DE919791C - Machine for storing preferably calculated numerical values - Google Patents

Description

Machine for storing preferably calculated numerical values The invention relates to a machine for storing preferably calculated Digit values, d. H. on one in the field of booking machines, calculating machines, Punch card machines or similar machines lying application of a large number of storage units within such a machine. The use of such a Machine has so far mostly failed due to the fact that the memory elements for the desired larger number of storage units are too large and too heavy and therefore a very heavy and space-consuming machine would arise, if the actually desired and required number of storage units is in it would be accommodated. The relevant Technology both circular and linear moving storage elements application that according to embody a certain number with a certain amount of movement. It is there The ten switching device has already become known for both types of storage elements to be assigned jointly to a large number of storage units, as in Connection with it to carry out the arithmetic work by an auxiliary arithmetic unit and the memory elements only for holding digits, i.e. as memory elements to be used in the narrower sense and not at the same time as computational elements. Such memory members are expediently arranged according to their value intended, d. H. several storage units are combined into a group and within This group combines the elements of equal status into a subgroup.

The known proposals all have the disadvantage that the memory elements are too large for a really large number of storage units. You restrict thereby on the choice of a direction of movement of the storage body, be it one linear, be it a circular movement. The invention therefore seeks a new one, this one To create disadvantages avoiding memory element and achieved that using of the principle, not just one direction of movement of a storage body for the identification of a memory value, but two different directions of movement, namely to combine a linear and a circular to embody the basic numbers. According to the concept of the invention, in particular a helical body is used Representation of a digit value used. This storage element is prismatic Approaches provided at both ends, namely one approach is used to block, the other for engaging a coupling member to adjust the storage member. The coupling member is therefore according to the invention as a prismatic coupling approach of the memory member corresponding, wrench-like head formed.

The arrangement according to the invention has the advantage that the storage elements can be compressed into an extremely small space and, because of their small size, also represent a low mass. It is Z. B. in application of the inventive concept to the storage of several storage groups in a drum possible to provide the storage elements of a group of stores under, vertweiser summary of the storage elements of the same value at a distance of 3 mm in a row and these rows on the circumference of a drum in To allow spacing of 3, i4 (n) to follow one another. With ten-digit rows of storage units and the combination of ten storage units in a row, the storage drum is only 1o X 3 X 10 mm = 30 cm long. Arranging a hundred such rows of storage units on the circumference of a drum results in a drum circumference of DX n = 100 X 3, 14 mm, thus a drum diameter of only 10 cm, with a thousand memories being arranged in this drum. This example clearly shows the unusual performance of the new storage principle.

According to a further concept of the invention, there is an intermediate switchgear provided with a particularly low mass, which on the one hand with the storage elements works together and on the other hand the accepted values to the main switchgear outputs or takes over the values to be transmitted from the main switchgear. This arrangement an intermediate switchgear with particularly small masses has the meaning that a destruction of the fine screw threads by inertia forces, for example when Sumzidhen is avoided. The resulting complication of the circuit diagram is due to the advantage of complete security despite the small size of the parts balanced. However, according to an electrical embodiment of the inventive concept also directly from one connected to the coupling member of the storage member Contact control roller of the drive of an arithmetic unit, printing unit or the like. Performed will. According to the invention, the contacts or contact control means are also here Distributed helically on the contact roller, if not immediately that Coupling pinion connected to the coupling member is used as a contact control roller will. The embodiments of the invention are both to be considered as examples. Of course, in connection with the new storage unit principle, everyone can known switchgear form and form of contact control are used. Of the Inventive idea, which is preferably in the form of a helical member is embodied is not limited to this either, but rather every two-dimensional one Movement, especially the combination of circular and linear movements of one Means of value embodiment, corresponds to the idea of the invention.

Single screw-shaped link, the numerical values determined during measurements holds, is already known in the form of the micrometer screw. A however, such a measuring instrument cannot be used with a memory element according to the invention be compared, since it cannot be used as a storage element within the meaning of the invention is, d. H. that neither adding nor subtracting nor adding up processes with him are feasible.

The invention is explained below in two exemplary embodiments. Fig. I shows the storage elements with the associated coupling elements in an enlarged view, Fig.2 - the blocking of a memory element in a view perpendicular to Fig. i, Fig. 3 the auxiliary switchgear and the main switchgear, Fig.q. the coupling of a printing unit, Fig. 5 an electrical embodiment for a device according to the invention.

The exemplary embodiment is limited because of the simplification of the Representation on the explanation of a storage unit group of only three storage units; the normal, however, is the combination of about ten storage units in be a series of storage units, as already introduced in the explanation of the drum-shaped Arrangement was highlighted.

In a carrier strip i are provided with threads at intervals of 3 mm Bores 2 are provided in which the storage elements with their threaded bolts 3 are movable. A square shoulder is attached to the threaded bolts 3 .4 on, of resilient plates 5 in the Fig, 2 evident Way is resiliently included, so that the memory elements in their respective setting position be held resiliently. The resilient plates 5 are a comb-like locking member 6 summarized. At the threaded bolt 3 of the storage members a closes Stop disk 7, which is crowned by a larger square shoulder 8.

A wrench-like design works with the square shoulder 8 Coupling head 9 together, which for this purpose has a square recess i i owns that can access the approach 8. The coupling heads 9 are in one distance from each other determined by the number of storage units in a storage unit group provided only once for each decimal place. They are stored in a carrier 12, which is adjustable in a manner known per se both parallel to itself in order to to establish the coupling connection of the coupling heads 9 with the lugs 8, such as is also displaceable in the direction of its longitudinal axis to selectively one of the storage units of the storage group.

The axis 13 of the coupling head penetrates the carrier 12 and is rigidly connected to a wide coupling pinion 14 on the other side of the carrier, which is in engagement with an auxiliary switching rack 15. The width of the clutch pinion 14 results from the axial movement required to enable the coupling of parts 8, 9.

The auxiliary rack 15, which must therefore be able to move longitudinally of the carrier 12 to follow represents an auxiliary switching mechanism. It is slidably mounted and is pulled to the left by a spring 16 as shown in Fig. 3 when the locking block 17 recedes. A coupling attachment 18 enables coupling with the main shift rod i9, which is connected to a pin of the drive rack 22 through a fork slot 21 is. The pivotably mounted switching segment 23 engages in the drive rack 22, whose stop 24 cooperates with the keys 25. The switching segment 23 is standing under the action of a spring 26 so that the racks coupled together 19, 22 can be pulled to the left according to Fig. 3, if the controlled by the N machine Locking block 27 is released.

The rack i9 is mounted displaceably in its longitudinal direction in a fork 28 , while the fork itself is displaceable perpendicular to the longitudinal axis of the rack. This adjusting movement of the fork 28 brings the toothing of the rack i9 into engagement with the coupling attachment 18 of the auxiliary switching mechanism, and the racks 15, i9 and 22 are thus connected to one another in a joint movement.

Above that, which is also provided with a toothing on its upper side Toothed rack 22, the computer 31 is mounted in swivel arms 32, so that its arithmetic unit wheels can be pivoted into and out of the toothing of the racks 22. A cone 33 works with a spring-loaded locking mechanism for the arithmetic unit wheels Latch 3q. together, with which the zero stop of the arithmetic unit wheels is determined.

A printing unit can now also be attached to the rack 22 in the manner shown in Fig. q. be coupled in an obvious manner. The rack 22 has one after upwardly directed coupling lug 35, with which the toothing one in the direction its longitudinal axis displaceable rack 36 can be brought into engagement. This engagement is achieved in that the rack 36 is also in a adjustable fork 37 is mounted. The rack 36 is through a fork slot 38 connected to a further shift rack 39, with the teeth of which the type wheels 41 are engaged. A spring 42 acts on the type rack 39 and adjusts it this according to the extent released by the locking block 43.

In Fig. 5 is a particularly simple electrical embodiment of the invention shown. Thereafter, the clutch pinion 14 is a control roller 51 connected, on which in a corresponding to the screw thread of the storage elements Distribution contact lugs 52 are arranged. This increased contact points push a resilient contact arm 53 against a second contact arm 54., so that of a current source 55 outgoing current reaches a solenoid 56 and this makes you respond. The solenoid 56 receives as many current surges as contact approaches the contact roller 51 pass under the contact arm 53, d. H. the anchor of this Switching solenoids are used in a number corresponding to the number that is switched moved by electrical surges. These current surges are caused by the armature 57 and a pawl 58 a progression of one as a number wheel or character wheel or as a transmission gear a gear designed as a numerical or printing mechanism.

The arrangements described work in the following way: A. First let us explain the mechanical example, namely the storage of a value as well as the summation process are described.

I. The storage of a value The switching mechanism 23, 24 and with racks 19, 22 connected to it decrease the value of the pressed key 25 as soon as the locking block 27 released by the machine control, d. H. according to Fig. 3 is moved to the left. The computer 31 is then coupled to the racks 22, and the locking block 27 leads the rear derailleurs back to their basic position, wherein the keyed in value is transferred to the computer. The calculator's counting wheels are moved counterclockwise during this process according to Ab-b- 3.

The computer is then decoupled from the racks 22 again, and the pressed key 25 is cleared. At the same time is dependent on not Means explained in more detail in a manner known per se, the selection of the desired Storage- Work, be it depending on keys, be it depending of punch cards or the like. The carrier 12 is after the selection movement shifted parallel to itself, d. H. the coupling body 9 are on the Square shoulders of the storage elements of the selected storage unit pushed. Of the Locking block 17 is released. So that the auxiliary racks 15 are screwed the storage elements are withdrawn as far as it will go as far as the stop of the plate 7 corresponds to the position of the storage elements. Every quarter turn of the memory links corresponds to a unit of value. The racks ig, 20 are released at the same time, so that they reach their left end position under the action of the spring 26.

The computer 31 is now swiveled into the racks 22 again. At the same time, the coupling connection between the racks 15 and ig is established by lifting the fork 28. The coupling connection 8, 9 can thus be released even if special locking means for securing the coupling heads 9 were not provided. Now the locking blocks 17 bring the auxiliary racks 15 back to the right (according to Fig. 3) and thus transfer the value taken from the memory elements to the computer 31, in which the sum of the keyed in value and the taken value is calculated. However, for the purpose of performing the numeric switching in the arithmetic unit wheels, the computer has to be decoupled again from the racks 22 and the numeric switching must be carried out. At the same time, however, the decoupling of the racks 15 and i9 is carried out. The racks i9 are returned to their right end position by means of the locking block 27. Then there is a new coupling of the arithmetic unit wheels 3i with the gear racks 22, and the value calculated in the computer is transferred to the gear racks i9, 22 under the action of the spring 26, the pin 33 limiting their setting. At the same time, the racks 15 run back into their left end position.

The racks i9 and 15 are now coupled by means of the coupling lug 18 by lifting the fork 28, and at the same time the storage elements are again coupled to the coupling heads 9 while the computer 3 i is uncoupled from the racks 22. The locking block 27 now brings the switching racks 19,22 in the right basic position, whereby it. In the different locations at different times to rack 22, i9 incident, corresponding to the previous setting by the computer So the different values of the gear racks i9, 22 are transferred to the auxiliary racks 15 and thus due to the existing clutch 8, 9 on the storage elements, which are unscrewed from their support plate i according to the transferred value, that is, unscrewed by as many quarter turns as the has corresponding digit units. Finally, the storage elements 8 and the coupling heads g are uncoupled and the racks 15, 19 are uncoupled from one another, and the locking blocks 17 bring the auxiliary racks 15 back completely into their right-hand basic position.

So much for right and left position or horizontal and is spoken more vertically, it is of course only about the Reference to the drawing, which in no way indicates the position of the parts in the execution needs to conform.

II. The Sum Draw Process The sum draw process is very simple. It takes place after the selection proceeding in the same way as with the addition of the storage unit a coupling of the storage elements with the auxiliary racks 15; the springs 16 pull the auxiliary racks 15 according to the value of the storage members until they rest with their stop plate 7 on the support plate i, wherein likewise, every quarter turn of the storage elements corresponds to one unit. On that the coupling of the racks ig, 22 with the auxiliary racks 15 and through the approach 35 with the printing unit 41.

When a total is withdrawn, the storage elements are now uncoupled, on the other hand, when a subtotal is drawn, the coupling of the storage elements remains exist. In any case, however, is now contained in the auxiliary racks 15 Value via the interconnected racks i9, 22, 36, 39 in the printing unit 41 introduced, in which by means of the locking block 17, the auxiliary racks in their right end position can be pushed back. The spring 26 supports this movement with. After the printing unit has been decoupled (coupling attachment 35), the Gear racks i9, 22 returned to their right end position.

B. The electrical embodiment. The electrical embodiment only requires a supplement for the in terms of their mode of action Addition process, since the summation process can already be found in the description of the Structure results.

The addition process can also be mechanical in that of the first embodiment described manner. However, it can also be an electromagnetic switchgear drive either act directly on a ratchet wheel connected to the clutch pinions 14 or on the auxiliary racks 15. The control of the magnetic pulses can then be carried out in a known manner Way can be effected depending on a keying in or a punch card.

Claims (17)

PATENT CLAIMS: i. Machine for performing arithmetic operations, in particular for storing preferably calculated numerical values, the storage units of which have adjustable storage elements to embody the storage value, characterized in that the storage elements (3, 4, 7, 3, 4, 7, 8) positions that correspond to a certain numerical value, the result of combined adjustment movements, e.g. B. a helical adjustment movement are. 2nd machine according to claim i, characterized in that the storage element (3, 4, 7, 8) as helical body is formed and the value transfer to the memory members by unscrewing, the buzzing by screwing in the storage element takes place and that preferably a fraction of a full rotation of a storage unit is equivalent to. 3. Machine according to claim i and 2, characterized by a stop disc (7), which becomes effective through the linear movement of the storage element and in the serves as a zero stop by screwing in the cumulative pulling processes. 4. Machine according to claim 2, characterized in that the storage element (3, 4, 7, 8) is provided with prismatic extensions at both ends, one of which (4) to fix the storage element in the respective storage position, the other (8) is used for coupling with the adjusting members (9, 14, 15). 5. Machine according to claim 4, characterized in that a switching pinion with the coupling member (9, i i) (14) is connected, which is in permanent engagement with the shift rack (15) of the Auxiliary switching mechanism even when it is moved sideways for the purpose of coupling with the memories. 6. Machine according to claim 4, characterized in that a storage unit corresponding rotation of the storage member to the angle of a Side of the prismatic locking approach (4) corresponds. 7. Machine according to claim 5, characterized in that the clutch pinion (14) is one of the number of sides of the prismatic locking projection (4) has a corresponding number of teeth. B. Machine according to Claim 7, characterized in that the coupling pinion (14) is directly through its teeth or through a contact roller (51) connected to it one of the Number of memory rotations corresponds to the number of contact closures when pulling together causes. 9. Machine according to claim 4, characterized in that the storage members are arranged in a known manner in places and the coupling member (9, 11) is only provided once for each place value. 1o. Machine according to claim 4 and 9, characterized in that for the memories combined in a group common holding means (5, 6) for securing the storage elements in the setting position are provided, the comb-like spring tongues cut out of a plate (6) (5) form. i i. Machine according to Claim 2, characterized in that an intermediate switching mechanism of particularly low mass is provided, which on the one hand with the storage elements, on the other hand cooperates with a main switchgear. 12. Machine according to claim i i, characterized in that the auxiliary switching mechanism is designed as a spring switching mechanism and after acceptance of a value and for the return transfer of a value with the main switchgear (19, 22, 23) can be coupled by a coupling attachment (18). 13. Machine according to claim 12, characterized in that the calculation of the new memory value in one with the main switching element cooperating arithmetic unit (31) takes place. 14. Machine according to claim i and 2, characterized by the combination of the memories in groups arranged in a straight line, preferably subdivided in places, and the distribution of these groups on the circumference of a storage drum in such a way that that the coupling lugs (8) are directed radially outward. 15. Machine for Carrying out arithmetic operations, in particular for storing preferably calculated numerical values, their storage units to embody the stored value have adjustable storage members, characterized in that combined Adjustment movements as well as the selection of one of several arithmetic units (coordinate selection) as well as the loading or emptying of the selected arithmetic unit. 16. Machine according to Claim 15, characterized in that the combined adjusting movement to select one of several arithmetic units a circular movement of the storage unit carrier (Drum) and a linear movement of the drive link carrier (12). 17. Machine for performing arithmetic operations, in particular for storing preferably calculated numerical values, their storage units to embody the stored value have adjustable storage members, characterized in that the storage member is designed and arranged in such a way that to embody a certain value (5 to 9) several revolutions of the storage element are required.