As indicated previously, the printing element carriage 41 also carries a selection motor 49 in turn equipped with a shaft 51 on which the printing element 35 is mounted. The selection motor 49 controls the angular position of the shaft 51 and therefore the positioning of a selected printing tab in the printing position.

When it is desired to remove the printing element 35 from the printing shaft 51 to replace it with a different printing element, the selection motor 49 is brought into rotation in its rest position, then tilted around of its tilting axis 101 (see also Figure 1) in the position shown in Figure 8. The tilting axis 101 is fixed to the rear of the motor 49 and pivotally mounted in a U-shaped support 103.

A control handle 105 can be used by the operator to move the selection motor 49 and the printing element 35. When the handle 105 is moved away from the selection motor 49, the pivot rod is caused to pivot. link 107 towards the outside, around its pivot 109, which frees the locking surface 111 from the lock 113 which is fixed to the motor 49. The spring 115 biases the slide 117 and pushes it down against the curved lip 119 ( see Figure 8) of the support 103, which causes the latch 113 to pass over the locking surface 111 of the connecting rod 107. The slide 117, being pushed down, also urges a flat 120 of the collar 121 fixed to the printing shaft 51 and thus, blocks the printing shaft in the rest position. The handle 105 is then pulled to the left as shown. seen in Figure 7 and requests the finger 122 fixed to the selection motor 49 to cause the pivoting of the selection motor 49 and of the printing element 35 upwards around the pivot axis 101 of the motor.

Figure 8 is a perspective view of the print element carriage and the selection mechanism in the operator loading position. The printing element 35 of FIG. 7 has been removed from the printing shaft 51 to show the drive finger 77. To release the printing element 35 from the fixed stop 87 by tilting the motor 49 around the axis 101 of Figure 7, the fixed stop 87 is tilted forward. The selection motor 49 bears on the surface 123 of the connecting rod 125 when it is in the operating position. When the selection motor 49 is tilted out of its operating position, a spring (not shown) disposed on the pivot axis 127 biases the rear surface 129 of the fixed stop 87 to separate it from the selection motor 49. When the motor 49 is returned to the operating position, it biases surface 123 downward causing pivoting of stop 87 against the force exerted by the spring (not shown), around the pivot axis 127, to return to its operating position. It will be noted that the stop 87 remains fixed as long as the selection motor 49 remains in the operating position as shown in FIG. 7. The fixed stop 83 which operates in association with the front printing wheel 43 is fixed to the selection motor 49 since it is integral with the support 131.

As indicated above, an offset control arm 89 biases the printing element 35 of the Figure 7 to cause its axial offset on the printing shaft 51. The movement of a solenoid plunger (not shown) against the surface 133 of the connecting rod 135 causes it to pivot around the pivot 137 and the lifting of the tongue 139. The upward movement of the tongue 139 which is integral with the shift control arm 89, causes the latter to pivot clockwise around the pivot 141 against the restoring force exerted by the spring 143. This action causes the printing element 35 of FIG. 7 to move away from the motor 49 on the printing shaft 51. The relaxation of the force exerted by the solenoid plunger on the surface 133 allows it is up to the spring 143 to return the printing element 35 to its position closest to the motor 49.

As described above, the characters can be entered into the machine from the keyboard 19 in FIG. 1 or from other means for entering characters such as communication channels or storage devices such as magnetic media. When using a keyboard, it is desirable to place all the characters encountered in the preparation of conventional documents, on a single print wheel, for example the front print wheel 43. The characters that are encountered less often such as for example, the Greek characters, can be placed on the second printing wheel which will be, in this case, the rear printing wheel 45. Thus, in normal printing operation, all the characters will be selected from of the front print wheel, allowing for maximum print speed. When a special character is to be selected, the second printing wheel is used. This second selection process is faster and easier to perform by the operator than the prior art method which consisted of changing the print wheel. Since most keyboards are designed to allow the selection of a hundred characters (using the shift key), it is necessary to add an additional code key to these classic keyboards in order to be able to select additional characters arranged on the second wheel or rear print wheel 45.

Figure 9 shows the flow of operations performed by the logic of the print wheel selection device of the present invention. Pressing a key generates a CC character code representing a particular character tab of one of the two printing wheels 43 and 45 of FIG. 1. This CC character code is applied to the decoding logic during step 151 and this logic delivers output signals, which are applied to blocks 153 and 155, which respectively indicate whether the character in question is placed on the front wheel 43 or on the rear wheel 45 of Figure 1. The signals from blocks 153 and 155 are respectively applied to blocks 157 and 159 which respectively determine whether the character in question is on the front wheel presently in the printing position, or on the rear wheel presently in printing position. If, as indicated by the affirmative paths from blocks 157 and 159, the selected character is on the wheel currently in the printing position, the selection logic is excited during step 161 and causes the rotary drive by the selection motor 49 of the Figure 1, of the print wheel so that the tab bearing the selected character is aligned with the hammer device 35 of Figure 1. Once this alignment is performed, the print ribbon 39 is raised in printing position and the hammer device 35 is energized to perform printing during step 163.

If the output of blocks 157 and 159 indicates that the selected character is not on the wheel currently in the printing position, the negative outputs of blocks 157 and 159 are followed.

In this case, the printing element 35 is brought into its rest position during step 165. The printing wheel selection logic is then excited, during step 167, to cause the offset of the printing element 35 of FIG. 1 on the printing shaft 51 so as to select the second printing wheel for its rotation drive. The selection logic then causes, in step 161, the alignment of the selected printing tab with the printing position, as indicated above.

Figure 10 is a schematic representation of the print wheel selection control logic. The print wheel selection control logic determines which of the wheels 43 or 45 of Figure 1 is selected for printing as well as which of the free sectors is aligned with the print position and the hammer. As indicated above, the character code from a keyboard or any other input device is decoded to determine whether this character is on the front print wheel 43 or on the rear print wheel 45 of Figure 1. A signal called PPI representing the wheel currently in the printing position as delivered by a position lever 171 and a decoded character signal CD are applied to the wheel selection logic 173. This logic is composed of simple elements of combinational circuits which deliver an output signal indicating either that the correct wheel is in position for character selection, or that the position of the wheel must be changed. If the correct wheel is in position, a signal is sent to the OR gate 175, then to the position selection logic 177. The logic 177 may be identical to that used in current printers such as the QUME Q series printers. Logic includes a character counter that maintains the current rotational position of the print wheel and a logic part, including storage flip-flops, which indicate the desired position of the selected character. The motor 49 of Figure 1 which can be the same servo motor as that used in the QUME printer, is then rotated until the correct printing tongue is aligned with the hammer and the position printing. An optical transducer delivers reaction pulses indicating the rotation of the servo system. The logic controlling the hammer and the printing ribbon is identical to that used in the QUME Q series printers. This logic is represented by block 179.

When the print wheel selection logic 173 indicates that the wheel must be changed, the currently selected print wheel is brought into the rest position by the logic block 181. The print wheel can be brought back to the position of rest using the current position selection logic of the QUME Q series printer. This operation is accomplished by loading the rest position into the storage scales of the desired character positions, which causes the servo motor to rotate to the rest position. A neutralization signal is applied to the ribbon logic and the hammer logic to avoid the execution of a printing cycle. Once the previously selected print wheel has been placed in the rest position, a signal is delivered by the block 181 to the position latch 171 which also receives a reaction signal and a signal from the wheel selection logic d impression 173 indicating that the position of the wheel must be changed. The position lever 171 is a bistable device which changes state when the wheel selection logic 173 and the wheel return logic in the rest position 181 deliver signals to it. When the position latch 171 changes state, it causes the application of a signal to the solenoid exciter 183 which, in turn, causes the surface 133 of the connecting rod 135 of FIG. 8 to be stressed. by a solenoid (not shown), causing the repositioning of the printing element 35 by the shift control arm 89. The output signal of the position latch 171 is delayed by the circuit 185 to ensure positioning correct wheel before applying this signal to OR gate 175 and therefore to position selection logic 177. Once logic 177 has received this signal, it responds to the character coded signal by causing the rotation of the newly selected print wheel to its correct position. Then the printing hammer logic 179 controls the printing as described above.

Although the present invention has been described in relation to a printing element comprising two wheels printing with character-carrying tabs, it is obvious that additional printing wheels could be used in the same way to allow the printing of a greater number of characters, while retaining the benefit of maintaining or reduction of the inertia affecting the print wheel selection device. For example, three printing wheels could be mounted on the printing shaft 51, each of them having a sector free of tongues and a corresponding stop being associated with each wheel. The two unselected printing wheels would be arranged so that their free sectors are aligned with the striking hammer while the selected wheel would be entrained - in rotation to align the tongue bearing the character to be printed with the striking hammer. The print wheels would be offset axially to maintain a constant distance between the selected print tab, the hammer and the platen.

In addition, the currently disc-shaped printing member could be in the form of a cup. The print tabs forming a cup would be mounted concentrically on a vertical print shaft. The vertical shaft would then be shifted to or from the stage depending on the selected printing element. Each of these printing elements would have a tongue-free sector, that of the external printing element being dimensioned so as to. allow the passage of the printing tabs and that of the internal printing element being dimensioned so as to allow the passage of the hammer.

Various minor changes in form and design could also be made to the device without departing from the scope of the present invention. Simple inversions could be carried out in the device, for example the driving finger 77 and the driven slot 79 of FIG. 6 would be replaced by a driving slot made in the printing shaft 51 and a driven finger integral with the element d printing 35. A magnetic coupling could also be used in place of the crown 73 / groove 75 assembly currently in use.

Although the essential characteristics of the invention applied to a preferred embodiment of the invention have been described in the foregoing and represented in the drawings, it is obvious that a person skilled in the art can contribute to it. any modifications of form or detail which he judges useful, without departing from the scope of said invention.

Claims (9)

1.- Multi-wheel printing assembly for a printer of the type comprising a plate on which a document is placed, a printing ribbon, a printing element in the form of a wheel, separated from the plate and comprising a plurality of tabs character carrier capable of being driven towards the plate to strike it at a printing position, the printing element and the plate being mounted so as to be able to be animated with a relative movement relative to each other to change the printing position in at least two directions, and a hammer to apply any selected tab against said platen at said printing position, said multi-wheel printing assembly being characterized in that it comprises: a first printing wheel comprising a plurality of radial tongues integral with a central hub, each carrying a printing character and having a sector free of tongues dimensioned so as to allow the passage of the hammer, said first printing wheel being rotatably mounted on an axis so that each of said printing tabs can be selectively aligned with the printing position, at least a second printing wheel comprising a plurality of tabs integral with a central hub each carrying a printing character and having a sector free of tabs dimensioned so as to allow the passage of at least one printing tab of said pre first printing wheel, said second printing wheel being rotatably mounted on the same axis as that of said first printing wheel so that each tab of said second printing wheel can be aligned with the printing position , character selection means for selectively rotating one or the other of said printing wheels in order to align the tongue-free sector of one of said wheels with the hammer in the printing position as well as a selected print tab on the other of said wheels with said hammer in said print position, and an actuating means responding to the character selection means for actuating the hammer in order to apply the selected printing tab against the platen, at the printing position, so that the printing character carried by said tab prints the document. 2.- printing assembly according to claim 1, characterized in that said character selection means comprises: a rotary shaft for driving said printing wheels in rotation, said printing wheels each being mounted coaxially on said shaft and axially movable thereon, shift means for axially shifting a selected print wheel along said shaft from a rest position to an operating position and for shifting the second printing wheel from its operating position to its rest position along said shaft. 3. A printing assembly according to claim 2 characterized in that said rotary shaft has a drive finger selectively engaging in a drive slot formed in the print wheel placed in the operating position, for the drive in rotation. 4. A printing assembly according to claim 2 or 3, characterized in that said character selection means further has a stop which blocks that of the printing wheels which is in the rest position to prevent its rotation while said shaft drives the other print wheel in rotation. 5.- A printing assembly according to claim 4 characterized in that said stop is composed of a first stop element blocking said first printing wheel when said second printing wheel is rotated and a second element d stop stopping said second print wheel when said first print wheel is rotated. 6. A printing assembly according to claim 5, characterized in that each printing wheel has a flat on its hub used in association with its stop to ensure its blocking. 7. A printing assembly according to claim; characterized in that said sector free of tabs of said second print wheel allows the passage of said print ribbon when said second print wheel is in the rest position. 8.- A printing assembly according to claim 2, characterized in that said first printing wheel and said second printing wheel are connected by their hubs so as to be able to be driven in rotation relatively one relative to l 'other and driven axially and integrally on the printing shaft. 9. A printing assembly according to any one of claims 1 to 8, characterized in that said first and second printing wheels are connected by a crown provided on the hub of one of them and by a groove corresponding annular machined in the hub of the other.

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