Drafting The original use of the pantograph was for copying and
scaling line drawings. Modern versions are sold as technical toys.
Sculpture and minting Sculptors use a three-dimensional version of the pantograph, usually a large boom connected to a fixed point at one end, bearing two rotating pointing needles at arbitrary points along this boom. By adjusting the needles different enlargement or reduction ratios can be achieved. This device was invented by inventor and steam pioneer
James Watt and perfected by
Benjamin Cheverton in 1836. Cheverton's machine was fitted with a rotating cutting bit to carve reduced versions of well-known sculptures. Though now, it is largely overtaken by
computer guided router systems that
scan a
model and can produce it in a variety of materials and in any desired size, A three-dimensional pantograph can also be used to enlarge sculpture by interchanging the position of the model and the copy. Another version is still very much in use to reduce the size of large
relief designs for
coins down to the required size of the coin.
Acoustic cylinder duplication One advantage of
phonograph and gramophone discs over cylinders in the 1890s—before electronic amplification was available—was that large numbers of discs could be stamped quickly and cheaply. In 1890, the only ways of manufacturing copies of a master cylinder were to mold the cylinders (which was slow and, early on, produced very poor copies), or to acoustically copy the sound by placing the horns of two phonographs together or to hook the two together with a rubber tube (one phonograph recording and the other playing the cylinder back). Instead of copying a master cylinder, the other alternative was to record a performance to multiple gramophones simultaneously, over and over again, making each cylinder a master copy.
Edison,
Bettini,
Leon Douglass and others solved this problem (partly) by mechanically linking a cutting stylus and a playback stylus together and copying the "hill-and-dale" grooves of the cylinder mechanically. When molding improved somewhat, molded cylinders were used as pantograph masters. This was employed by Edison and
Columbia in 1898, and was used until about January 1902 (Columbia brown waxes after this were molded). Some companies like the
United States Phonograph Company of
Newark, New Jersey, supplied cylinder masters for smaller companies so that they could duplicate them, sometimes pantographically. Pantographs could turn out about 30 records per day and produce up to about 150 records per master. In theory, pantograph masters could be used for 200 or 300 duplicates if the master and the duplicate were running in reverse and the record would be duplicated in reverse. This, in theory, could extend the usability of a pantograph master by using the unworn/lesser worn part of the recording for duplication.
Pathé employed this system with mastering their vertically cut records until 1923; a , master cylinder, rotating at a high speed, would be recorded on. This was done as the resulting cylinder was considerably loud and of very high fidelity. Then, the cylinder would be placed on the mandrel of a duplicating pantograph that would be played with a stylus on the end of a lever, which would transfer the sound to a wax disc master, which would be electroplated and be used to stamp copies out. This system resulted in some fidelity reduction and rumble, but relatively high quality sound.
Edison Diamond Disc Records were made by recording
directly onto the wax master disc.
Milling machines Before the advent of control technologies such as
numerical control (NC and CNC) and
programmable logic control (PLC), duplicate parts being milled on a
milling machine could not have their contours mapped out by moving the
milling cutter in a "connect-the-dots" ("by-the-numbers") fashion. The only ways to control the movement of the cutting tool were to dial the positions by hand using dexterous skill (with natural limits on a human's
accuracy and precision) or to trace a cam, template, or model in some way, and have the cutter mimic the movement of the tracing stylus. If the milling head was mounted on a pantograph, a duplicate part could be cut (and at various scales of magnification besides 1:1) simply by tracing a template. (The template itself was usually made by a
tool and die maker using
toolroom methods, including milling via dialing followed by hand sculpting with
files and/or
die grinder points.) This was essentially the same concept as reproducing documents with a pen-equipped pantograph, but applied to the
machining of hard materials such as metal, wood, or plastic. Pantograph
routing, which is conceptually identical to pantograph milling, also exists (as does CNC routing). The Blanchard lathe, a
copying lathe developed by Thomas Blanchard, used the same essential concept. The development and dissemination throughout industry of NC, CNC, PLC, and other control technologies provided a new way to control the movement of the milling cutter: via feeding information from a program to actuators (
servos,
selsyns,
leadscrews, machine slides,
spindles, and so on) that would move the cutter as the information directed. Today most commercial machining is done via such programmable, computerized methods. Home machinists are likely to work via manual control, but computerized control has reached the home-shop level as well (it is just not yet as pervasive as its commercial counterparts). Thus pantograph milling machines are largely a thing of the past. They are still in commercial use, but at a greatly reduced and ever-dwindling level. They are no longer built new by machine tool builders, but a small market for used machines still exists. As for the magnification-and-reduction feature of a pantograph (with the scale determined by the adjustable arm lengths), it is achieved in CNC via mathematic calculations that the computer applies to the program information practically instantaneously. Scaling functions (as well as mirroring functions) are built into languages such as
G-code.
Other uses In another application similar to drafting, the pantograph is incorporated into a pantograph
engraving machine with a revolving cutter instead of a pen, and a tray at the pointer end to fix precut lettered plates (referred to as 'copy'), which the pointer follows and thus the cutter, via the pantograph, reproduces the 'copy' at a ratio to which the pantograph arms have been set. The typical range of ratio is Maximum 1:1 Minimum 50:1 (reduction) In this way machinists can neatly and accurately
engrave numbers and letters onto a part. Pantographs are no longer commonly used in modern engraving, with computerized laser and rotary engraving taking favor. In
electric locomotives and
trams, the device which maintains electrical contact with the
contact wire and transfers power from the wire to the
traction unit is also called a "
pantograph".
Herman Hollerith's
"Keyboard punch" used for the
1890 U.S. Census was a pantograph design and sometimes referred to as "The Pantograph Punch". An early 19th-century device employing this mechanism is the
polygraph, which produces a duplicate of a letter as the original is written. In 1886,
Eduard Selling patented a prize-winning
calculating machine based on the pantograph, although it was not commercially successful.
Longarm quilting machine operators may trace a pantograph, paper pattern, with a laser pointer to stitch a custom pattern onto the quilt. Digitized pantographs are followed by computerized machines.
Linn Boyd Benton invented a pantographic engraving machine for type design, which was capable not only of scaling a single font design pattern to a variety of sizes, but could also condense, extend, and slant the design (mathematically, these are cases of
affine transformation, which is the fundamental geometric operation of most systems of digital typography today, including
PostScript).
Richard Feynman used the analogy of a pantograph as a way of scaling down tools to the nanometer scale in his talk "
There's Plenty of Room at the Bottom". == See also ==