DE408087C - Device for remote actuation of the crank rotation and slide displacement of calculating machines and similar machines - Google Patents

Description

Device for remote control of the crank rotation and slide displacement of calculating machines and similar machines. Calculating machines are used for arithmetic and numbers or calculating apparatus used, which are usually of such a size that they do not conveniently enough to be placed next to the documents on which the arithmetic takes place can.

If you calculate z. B. with a slide rule tables from with many Numbers and digits, that's how you put the slide rule in front of you on the paper, so that you can get the numbers on the paper and the arithmetic on your slide rule can easily overlook.

This also applies to the more extensive number roles. switchgear hzw. Do calculating machines (also with sliders or the like instead of counting rollers) to be able to proceed according to the present inventive concept as follows.

You have the setting uris of the numbers on the calculating machine that apart stands because it takes up far too much space on paper, it is made that way the actual mechanical computing (cranking) that follows is an annoying intermediate process. So far he has not been able to record on paper where the actual arithmetic process was recorded is and where it must be pursued, be made, as in the case where one this calculation on a piece of paper, which is placed close to the calculation process put without a machine. Either you have to use the heavy calculating machine and approach the arithmetic process (lying in front of the computer), or you have to be Turn your attention away from the paper to the calculating machine, yourself turn to the adding machine. Both are, even if you have a lot of calculation documents in front of him on the table, extremely annoying and time-consuming. A machine should not only calculate correctly, it should also be convenient to use and save time in not having to keep moving them back and forth and must adjust. This is also of great concern because namely to carry out these distracting mechanical manipulations continuously. are. Because of their frequency, they are very important. Can you mind how it is the case according to the present inventive concept, the set machine there leave it where it is and don't have to turn the mechanical one every time To carry out the calculation, to turn to it and to adjust it so that one can to turn the crank (the right hand turns the crank, the left hand must turn the Hold the machine so tight that it does not slip, and so one must keep paying attention away from the paper and onto the machine), this means a great progress in machine computing compared to the current known processes.

If you work according to the present invention, you can while you has the arithmetic logic device lying in front of him and operates it, his attention after as before the billing process. Anyway, that's the distraction of the calculator the arithmetic process is much less than if it were during this time must alternately turn completely to the calculating machine, without this about would calculate more accurately or faster. The calculating machine then receives a special one Actuating device for turning the crank and switching the slide. The operating apparatus is spatially separated from the calculating machine, so that the actuating apparatus brought into close proximity to the numerical material that is to be expected the latter can be overlooked at the same time and comfortably, as in the case of Slide rule was marked. The calculating machine, on the other hand, is sidelined set up easily accessible. On this one then only needs the setting and delete manually as usual. to become.

In the accompanying drawing (Fig. I) the arrangement is shown schematically in Top view shown.

A means the calculating machine or the like, B the paper or the like, on which the numbers (tables, etc.) are written, C the operating device, D, the transmission. The latter can be done mechanically, pneumatically or electrically will.

The process is now that in A the settings as usual be made. At a glance you can see the numbers on A and the small one Actuating apparatus C such that one z. B. in roller calculators, where every revolution corresponds to an addition or subtraction process, for example by pressing a Pushbutton in C electrically or in another of the transmission modes just described triggers one revolution of the drive parts of the calculating machine by transmission through Di. If you press the next button or button or some other triggering device in C, the opposite rotation is accomplished. You add or subtract (or multiplied or divided).

The others. two buttons or buttons in C-are used to move positions the slide of the recorder in A.

The result is read off in the result set in A as usual. This is followed by the deletion in A; and the calculation process can be repeated accordingly.

The circuit diagram for this is given in Fig. A means in it as in Fig. i, the apparatus of the calculating machine; in this case the one for the person in charge Purpose additional apparatus of the adding machine to make the latter out of the ordinary Crank operated adding machine to convert to remote operated. D means the Transmission, as in Fig. I, C the actuator, as in. Fig. 2, but only in relation to the rotation of the crank of the calculating machine (not the slide adjustment). E. means in the present case an electric motor for the crank rotation, which with the crankshaft is coupled directly or with a reduction gear. Sitting on the same while F, an electromagnetically located either in the main or shunt current to the motor E. Precision arre @ tier device with solenoid H, the exact zero position every time the crank fixes or releases. Sitting on the same while, separately or with F combined in one piece, a slip ring device G, which is in the crank zero position keeps the current interrupted for both clockwise and counter-clockwise rotation by the slot of the slip ring is designed as an insulating piece and in which the sliding contact in the zero position in the middle of the insulating piece between the slip ring ends is located.

The electric motor (or other switching device), which is set up for both clockwise and counterclockwise rotation, is controlled by switch L and solenoids I and I (by the double keyboard M, which corresponds to part of the actuation of C in Fig , activated either forwards or backwards via line D.

The process is that, as soon as the calculator crank is in its zero position (when operated remotely, the zero position fixation of the crank, which fixes the exact zero position when calculating without a remote drive, is previously uncoupled), the lock F and H and the slip ring set G in the fixed zero position. Assume that the switch L, as shown in full lines in Fig. 2, is in the position that corresponds to a left turn, and a left turn is to be made. The left double button M is now depressed. The upper contact closes at the same time as the lower one. The upper contact (the double button could also be designed so that the upper one shown in the diagram is the lower one or one of adjacent contacts ) would set the motor switch L to the left by means of the solenoid I (. (In the present case this is already from Since the lower contact is also closed at the same time, the insulating piece of slip ring G is bridged by it, motor F_ receives power, and F is unlocked by H. The motor now rotates to the left is therefore moved to the left and closes the circuit over the slip ring so that the: motor must continue to run even when the double button / Y1 is released, and so long and so far, until the slip contact is swept over the whole slip ring and the current interrupts again in the zero position.

With this, actuated by a spring, the core of the solenoid H falls into the locking notch of F, and the exact zero position is ensured by the special training the locking notch in conjunction with the slip ring distances to the left and right of the Restored slip ring ends.

The motor thus works by means of the slip ring insulating piece momentarily bridged by the double button M only during a full revolution, without being dependent on the longer or shorter contact making in M.

If you want to make a clockwise rotation, you press the right double button of M. The process is repeated as above, only with the difference that the motor or the 'shaft E, F, G rotates clockwise, because when you press the double button the motor switch L would be switched to the right by the upper button. Instead of a motor E, a lifting magnet working with a corresponding translation can also be attached, which works with both right and left stroke and rotates the shaft E, F, G accordingly by 360 ° to the right or left. In this case, the motor switch L will be omitted, so that the control magnets I and I (become lifting magnets. The motor magnetic circuit E, H, G shown in Fig I and I (is operated as a lifting magnet, but H repeatedly unlocks and G controls when the current passes through.

In both cases it is the main task of the switching device that after the momentary triggering by the button, the self-control during a freely selectable right or left rotation takes over and always again returns to the initial zero position without the usual manual operation of the machine disturb.

The diagram of the slide shift is shown in Fig. 3.

It means here again: A the apparatus on the calculating machine, after coupling to the latter and switching off the usual slide switch for direct manual operation, the slide movement is now carried out by the operation Button etc. Control C is put into operation by means of remote transmission D.

D means again, as in Fig. 2, the remote transmission for the carriage movement, that when the process of Ab: b.2 (rotation of the machine) is combined with Fig. 3 (Slide adjustment of the machine) with remote transmission for the rotation of the machine can be collapsed.

C means again, as in Fig. A, the control by buttons etc., which, in contrast to the control in Fig. a, consists of simple buttons. The left button is for moving the slide to the left, the right button for the carriage movement to the right.

The slide N of the calculating machine is after its decoupling from Manual operation by means of a precision locking device newly attached to the slide: g O with the signal box P, which is in a suitable place, for example in the floor box, on which the manual calculating machine is placed by means of adjustment pins etc., coupled so that the exact slide setting to the setting mechanism of the calculating machine is guaranteed. Because the grid division in the calculating machine for the exact slide adjustment to the adjustment device, which is now locked by locking is out of action, is now taken over by the new switchgear. Of course the existing grid on the machine can also be used directly for remote control to be set up. But here for the sake of clarity and because it is intended for any Machines with posts or pusher devices can be used as shown in Fig. 3 outlined arrangement should be discussed.

The interlocking P consists of one or more superimposed or next to each other and in a suitable guide easily displaceable racks, such that for the exact fixing of the slide position to the setting mechanism with a rack the same notches are provided on both sides. For moving to the right is also a saw-shaped rack with tooth flanks rising to the left, for the movement to the left a saw-shaped rack with rising to the right Tooth flanks provided.

The pitches of the three racks are equal and dyke the slide grid division on the actual calculating machine. Of course A different pitch of the racks can also be used if appropriate Translation is taken care of.

For precise specification of the setting of the signal box each time P serves the rack lock Q, which is designed so that the into the rack intervening. Locking cone corrected the exact position by means of spring pressure and the Holds the counter slide in this.

The process of the remote-controlled slide displacement is as follows: If you press the right button of the apparatus C, while Q is unlocked, the magnet R gets current with the help of the circuit closed by the button. Its armature, which can be adjusted by adjusting screws and which is attached to the lever T to be used as a pivot point at U, is tightened and the lever retraction spring V is tensioned. The bolt W at the end of the lever T is moved to the right and immediately takes the tie rod a attached to it with it, which lifts the left-hand rack shift lever X on the left side of the apparatus, so that the rack group P is free from the left-hand shift lock. (Since the left side is designed and worked exactly like the right side of the apparatus, the process of the left side - also on the drawing of the right side - can be followed.) The tie rods a each have a spring housing e, the springs of which are set in this way are, da.ß when the lever T is tightened and the tie rods a are carried along by the bolt W, the notching of the rack locks Y is accomplished immediately, however. as the tie rods are tightened further, they can "lengthen" in the spring housing e so as not to drive the notch of Y 'too far with the help of the angle lever b against the pin c of the rack and pinion locking lever X, which takes place against an adjustable stop pin to make elastic. A spring tensioned between the pin c and the bolt W of the lever T always applies the bolt to the end of the elongated hole Z facing towards the center. Since the drive pin W on the lever T moves in an adjustable longitudinal slot Z of the pull lever X, the rack P can only be carried to the right as soon as the above-mentioned notch of Y has taken place on the other (left) side. The purpose of this is to avoid blockages which would otherwise occur if the entire circuit were simultaneous. The pull lever X rotates around the bolt W in the longitudinal slot and is kept pressed against the rack by the spring d, which acts at the other end of the lever of X, so that when the current surge in R is released, the armature by the spring V is withdrawn again, so that furthermore the pull lever X of the rack and pinion locking mechanism with the sloping pull hook Y can slide over the teeth back into its rest position. There is therefore a progression to the right by one tooth gap, that is to say by one point on the computing machine slide. At the same time, when the current subsides, the spring action causes the solenoid Q to fall back into a toothed rack groove, thereby specifying the position of the slide in relation to the calculating machine setting mechanism. When the shift lever T goes back into its rest position, the spring housing e relaxes in the pull rod a, and the angle lever b also goes back into the rest position, so that at the same time the latching of Y on the left side. inducing.

In the rest position, the self-coupled toothed racks P, which form a whole, are threefold locked and made more precise; namely through the fixation lock Q and the two switching noses Y right and Y left. The slide N, which is firmly coupled to the rack and pinion lock P by O, is also fixed. If you want to adjust it by hand, without remote control, you only need to uncouple it at O from the gearshift P, to put the calculating machine's grid lock into action again, and you can calculate either by hand or by remote control.

Switching to the left is exactly the same as that just described to the right. It goes without saying that all parts can be made adjustable in order to achieve the precise effect and permanent to maintain.

The control apparatuses C of Figs. 2 and 3 are combined if necessary in a small container box or the like, to be conveniently placed on the calculation pad to be able to. The tactile heads are designed so that they can be reached with the finger or can be operated with a pencil or the like. They are united in groups and provided with the appropriate designations, as they are in the calculating machine required are.

An embodiment of the electrically operated remotely operated apparatus. A crank and number roller calculator can be seen from Figs., 1 to @ i3, and while taking into account the preliminary conditions that on the calculating machine significant changes are not to be made, further that the calculating machine at any time and without further tools or aids by simple manual changeover can be operated as usual. It goes without saying that the remote operator can be adapted also with a significant change in the calculating machine to those in question Sharing is done in order to remain permanent.

Drive of the crank and locking in neutral position: Fig. Q. results Front view of the crank drive, Fig.5 side view, Fig.6 top view. In fig. q. sits on the hub of the normal hand crank attached to the shaft of the machine loosely the large toothed wheel f, which in the case of the remote drive with a suitable latching device ä is coupled with the hand crank, while at the same time the manual operation in Knob of the hand crank existing i zero fixation by pulling back and turning except Activity is set.

The large gear f meshes with a smaller gear that is on the Frame block stump into which the zero fixation for manual operation snaps, runs, after this stump a suitable turning for the gear hole for the purpose had received. From this cogwheel further translations lead to the one in the base located. Drive apparatus on which the calculating machine is attached with dowel pins and locking is put on.

The other; Stand block stump, which is the exposed second bearing of the crankshaft is also made with a suitable twist and pushed-on Ring provided, against. that the large gear f starts to give this a suitable guide admit.

The big gear is built so that it's the calculating machine facing cavity on insulating material a slip ring St is attached, which is identical with the slip ring Gr from Fig.2 of the diagram and which is the point of interruption i (Fig. 5), which is filled with insulating material. The entry and exit of the current takes place through the slip ring spring contacts k, k (Fig.q., 5 and 6), which are insulated and attached to the frame built around the crankshaft.

The frame has a bearing at the top for the zero position locking lever 7. (identical to F of Fig. 2), in the middle the guides for the anchor pulling elements, which also serve as an abutment for the snap-in coil springs. the two pulling elements that operate the lever i by means of a balancer are around the Machine shaft stored around, they end below at the armature of the below the bent gesture sheet magnet, which acts as a main or shunt electromagnet can be formed.

This frame is set up in such a way that it can be easily removed as required can be removed from the machine. The clamps are also attached to the frame for the lines insulated. It forms the frame of such a .in. closed Unit without significantly changing the calculating machine.

Compared to that. Scheme in Fig.2, the frame together with the large gear wheel forms the above-described device G, H, F. The mechanical design can of course be further modified, depending on the current, type, voltage u, sw.

The large gear wheel f (Fig. 4.) has a toothless one next to the gear rim Wreath with the locking notch in which the lever l with a suitably shaped wedge edge or the roller snaps into place as soon as the crank is in the zero position. in the the rest grinds or rolls the lever blade L or roller on the toothless rim, as soon as it is triggered, until after one turn to the right or left the zero position is reached again and made more precise by the springs of the anchor pulling elements has been.

If an electric motor E is used according to the circuit in Fig. 2, then this together with its electromagnetic switch L in an underframe or box be housed under the adding machine, so that the motor with a suitable gear ratio into the small gear in Fig. q. intervenes. In this way the adding machine, if they are fitted with a suitable fitting device (pointed screws, guide corner, lockable Lock, etc.) is placed on the box or the base, easily engaged be brought with the engine or its wheels. Since the zero position, lungsprecision takes place on the crank of the calculating machine itself, the motor transmission gear position is incorrect made irrelevant. The calculating machine can then just as easily without special auxiliary tools can be removed from the underframe if care is taken that the line coupling also by means of suitable contact devices (spring contacts, plug contacts; etc. can be done precisely. For this purpose, in the subset of the calculating machine the contacts remaining on it are embedded, while the corresponding ones on the base Mating contacts sit, so that the guided and thus more precise placement of the calculating machine the precise contact connection is conveyed to the subframe at the same time. the Both types of precision can also be connected to one another, so that the coupling of the contacts at the same time the specification of the intervention of the motor or how described later below, also brings about that of the slide switch mechanism.

Figs. 7, 8, 9 show a motor solenoid switch for a motor with two poles. Instead of the two-pole you can also add more Switch blade multi-pole switchings are made.

Fig. 7 shows such a switch with electromagnetic actuation from the front, Fig. 8 from the side, Fig. 9 from above. This switch corresponds to L. in the scheme. Fig. 2, with the only difference that there I and K solenoid electromagnets, in Fig. 7, 8, 9, however, armature electromagnets with a U-shaped closed magnetic circuit have been used. This armature switch consists of a base plate which the; two armature electromagnets for remote control by 'the button M (Fig.2) are mounted so that the armature to the poles through the plate carrying the clamps can get through. The anchors are connected to insulating pieces by clamps, so that they rotate with the pins of the insulating pieces in the switch blades and can adjust. The switch blades rotate in the center contact pieces .. On the six contact pieces; that carry the contact springs for the switch blades then the lines are connected according to the known switchover.

Figs. Io to 13 represent an embodiment of the slide control mechanism corresponding to the diagram in fig. correspond. It is therefore the scheme for explaining the Fig. 3 has been said to readily fig. Transferred to io to 1 3.

Fig. Io gives a view of the top of the calculating machine base attached Schli.ttenschaltwerkes, - ahead at the same time the transmission of the switching process on the calculating machine slide and the coupling of both parts can be removed.

Fig. I i results in the section in the central axis A-B of Fig. I o, Fig. 12 the section C-D of Fig. I o. Fig. 13 gives a plan view of the arrangement the electromagnet.

From Figs attached transfer bracket is inserted and determined in this position. Instead of the coupling device shown here, a different one can also be selected so that the slide switchgear is not attached to the false floor of the underframe, but rather to the slide base of the slide N of the calculating machine itself, so that a slight uncoupling is also possible here if the calculating machine to continue to be operated by hand or to be completely removed from the underframe. If the calculating machine is to be completely designed to be remotely operated for the duration, then all of the devices described from the beginning up to this point can be designed in a correspondingly modified manner. Because in the present case the device should first be described in such a way that it can be subsequently attached to an already existing crank calculating machine with counting rollers without any significant changes. . Io to 1 3 is apparent from the figure how the whole switching mechanism can be made kompendiös in one piece, so it däß as a whole acts, with no other besides him lying fixtures to require Anbringungsörter etc; because all parts are easily accessible and clearly arranged on a simple frame. Here too, for the sake of clarity, all lines and associated terminals have been omitted.

The shift rack P indicated schematically in the scheme of Fig Individual racks are disassembled there for the sake of a clearer diagram are shown in more detail in Fig. io and especially in Fig. i i. They are all three next to each other with their teeth facing down, so that the bar 3, which is used for the correct positional precision, lies in the middle, while on both sides next to it the right and left shifting racks i and 2 are arranged. Around They are not made of one piece, so that they can be milled throughout with the base plate, but they are individually screwed onto it. First with of this they form a prismatic whole, which in the correspondingly executed Guide bar slides so that the Verholzähne Y coming from below mediates gaps that are left free can intervene in them directly from below.

Likewise, in this manner the rack prism upwards against the cover so the Verholklemmen Y relieves any play in engages from below through corresponding gap by springs (Fig. Ii) against the rack upwards pressed cone into the center rod, a fixed pressing, the transfer or in the specification O compensating.

Claims (1)

PATENT CLAIMS; i. Device for remote actuation of the crank rotation and slide displacement of calculating machines and similar machines, characterized in that the manual settings corresponding to the calculation process, which cause the crank rotation and slide movement, are spatially separated from the calculating machine by means of a freely movable calculating switchgear (B, C in Fig. I) be made, so that either the calculating machine can be operated either directly by hand, as usual, or for the crank rotation and slide movement with the remote control. Device according to Claim i, characterized in that the calculating machine or the like can be connected to an additional frame containing the remote control tools (for turning the crank and sliding the slide), which can be easily and precisely coupled and removed, without influencing the manual operation. 3. Device according to claim i, characterized in that the control of the hand crank by double pushbuttons (M) takes place either forwards or backwards with simultaneous triggering of the locking parts (H) holding the drive parts in the zero position, that the control causes a full revolution of the drive parts and it locks again in the zero position after completion of the rotation and that finally the control parts can be easily and precisely coupled with the hand crank. .l. Device according to claim i, characterized in that the slide is shifted by one position each by a pair of buttons (C in Fig. 3) optionally to the right or left by means of a three-part rack and pinion gear, which is made up of a left and a right electromagnetic lever switch (R, T, W , X, Y, a, b, c) and an electromagnet setting fixation (Q), so that first the unlocking of the setting fixation (Q) and the other side, inactive rack gear (Y) and only then the further indexing to the right or left by depending a point takes place, wherein this slide displacement device can be easily and precisely coupled to the computing slide. 5. Device according to claim i, characterized by the use of a multi-pole magnetic switch with rotatable armatures, which directly influences the switch blade.