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A.D. 1851 . . . . . . . N^o 13,504.

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Calculating Machine.
 

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De Colmar's Specification.

A.

   In Drawing I., Figure 1 is a plan or bird's-eye view of the machine when the lid is raised, showing the plates M, M, M, M, and F, F, F, F. Figure 2 of the same Drawing is an underneath view of the plate M, M, M, M. Figure 3 is a side elevation of the same plate M, M, M, M. Figure 4 is a section of the plan of the cylinder, the plate F, F, F, F, being taken off to exhibit the working of the several organs composing the mechanism of the cylinders Y, Y, Y, Y, Y¹, and H. Figure 5 is a side elevation of the cylinder H. Figure 6 is a side section of the cylinders Y, Y, Y, Y. Figure 7 is an horizontal elevation through the plate R, R. Figure 8 is a front plate, showing the rod o, o, o, and bevil wheels d¹, d¹, d¹, d¹, d¹. Figure 9 is a front and side view of the levers L, L, L, L. Figure 10 is a front and side view of the stops for the small levers k¹, k¹, k¹, k¹. Figure 11 is a front view of the rack E, wheel X¹, and indicator plate. Figure 12 is a front view and plan of the cylinder Y, and of the spring S.
   In Drawing II., Figure 1 represents a plan of the double dial for quotient and multiplier. Figure 2 is a sectional elevation through A, B, of Figure 1; Figure 3 is a side elevation of cylinder and gear to obtain the quotient and multiplier; Figures 4 and 4¹ are a side and front elevation of fork lever F, F; Figures 5 and 5¹ are a front and side view of the lever Z, Z.

   The mechanism for the multiplicant and multiplier can be inserted, as represented in the Drawing I., in a box having about 2 in. 1/8 in elevation, one foot three inches in length, and 6 in. 1/4 in width. It is composed of two plates, as represented in Figures 7 and 8 of the Drawing I., which said plates are united together by four pillars, seen in Figures 4, 5, and 6, and of another small plate carrying the guides G, G, G, in which the steel rod G¹, G¹, is sliding, as seen in Figures 2 and 3. The box is covered with a wrought iron or brass plate, which may be about 5 in. 1/4 in width, and 1 ft. 1/5 in length, as represented by the letters F, F, F, F, Figure 1. This wrought iron or brass plate is provided with an equal number of slits as there are figures for the multiplicant beside one more for the multiplier. It is in those slits which are in Drawing I., six in number, that the knobs A, A, A, A, A, Figures 1, 6, and 8, with their indicating hands, by which the figures of the multiplicant are pointed out, and the knob B¹, Figures 1, 5, and 8, with its double hand, indicate the figures of the multiplicator or devisor, are made to slide, as it will be herein-after described. The ten dials c, c, c, c, c, Figures 1, 2, 3, are separated from each other by about 3/4 of an inch, and are fitted on another plate M, M, M, M, having about 1 in. 7/8 in width, and 1 ft. 1/8 in length. Each of these dials c, c, c, c, c, represent ten figures, from 0 to 9, which serve to indicate by means of openings cut, as shown in the herein-before described plate M, M, M, M, the products obtained by the working of the machine. The above-described plate M, M, M, M, can be made to raise and to slide along the box upon the herein-before described steel rod G¹, G¹, Figures 2 and 3, which serves as a hinge to the said plate M, M, M, M, and by that contrivance it causes the line of the dials c, c, c, c, c, to be changed, which renders them successively independent of the mechanism when it is put in motion. I fix on the same plate M, M, M, M, but underneath each of the said dials c, c, c, c, c, the wheels D, D, D, D, Figures 2, 3, and 6, provided with ten cogs. Each dial carries a double inclined steel pin u, u, u, u, Figures 2, 3, which presses on the catching levers L, L, L, L, Figures 4, 6, 7, and 9, and disengages the catching each time the dials pass from 0 to 9, or from 9 to 0. The small flat wheels X¹, X¹, Figures 3 and 11, divided in ten equal parts, but with only nine cogs, are cast on every wheel D, D, D, D, of the dials c, c, c, c, c, as herein-before stated. These small wheels X¹, X¹, cause all the dials c, c, c, c, c, to be replaced at once to 0 by means of the rack E, E, E, Figures 2, 3, and 11, either by drawing the knob T, Figures 1, 2, and 3, or by means of any other suitable mechanism, giving to the wheel X¹, X¹, a rotative motion, as in Figure 11. When the dials c, c, c, c, c, are at 0, the said wheels X¹, X¹, are in the position represented by the said Figure 11. The cylinders Y, Y, Y, Y, seen in Figures 4, 6, and 12, are provided with nine graduated cogs cut lengthway, in order to represent the figures of the multiplicant from 1 to 9. The teeth of the cylinders Y, Y, Y, Y, Figures 4, 6, and 8, catch with the small wheels A¹, A¹, A¹, A¹, A¹, of the same Figures. These wheels are provided with ten cogs, and they are put in motion by means of the fork P, Figures 6 and 8, with which the indicating knobs A, A, A, A, A, already described, are provided. The wheels A¹, A¹, A¹, A¹, A¹, slide over the square axes A¹¹, A¹¹, A¹¹, according to the motions of the fork P, and of the knobs A, A, A, A, by which they are conducted to the figures of the multiplicant. It is then that the herein-before described wheels A¹, A¹, A¹, A¹, A¹, catch their separate cogs with the section of the teeth cut, as herein-before described, on the length of cylinders Y, Y, Y, Y, which have the number of their cogs equal to that of the figure exhibited by the indicating knob A, A, A, A. When the cylinders Y, Y, Y, Y, perform a rotative motion, they cause the small wheels A¹, A¹, A¹, A¹, to turn the same number of cogs which the figure facing the indicating hand of the knobs A, A, A, A, points out, and the dials c, c, c, c, render visible the same figure through their opening on the moveable plate M, M, M, M, Figure 1. On the left of the cylinders Y, Y, Y, Y, Figure 4, another cylinder H, Figures 4 and 5, cut helically, is set, and a slit cuts in all its length, allows the lever B, seen in Figures 4, 5, and 8, and put in motion by the knob B¹, Figures 1, 4, 5, and 8, to regulate the number of revolutions the cylinders Y, Y, Y, Y, are to perform together, in order to represent one of the figures of the multiplier. Thus, for instance, when the hand of the knob B¹, Figures 1, 5, and 8, indicates the figure 9 of the left column, the multiplicant will be multiplied by 9.
   All the herein-before described cylinders Y, Y, Y, Y, Figures 4, 5, 6, 7, 8, and 12 of the multiplicant, as well as the cylinder H of the multiplier, are provided at one of their extremities with bevil wheels d, d, d, d, having twenty cogs which catch with a similar number of bevil wheels d¹, d¹, d¹, d¹, set on the same axis o, o, o, Figures 4, 5, 6, and 8. On the right hand of the herein-before described axis o, o, o, is placed the bevil wheel d¹¹, which cogs with the wheel set on the axis of the crank arm N, Figures 1, 4, 6, and 8. Close to the other extremity of the cylinders, Y, Y, Y, Y, of the multiplicant and of the cylinder H of the multiplicator, less however the cylinder Y¹ set on the right, I have placed a system of cogs Z, Z, Z, Z, to operate the catchings. The moveable pins set on the levers k, k, k, Figures 4, 5, 6, 7, and 12, cog only with the ten cogs wheels Z, Z, Z, Z, Figure 7, when they are to operate the catchings. In order to obtain that effect the spiral springs S, S, S, S, Figure 4, 5, 6, and 12, placed between the levers k, k, k, and the cylinders Y, Y, Y, Y, and H, as represented by Figure 12, act on the said levers k, k, k, and force them to meet during their circular motion the catch wheels Z, Z, Z, Z, Figure 7. This last movement takes place only when the dials c, c, c, c, c, have passed from 0 to 9, or from 9 to 0, because the small double inclined pins u, u, u, u, herein-before described, Figures 3 and 6, by pressing them on the levers L, L, L, Figures 7 and 9, allow the spiral springs S, S, S, S, to cause the descending motion of the levers k, k, k, Figures 4, 5, 6, 7, and 12, which action they would not perform otherwise, being kept by the small pin b, b, of the levers L, L, L, Figure 9. The spiral springs S, S, S, S, being distended and the small levers k, k, k, lowered, when the cylinders are made to turn by the action of the crank arm N, the small levers k, k, k, meet the catch wheels Z, Z, Z, Z, and compel them to turn one cog, which causes the dials c, c, c, c, c, to turn of one figure, then the small levers k, k, k, by continuing after their circular motion meet on their passage with the small inclined pieces I, I, I, I, Figures 5, 6, 7, and 10, fixed on the small plate, Figure 7. These small inclined pieces I, I, I, I, will cause the small levers k, k, k, to ascend again to their former position, and at that place they are maintained by the herein-before described small pin b, of the levers L, L, L, Figure 9. The aforementioned small levers k, k, k, having thus returned to their usual position, as afore stated, if the cylinders Y, Y, Y, Y, are made to turn the said small levers k, k, k, will pass in front of the catch wheels Z, Z, Z, Z, Figure 7, without causing the said wheels to rotate.
   I must explain here the reasons which have induced me to use only nine cogs on the cylinders Y, Y, Y, Y, Figures 4 and 8. It is absolutely necessary that each of the cylinders Y, Y, Y, Y, should receive the catchings after having produced its figure, and to perform that operation it is required that the holdings or catchings be produced in due succession one after the other. It was therefore indispensable that the tenths should be produced before the hundredths and the hundredths before the thousandths, and so on. For that reason I have necessarily placed the cylinders Y, Y, Y, Y, Figure 4, in such a position that they are able to cog with the wheels A¹, A¹, A¹, A¹, A¹, of the multiplicant figure one after the other, then the cylinders Y, Y, Y, Y, and their levers k, k, k, will be placed relatively to each other in the position as represented in Figures 4 and 7. The subtraction and division being the reverse rules of the addition and multiplication, to perform these last operations I have fixed on the square axes A¹¹, A¹¹, A¹¹, A¹¹, on which the wheels A¹, A¹, A¹, A¹, are made to slide, as herein-before described, two bevel wheels, having each of them ten teeth, which cause the dials c, c, c, c, c, to turn from right to left and from left to right. The square axes A¹¹, A¹¹, A¹¹, A¹¹, on which the bevil wheels D, D, D, D, and D¹, D¹, D¹, D¹, are set, have their pivots jutting out, as represented in F¹, F¹, F¹, F¹, Figure 4, in order that they should be made to operate in the direction of their length without moving out from the plates into which their pivots are made to turn. Between the two bevil wheels D, D, D, D, and D¹, D¹, D¹, D¹, are set the plates with grooves having the same width than the band R, R, Figure 4. I cause all the bevil wheels D, D, D, D, and D¹, D¹, D¹, D¹, to recede or to advance together by means of the said band R, R, which passes in the grooves of the bevil wheels in order to have those of the front or back to cog with the wheels of the dials c, c, c, c, c. I obtain this change from the multiplication to the division, or that from the addition to the subtraction, and vice versa, by turning the wing nut E¹, Figures 1 and 4; in that manner its indicator points out the real operation to be performed. The large knob L¹, of Figures 1 and 3 serve to raise the plate of the dials c, c, c, c, c; the two knobs V¹, V¹, Figure 1 and 2, can be placed indifferently into the small holes V, V, V, of the dial plate M, M, M, M, when semicolons are required to separate the several aliquot parts or to divide the numbers in groups of two or three figures and to extract the square or cube root of a number and also for fractions and decimals.
   I can also obtain the quotient in the division and the multiplier in the multiplication by setting on the back of the first cylinder on the right, A, Figures 1 and 3, Drawing II., that is to say, on the back of cylinder Y¹, Figure 4, Drawing I., a cylindrical piece B, Figure 3, Drawing II., having about 7/10 of an inch in diameter and provided with a groove c, c, Figure 3, being about 1/10 of an inch deep. This groove c, c, cuts obliquely in two parts and in a contrary direction the cylindrical piece B, in order to give to a lever L, Figure 3, entering into the said groove, an alternate motion. The lever L, is moveable in an hinged piece S, Figures 1, 3, 4, and 4¹, set on the back plate, and is provided at its upper extremity (having also a hinge) with a fork F, Figures 1, 3, 4, and 4¹, the two arms of which are moveable, and commands a spiral spring T, Figures 1 and 4 having a tendency to cause the said arms to approach one from the other. The arms F, F, Figures 1, 3, 4, and 4¹, of the fork are bent inside and serve to put in motion a wheel R, Figures 1, and 3, having about 7/16 of an inch in diameter, and this wheel R is provided with ten square teeth and is fixed to the dial plates. On its axis I set an indicating hand working on the openings plate and pointing out on a dial V, Figure 1, having a double row of figures, the number of rotations performed by the crank arm N, Drawing I. The red numbers on the dial V, Drawing II., indicate the quotient, and the black numbers those of the multiplier. On the lower part of the small iron band Q, Q, Figures 1, 2, and 3, communicating with the wing nut E¹, of the Drawing I., is set a piece O, Figures 2 and 3, Drawing II., supporting perpendicularly a fork projecting towards the bottom of the apparatus. Between the two arms of the herein-before described fork a pin K, Figures 1, 2, 3, 5, and 5¹, is moving. The said pin K forms a part of the lever Z, Figures 1, 2, 3, 5, and 5¹, fixed to the back plate by means of a screw. The lever Z is ending in the shape of a fork Z, Z, Figures 1, 2, 3, 5, and 5¹, the arms being at angle and kept in between the two arms F, F, and the spring T, herein-before described. The small iron band q, q, Figures 1, 2, and 3, communicates a right or left motion to the lever Z commanding the back plate according to the motion given to the crank arm E¹, Drawing I., for performing either an addition or subtraction. The right or left hook Z, Z, Figures 2, 3, 5, and 5¹, of the lever distends the corresponding arm of the fork F, F, Figures 1, 3, 4, and 4¹, leaving the opposite arm to be alone in communication with the cog wheel R. Each revolution of the crank arm N, Drawing I., causes an alternate motion to the fork, the arm of which communicating with the wheel R, Figure 3, Drawing II., causes the last to turn of a cog from right to left or from left to right according to the arm which is acting on the said wheel R. I set on the dial plate V, Figure 1, the same number of cog wheels R, with their hands and double set of figure dials, as I have placed cylinders in the machine. The same fork F, F, Figures 3, 4, and 4¹, will act successively on the several wheels when put in communication either by carrying the plate on the right or on the left. The dial plate for the present arrangements have been increased of 5/16 of an inch in length, the square axes A¹¹, A¹¹, A¹¹, and the pillars of back plate, Drawing I., of the machine have also been lengthened of the same quantity.

   And having now described the nature of my said Invention, and in what manner the same is to be performed, I wish to be understood that I do not restrict myself to the precise details, proportions, or modus operandi I have described, provided the general features of the organs and arrangement of my Invention be preserved; but what I claim as my Invention, and intended to be protected by the herein-before recited Letters Patent, is, -
   Firstly, the constructing and dividing cylinders as herein-before described, reference being had to Figures 4, 5, 6, 7, 8, or 12 of Drawing I.
   Secondly, the obtaining the products, as herein-before described, reference being had to Figures 1, 3, 4, 5, 6, and 8 of Drawing I.
   Thirdly, the changing from multiplication to division, and from addition to subtraction, as herein-before described, reference being had to Figure 1 & 4, Drawing I.
   Fourthly, the mode of effecting the stoppings as herein-before described, reference being had to Figures 7, and 9 of the Drawing I.
   Fifthly, the method of replacing the numbers to 0 as herein-before described, reference being had to Figures 2, 3, and 11, of Drawing I.
   Sixthly, the arrangement for putting the machine in motion as herein-before described, reference being had to Figure 1, 4, 5, 6, and 8, of Drawing I.
   Seventhly, the arrangement for obtaining the quotient and multiplier as herein-before described, reference being had to all the Figures of Drawing II.

In witness whereof, I, the said Charles Xavier Thomas de Colmar, have hereunto set my hand and seal, this Seventh day of August, in the year of our Lord One thousand eight hundred and fifty-one.

Charles Xavier (L.S.) Thomas (de Colmar.)

Taken and acknowledged by Charles Xavier Thomas de Colmar (party hereto) at Paris, in the Republic of France, this 7th day of August 1851, before me,

			Thomas Pickford,
(	Consul's Seal.	)	Her Majesty's Consul for Great Britain.

Henry Mowbray.

L' de Fontaine Moreau.

Sworn at the Chancery Affidavit Office, Southampton Buildings, Chancery Lane, in the County of Middlesex, this 9th May of August 1851, before me,

Henry Mowbray. 

Figures:

Drawing I. : 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12;

Drawing II.: 1, 2, 3, 4, 4¹, 5, 5¹.