Direct Multiplication Calculating Machines

The first calculating machines multiplied by repeated addition. To multiple by tens, hundreds, or larger units, one shifted the carriage.  From the 1870s, a few inventors proposed machines that could multiply directly – albeit by a single digit at a time. The Frenchman Léon Bollée exhibited such a machine at a world’s fair held in Paris in 1889. Not long thereafter the American George Grant and the Swiss inventor Otto Steiger invented direct multiplication machines. Steiger’s machine would sell successfully as the Millionaire in both Europe and the United States. In the 1930s, Swedish-born inventor Carl Friden introduced a calculating machine on which all of the digits of the multiplier could be entered at once. Automatic multiplication – and automatic division – came to be widely available on calculating machines in the 1950s.

In 1878 Ramon Verea, a Spanish-born newspaper publisher in New York City, sent the U.S. Patent Office this model of a calculating machine he had invented.
Description
In 1878 Ramon Verea, a Spanish-born newspaper publisher in New York City, sent the U.S. Patent Office this model of a calculating machine he had invented. It was one of the first calculating machines that could multiply a number by a digit directly, rather than be repeated addition. The machine did not become a commercial product.
The lever-set machine has flat brass sides and is open at the front, bottom and back to reveal the mechanism. At the front are two ten-sided brass prisms that are mounted vertically. Each of the sides of the each prism has two columns of holes, with ten holes in a column. The holes come in ten sizes, with the largest and deepest representing 0, and the smallest and shallowest, 9. The holes represent multiples of a given digit.
Above the prisms are two knobs that move in slots in the flat top of the machine. Pulling forward a knob rotates the cylinder below, so that the side facing the back of the machine has holes representing multiples of the digit desired. Behind this mechanism is a row of tapered pins. Pulling a lever at the back of the machine raises or lowers these pins in order to set the multiplier. Turning a crank on the right side moves the pins up to the faces of the prisms and, where there are holes in the prism, allows the pins to enter to a certain depth.
Once the surface of a prism touched a pin, it pushed the pin, and a rack behind the pin, backward. Pins entering shallow holes reach the prism quickly and have a correspondingly greater effect on the rack. Pinions linked to the racks rotate correspondingly, rotating the result wheels at the back of the machine, with carrying occurring as required. Further turning of the crank restores the prisms, racks, and pins to their original position.
A mark on the top front of the machine reads: R. VEREA (/) NEW YORK. Verea had close ties to Cuba.
The model was displayed at the Museums of the Peaceful Arts in New York City. When that museum closed, it was given to the Smithsonian Institution by L. Leland Locke.
References:
R. Verea, “Improvement in Calculating Machines,” U.S. Patent 207918, September 10, 1878.
L. Leland Locke, “The First Direct-Multiplication Machine,” Typewriter Topics, November, 1926, pp. 16 and 18.
P. Kidwell, “Ideology and Invention: The Calculating Machine of Ramon Verea,” Rittenhouse, vol. 9, 1995, pp. 33–41.
date made
1878
date patented
1878
patentee
Verea, Ramon
maker
Verea, Ramon
ID Number
MA.311942
catalog number
311942
accession number
155183

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