NO127548B - - Google Patents

Description

Device by keyboard for calculators.

For calculators with keyboards

of the ten-key type, it has often been pointed out as a disadvantage that both the key pressure and the key movement are so large that the setting operations with constant calculation become rather tiring for the fingers.

By e.g. adding machines are this

problem has long since been solved by using a special pin carriage, with the help of which you get a fast and easy-to-operate keyboard with small key movements.

That this problem is more difficult to solve

in the case of calculators with a ten-key board, and especially in those with a pinwheel rotor, the reason is that the depression of the key will partly cause a number of locking devices to be pushed away, and partly a turning of a setting disc by a certain angle which, as a rule, is proportional to the set digit. Consequently, the 9's setting dial must perform a movement that is nine times as large as when a 1 is to be set. On many types of machine, the 9-number tangent therefore offers a significantly greater resistance to pressure than, for example, the key for zero or one. This is also unfortunate for such a keyboard, where the different keys require different force, and it has proven to be rather tiring for the fingers of the calculating hand when working for longer periods of time.

Up to a certain extent this has

disadvantage could be remedied by selecting the disc's initial position between the numerical values 4 and 5, so that the disc is turned in one direction or another from a central position when setting. The value zero has also been represented by the middle position and the other digits have been regrouped

this in order to equalize the varying setting work in this way.

If you leave the value zero in the middle in this way, the keyboard can indeed be executed fairly satisfactorily, but the design of the rotor causes considerable difficulties, and this is particularly the case if the machine is to be able to perform repeated multiplications (the result of which is added, for example); furthermore, manufacturing-technical difficulties are present.

The system of placing the initial position of the dial between numbers 4 and 5 also entails certain disadvantages, mainly of a manufacturing technical nature, which make the device expensive for simpler machines, but it is well suited for larger and more complicated machines with assembly mechanisms , as in this case it can be combined with a very simple return mechanism.

The purpose of the present invention is to provide a device for keyboards for calculators, preferably for simpler ones of the pinwheel type, where each digit setting key when pressed affects recording organs in an actuator (rotor) and triggers its step-by-step movement after each set digit, and where the key pressure is lowered by one or more springs which act in known manner on one or more knee-joint-like organs which, when a key is depressed a short distance, are brought past an upper dead position, after which the action of the spring or springs on the knee-joint-like organs helps the set finger to press the key so far down that the setting work in the rotor is carried out; the invention is distinguished by the fact that the drive device for the step-by-step movement is arranged to tension the spring or springs which contribute to the depression of the keys and, as a result, reduces the necessary manual pressure on the keys.

A particularly simple embodiment of the invention adapted to a common type of pin-wheel machines will be described in the following in connection with the drawing, where fig. 1 shows in perspective a setting mechanism in the initial position (the zero position) and fig. 2 same element with a number key in the depressed position. Fig. 3 shows a section through the mechanism, where the parts take the same positions as in fig. 1, and fig. 4 corresponding to fig. 2. Figs. 5 and 6 show, seen from the underside, some details during two different phases of the setting operation, and fig. 7, seen from above, a pinwheel rotor as it can suitably be designed to cooperate with a setting mechanism according to the invention.

In the design example shown in the drawings, the spring device which helps to press down each digit key consists of two springs (30 and 46) which both act on knee-joint-like elements which, when a key is pressed down a short distance, are guided by the key past an "upper dead position", after which the action of the springs on the knee joint-like organs helps to help the tuning finger to press the key so far down that the necessary tuning work in the rotor is carried out. When the setting mechanism is then moved step by step for each set digit, the springs of the setting devices are tensioned again by the per se known (and very powerful) spring which moves the rotor into the side position, i.e. this spring brings the knee-joint-like organs back to the starting position.

The type of machine shown in the drawings has, in a known manner, a setting rotor A which is displaceably mounted on a shaft fixed in the machine's frame. This rotor is normally composed of a number of calculation disks 2 (see fig. 7). As can be seen from fig. 3, each calculation disc has nine radial grooves, in which calculation pins 3 are displaceably arranged. Each calculator pin has a small pin 3a which cooperates with a curved groove 4a in a setting disk 4 belonging to each calculator disk 2 which is stored on a hub on the calculator disk. (The appearance of the setting dials can be seen best from fig. 1 and 2).

Each setting disc 4 carries along its periphery a numbered element 4c (see fig. 3 and 4). The digits are read through a digit window 48 and show the number set in the rotor. Each calculation disk 2 is provided with a locking hook 5 which is pivotably stored on a pin 6 riveted to the calculation disk 2; a tension spring 7 is arranged to constantly pull a bent part 5a on the chin 5 into engagement with tooth-like recesses 4b (see fig. 4) in the setting disc 4.

Setting and calculation discs are threaded alternately on a tube 9 and are held to a unit by a guide disc 8 with a groove 8a in the periphery, which is locked in position by a nut 10 which is screwed onto the tube 9. The calculation discs 2 are prevented from rotate in relation to the guide disc 8 (or inter-mutally) by a shaft 11 which is passed through a hole in all the discs 2. The setting discs 4 have a clearance slot for the shaft 11.

The thus constructed rotor A is stored on ball bearings 12 and 12a on the shaft 1 and can both be rotated and displaced along the shaft.

Near each end of the shaft 1, an end disc 13 or 14, which end disks between them carry a guide ruler 15 with a ridge 16 which locks all adjustment disks 4 in position by cooperating with internal grooves 4d in these (see fig. 4). The back 16 of the guide ruler has a recess 16a (see fig. 7) which is located in such a way that the setting disc which is just in the setting position is directly outside this recess. The setting disc that is in this position is therefore held against rotation only by the locking hook 5.

The calculating disks 2 and the setting disks 4 move completely free of the ruler 15, 16, but the guide disk 8 has a groove for the ruler 15, which allows the rotor to be displaced axially. If, on the other hand, shaft 1 rotates, rotor A follows this rotation.

The rotor shaft 1 stored in the machine stand can be turned in one direction or another by means of a crank or preferably an electric drive device for additive or subtractive calculus.

When a number is set in the rotor, it is displaced in the known manner in the lateral direction one step at a time, in fig. 7 to the left, and this step movement is effected by a rotor bracket 17 which is displaceable but not rotatable stored on a fixed shaft 18 in the machine stand. The rotor bracket 17 carries an arm 17a which engages with the groove 8a in the guide disc 8 circumference. The rotor A and the hoop 17 are thereby firmly connected to each other in the axial direction.

The unit that is thus formed by the rotor and rotor bracket is affected by a force to the left in fig. 7 by a relatively strong spring 19. The rotor bracket 17 is further firmly connected to a rack 20 which is in constant engagement with a gear 21 which is fixed on a shaft 22. As indicated in fig. 1-6, this shaft 22 is rotatably stored in the machine frame, and the lower part of the shaft is firmly connected to a locking wheel 23 with five arms 23a or teeth.

From fig. 1-2 it can be seen that the locking wheel 23, the shaft 22 and the toothed wheel 21 are driven around by the rack 20 as soon as the rotor A and the rotor bracket 17 are displaced in the lateral direction, and the ratio is chosen so that the locking wheel 23 by a displacement of the rotor, which corresponds to a decade (a step ), turns a fifth of a turn. When the rotor is shifted to the left in fig. 7, the locking wheel 23 turns clockwise, fig. 5, i.e. in the direction of the arrow (fig. 5 and 6 show, as previously mentioned, the details of the machine seen from the underside).

The locking wheel 23 cooperates with a locking mechanism consisting of a pin 24 which is fixed in the machine's foundation, and on this pin is stored a hook 25 which is acted upon by a spring 26 in the direction of a pin 27 (see fig. 5 and 6). The hook 25, which forms a two-armed barbell, carries two attachment tabs 25a and 25b, and in the position shown in fig. 5, the rotor is prevented from moving to the left, while the tab 25 a rests directly against an arm of the locking wheel 23. Only if the hook 25 is swung around the pin 24 to the position shown in fig. 6, the locking wheel 23 can be turned in the direction of the arrow, whereby the rotor moves to the left.

Another arm 29 is stored on another pin 28 which is also fixed in the machine's foundation. If this arm is swung around the pin 28 to the position shown in fig. 6, the outer end 29 of the arm will act on the protrusion 25b of the hook 25, so that the hook is swung and the protrusion 25a is released from the locking wheel 23 arm. The rotor and the rotor bracket are now free and move under the action of the spring 19 to the left. The continued movement of the rotor unit in this direction is, however, prevented by the fact that the arm 29, during its oscillation, has guided a roller 31 stored on a pin 29b on the arm 29 into the path of one of the arms 23a of the locking wheel 23. When the rotor, under the influence of the spring 19, continues its movement, the roller 31 and thus the arm 29 is forced back to its starting position, whereby the hook 25 is released and prevents the movement of the ratchet wheel 23 by the tab 25a blocking the next arm of the ratchet wheel. The rotor unit has thus been moved one step to the left (fig. 7), after which the movement is prevented by the locking mechanism.

The machine's keyboard and the thus

interacting parts are arranged in the following way (it should be noted that in the drawings, for the sake of clarity, only one key is shown, while the keyboard is of course of the normal ten-key type). Each key 33 (in the example shown, a key for the number 9) is stored on a shaft 32 which is fixed in the machine stand. The outer part of the key is finished with the usual button 34 with a numerical designation, and on the key arm a fork 36 is pivotally supported on a pin 35. The leg of the fork 36 encloses a shaft 37

on a tangent bridge 38 which consists of two arms which are pivotably stored in the machine stand about pins 39: One of the two arms of the tangent bridge 38 has a downward-directed part with a pin 40, which is inserted into a hole at one end of a link 41. This link's other end is supported on a pin 29c on the above-mentioned arm 29 in the locking mechanism. As can be seen from fig. 1 and 2, depressing the key 33 will cause a rotation of the key bridge 38; this rotation is also indicated by an arrow in fig. 3. The joint 41 is thereby pulled to the left (fig. 5) and thus triggers, in the manner described above, by swinging the arm 29, a movement of the rotor by one step.

The tangent bridge 38 with the shaft 37 forms one of the two above-mentioned knee joint-like organs. It is affected by a spring 30 which is clamped between the shaft 37 and a fixture in the machine stand. From fig. 3 and 4, it appears that the spring during the tangent bridge's movement passes the center line of the bridge as soon as the "knee joint" has passed its upper dead position.

If you hold the key with your finger in the depressed position, the rotor is prevented from moving laterally, as the spring 19, which seeks to turn the locking wheel 23, cannot lift the key over the growth pin system 29-41 against the finger's pressure. The step flow thus only takes place when the key is released.

The key is furthermore provided in a known manner with a hooked fork with a curve-shaped groove 33a which, during the depression of the key, grips and affects a shaft 42.

The shaft 42 is fixedly connected with one end to an arm 43 and with its other end to a segment 44, so that the shaft, the arm and the segment form another knee-joint-like unit which is pivotally mounted on pins 45 in the machine's frame. A spring 46 acts on the shaft 42, and the line of action of the spring also passes here during the movement of the shaft over the bearing center for the pins 45, so that the spring 46 also, as soon as the upper dead position has been passed, contributes

Claims (5)

to drive the shaft 42 downwards, i.e., the finger acting on the key assists in turning the segment (see Fig. 4). When the key 33 is pressed down, the groove 33a in the key arm will grip the shaft 42 and lift it up, so that the segment 44 is turned in the direction of the arrow (fig. 3) until the segment, when the key is at the bottom, has assumed the position shown in fig . 4. The arm 43 fixedly connected to the shaft 42 is provided with a pin 43a which is the storage center for a link 47, the other end of which is designed with a groove that encloses a pin 40 on the above-mentioned tangent bridge 37, 38. From fig. 1 and 3 it appears that the bridge 37, 38 in its initial position also maintains the segment 44 in the initial position. When the bridge 37, 38 moves, the segment is released, and from the same figures it is clear that the joint 47, when the tangent bridge is pressed back by the spring 19 over the elements 29-41 in the manner described above, will be driven by the pin 40 back to the starting position which is shown in fig. 1 and 3, whereby the segment 44 is brought along and the spring 46 is tensioned. From the same figures it is also clear that the spring 30 acting on the tangent bridge has its line of action above the center of the pivot point, so that the spring helps with the key setting after a short movement of the key. The force required to bring the springs 30 and 46 back to their tensioned starting position is provided by the spring 19 which must therefore be dimensioned appropriately in relation to the size of the transmission and the strength of the other two springs. When a key is pressed down and the segment 44 is made to swing about the pin 45, its first tooth will lift the above-mentioned locking hook 5, so that the disc 4 is released in a known manner at the same time as the teeth of the segment engage with the teeth 4e of the disc 4. When the segment continues its turning movement, the disc 4 follows along, and in the case shown in the drawings, i.e. that the tangent corresponds to the number nine, the disc is rotated nine steps. It is clear that the division between the pin 3, the outlets 4b and 4d and between the teeth 4e must be in accordance with the division between the digits on the elements 4c. In principle, the different tangents 0-9 differ only in the design of the fork-shaped groove 33a. On the key that sets the digit 1, the track is thus e.g. only so large that the disc 4 is turned one unit. From fig. 7 shows the relative position between the segment 44, the rotor A and the ruler 15, 16, and it also appears that the setting disc 4 which is currently under position, lies directly outside the recess 16a in the back 16 of the ruler. Setting a digit in the calculator rotor takes place in the following way. When the key 33 is pressed down, the segment 44 will turn the first part during the finger's depression, after which the springs 46 and 30 help to turn the key bridge and the segment as far as the curved track 33a of the key allows. The disk 4 is thereby turned in a known manner (after the segment has released the lock 5) as many divisions as the numerical value of the tangent indicates. The set numerical value can be read in a numerical window 48, where the set number of the element 4c comes into view. At the same time as the segment is rotated, a rotation of the tangent bridge 37, 38 is also effected by means of the joint 36, which transfers its movement over the joint 41 to the arm 29, which is thereby brought to the one in fig. 6 shown position. The locking wheel 23 is released from the hook 25 and the rotor is thus free to perform the movement that the spring 19 seeks to impart to it. The rotor is pulled by the spring to the left, and if the finger now releases the key, the locking wheel 23 above the roller 31 pushes back both the bridge and the segment 44 as well as the key 33 back to the starting position. This therefore takes place at the same time as the rotor moves one step. During the first part of the rotor step, the roller 31 is not affected, more precisely during the part corresponding to the movement of the rotor, as long a stretch as is necessary for the track 4d which corresponds to the set digit, to be guided up onto the back 16 of the ruler, for during this part of the step the segment 44 and the disc 4 must be prevented from turning. The design of the hooks 23a interacting with the roller 31 is such that the segment manages to become free from engagement with the disk 4 during the continued part of the step before the push back begins and the return is completed, so that the segment has come out of the path of the next setting disk when this slides forward to its setting position. The setting dial that follows is now ready to be set. By selecting the springs 30, 46 and 19 in an appropriate manner, a very comfortable key press is obtained without complicating the machine's construction for that reason. 1. Device for keyboards for calculators, preferably for simpler ones of the pinwheel type, where each number setting key when pressed affects recording organs in an actuator (rotor) and triggers its step-by-step movement after each set digit, and where the key pressure is reduced by one or more springs (30 , 46) which in a known manner affects one or more knee-joint-like organs (38, 41, 37, 42, 43 and 44) which, when a key is pressed down a short distance, are led past an upper dead position, after which the spring or springs ( 30, 46) impact on the knee-joint-like organs helps the setting finger to press the key down so far that the setting work in the rotor is carried out, characterized in that the drive device for the step-by-step movement is arranged to tension the spring or springs (30, 46) which contributes to the key being pressed down and, as a result, reduces the necessary manual pressure on the keys. 2. Device according to claim 1, characterized in that the step-by-step movement of the setting rotor (A) is provided by a strong spring (19) which simultaneously with the step movement leads the knee-joint-like organs (38, 42, 43, 44) back to the starting position. 3. Device according to claim 1 or 2, characterized in that the step displacement spring (19) of the rotor (A) over the transmission elements (21, 22, 23) connected to the rotor affects a locking device (25, 29) which during the end of its movement during each rowing step, they bring the knee joint-like organs (36, 42, 43, 44) back to their starting position. 4. Device according to claim 3, characterized in that one of the knee-joint-like organs consists of a brace (38) cooperating with the tangents which, via a joint system (41, 47), both cooperates with the locking mechanism (29) and with an adjustment segment (44) for setting the desired digit in the rotor (A). 5. Device according to claim 4, characterized in that the setting segment (44) is connected to a hoop (42, 43, 44) which forms the second knee joint-like organ, affected by one of the springs (46).