DE337862C - Device for setting the decimal point in calculating machines - Google Patents

Description

Device for setting the decimal point in calculating machines. contraption on calculating machines for the mechanical setting of the decimal point in the result in the right place.

The aim of the present invention is to create a device by means of which, when calculating with decimal numbers, the decimal point in the result can be set without having to count the decimal places. A product of whole numbers has as many places as the sum of the places of the two factors is, if the multiplication of the two highest digits of the two factors resulted in a tens transfer in the product, e.g. B. 3a X 73 = 2336 or with multi-digit multiplications of the two highest digits does not result in a tens transfer, but such a transfer is caused by the multiplication of the lower digits of the two factors, e.g. B. 35 X 32 = 112o. When multiplying two numbers for which a tens transfer is not caused by @ the highest digits, e.g. For example, 24 X 32 = - 768, the same principle can still be applied, provided that the tens transfer that was not carried out is regarded as a zero transfer of tens and therefore "o768" is written.

The subject of the invention is primarily as an automatic decimal point setting in calculating machines with a fixed counter, in which the for multiplication and division required position shift, which takes place inside the machine, is already carried out before. the numerical values from the setting mechanism to the result counter be transferred so that the first digit of the number setting works on the second digit of the result counter and the first digit in the counter remains free for the inclusion of tens transfers. In Fig. Z, the transmission is the Number 375 represented by the number setting mechanism after the result counter when multiplied.

A is the number dial, C is the result dial.

Fig. A is: the scheme for a numerical example.

Fig.3 represents the display works of a calculating machine and shows the Mechanism for shifting the decimal point.

Fig. 4 is a cross-section to Fig. 3. Figs. 5 and 6 are details of the Roller z6. Fig.7 shows the lacing. Fig. 8, 9 and io are schemes for various calculation examples.

Should z. B. 3.75 are multiplied by 2.0, so are in the counter to cross off two digits, since the two factors together make two digits whole Have numbers (Fig. 2). B is the rotation mechanism> which indicates how often the number has been transferred in plant A to plant C. The decimal point i (Fig. 3) in factory A is to be pushed behind the first position, the decimal point 2 in plant B is also to a place from. to move from the left side of each work; this means that the decimal point 3 in plant C must be shifted by i + i = 2 places. The product is = 7., 5o. When calculating with decimal numbers, the product must which is in counter C, the decimal point 3 by as many places next to the right be moved from the left as like the numbers in front of the decimal point i and 2 in the two factors in plant A and B together are '.

The automatic shift of the decimal point 3 to the correct one Position in the product, i.e. in counter C, is made by the two other decimal points i and 2 of the two factors in plants A and B. The decimal point 3 is with the other two decimal points i and 2 are connected by mechanical means in such a way that that it is shifted by the same number of places as the decimal point i which has been manually shifted a number of places. Moves If you set the decimal point 2 in plant B by hand, the decimal point 3 becomes in Plant C shifted again by the number of digits by which decimal point : 2 has been moved (Fig. 3).

The calculating machine has a fixed counter C as a display unit for the product for multiplications and for the dividendus for divisions, a number setting unit A as a display unit for the first factor for multiplications or divisors for divisions and a revolving unit B for learning the second factor for multiplications or O_uotients at divisions. In front of all three display units, decimal points 1, 2 and 3 are attached to bars 5, 6, which can be moved. The decimal point i in plant A is attached to a cord without an end io, which runs over two pulleys ii and 12. Roller 12 is fixed together with a bevel gear 13 on a shaft. Bevel gear 13 meshes with bevel gear 14. Bevel gear 14 is attached to a shaft 15 on which a roller 16 is displaceable in the axial direction. Roller 16 is linked to: the rotational movement of the shaft 15 by a pin 7 being attached to the shaft 15 (FIGS. 5 and 6), which can slide in a longitudinal groove 8 within the roller 16, and has a helical groove on the outer surface 17, in which the claw 18 (Fig. 3, q. And 5) of the decimal point 3 engages. The roller 16 is attached to the cord without an end 2o by a bracket 19 (FIGS. 3 and 7). The cord 2o slides over the rollers 21, 22, 23,: 24, 25 and 26 and is attached to the decimal point 2 on the other hand. If decimal point i is shifted by: a number of places, decimal point 3 is shifted by the same number of places by transferring the movement to roller 16 through the S: clülur io, roller 12, bevel gear 13 and 1q., Shaft 15. As a result of the helical groove 17, the thread pitch of which corresponds to the digit widths: of the calculating machine, the decimal point 3 is shifted by means of the claw 18. By shifting the decimal point: 2, the decimal point 3 is shifted again, corresponding to the shift length of decimal point 2, by this movement by means of cord 2o over the rollers 26, 2q-, 25, 22, 23 and 21 (Fig. 7) on the bracket 19 is transmitted. Bracket 19 moves the decimal point 3 by means of the roller 16 by engaging the claw 18 in the groove 17.

In the case of division, after the calculation, the decimal point i becomes in the divisor (Factory A), reducing the decimal point 3 by the same number of digits is moved. Then the decimal point 2 in the quotient (plant B) becomes so far to the right shifted until the decimal point 3 in the dividendus, which is the second shift again follows, in the correct place in Dividendus (Work C). Then stands Decimal point 2 in O_uotient (Plant B) also in the right place.

Since for the i here assumed for example: machine with multiplication and dividing the position shift before performing the arithmetic operation in each Positions and consequently the I. position of work A on the II. Position - of work C is transferred (Fig. i), care must be taken when dividing that the number of the dividend in work C is only in the II. or a lower position begins, provided the numbers in the individual digits of the dividend are greater than those of the divisor (Fig. 8). On the other hand, are the numbers of the first digits in the divisor greater, so it does not matter, it can then be the number of the dividendus in the same Place as the number of the divisor begin (Fig. 9 and io).

The following task is given as a numerical example: 32.5 X 622.2 - 20221.50.

The first factor 32.5 is set in factory A, starting with the first digit. The second factor 622.2 appears in plant B, beginning with the first digit. The product appears in Plant C, starting with the 1st position. In plant A, the decimal point i is to be moved behind the second position, which means that the decimal point 3 in plant C is also moved behind the second position. In plant B, the decimal point 2 is added after the III. Position shifted, whereby the decimal point 3, after it had already been shifted by @ two places, is shifted by a further three places, i.e. a total of -five places, and the result is 20 221.5 0 . .

Claims (1)

PATENT CLAIM: -Device on calculating machines with fixed counting and display units for automatic setting: the decimal point in the result in the correct place by manual setting of the decimal point-in the number setting unit and the revolving unit, characterized in that in front of the number display units (A, B and C ) Decimal symbols (1, 2 and 3) are arranged on rods that are connected to one another in such a way that by moving the decimal symbol (i) in front of the number setting mechanism (A), the decimal symbol (3) in the result counter (C) by the same number of Places is shifted, and also this last-mentioned decimal point (3) by moving the decimal point (2) in the revolving mechanism (B) by a further number of. Positions that are shifted accordingly in the revolving mechanism (B) by attaching the decimal point (i) in the number setting mechanism (A) to a cord without an end (io) running over two pulleys (ii and 12), whereby the movement of one of these pulleys (12) is transferred by means of two bevel gears to a roller (16) with a helical groove (17) in which a claw (18) of the decimal point (3) engages, while the decimal point (2) is attached to a cord in front of the revolving mechanism (B) without end (2o) is attached and through this cord (2o) the roller (16) with the decimal point (3) also moves in the axial direction by the same length by which it itself (2) was moved.