Duplicating machines

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Duplicating machines were the predecessors of modern document-reproduction technology. They have now been replaced by digital duplicators, scanners, laser printers and photocopiers, but for many years they were the primary means of reproducing documents for limited-run distribution.

Like the typewriter, these machines were products of the second phase of the industrial revolution which started near the end of the 19th century (also called the Second Industrial Revolution)[citation needed][jargon]. This second phase brought to mass markets technologies like the small electric motors and the products of industrial chemistry without which the duplicating machines would not have been economical. By bringing greatly increased quantities of paperwork to daily life, the duplicating machine and the typewriter gradually changed the forms of the office desk and transformed the nature of office work.

They were often used in schools, churches, and small organizations, where revoluntionarily economical copying was in demand for the production of newsletters and worksheets. Self-publishers also used these machines to produce fanzines.[citation needed]

Mechanical duplicators[edit]

Until the late 18th century, if an office wanted to keep a copy of an outgoing letter, a clerk[citation needed] had to write out the copy by hand.[citation needed] This technology continued to be prevalent through most of the 19th century. For this purpose offices employed copy clerks, also known as copyists, scribes, and scriveners.

A few alternatives to hand copying were invented between the mid-17th century and the late 18th century, but none had a significant impact in offices.

Polygraphs[edit]

Polygraphs are mechanical devices that move a second pen parallel to one held by a writer, enabling the writer to make a duplicate of a document as it is written. Polygraphs appeared in the 17th century but did not become popular until 1800.[citation needed] Hawkins & Peale patented a polygraph in the US in 1803, and beginning in 1804 Thomas Jefferson collaborated with them in working on improvements in the machine. He used a polygraph for the rest of his life. However, polygraphs were not practical for most office purposes and were never widely used in businesses. Hawkins & Peale lost money producing polygraphs. The problem was their "inherent instability, and constant need for repair and adjustment."

Letter copying presses[edit]

Iron letter copying press, late 19th century, Germany

In 1780 James Watt obtained a patent for letter copying presses, which James Watt & Co. produced beginning in that year. Letter copying presses were used by the early 1780s by the likes of Benjamin Franklin, George Washington, and Thomas Jefferson. In 1785, Jefferson was using both stationary and portable presses made by James Watt & Co.

Using letter copying presses, copies could be made up to twenty-four hours after a letter was written, though copies made within a few hours were best. A copying clerk would begin by counting the number of master letters to be written during the next few hours and by preparing the copying book. Suppose the clerk wanted to copy 20 one-page letters. In that case, he would insert a sheet of oiled paper into the copying book in front of the first tissue on which he wanted to make a copy of a letter. He would then turn 20 sheets of tissue paper and insert a second oiled paper. To dampen the tissue paper, the clerk used a brush or copying paper damper. The damper had a reservoir for water that wet a cloth, and the clerk wiped the cloth over the tissues on which copies were to be made. As an alternative method of dampening the tissue paper, in 1860 Cutter, Tower & Co., Boston, advertised Lynch's patent paper moistener.

Then letters were written with special copying ink which was not blotted.[citation needed] The copying clerk arranged the portion of the letter book to be used in the following sequence starting from the front: a sheet of oiled paper, then a sheet of letter book tissue, then a letter placed face up against the back of the tissue on which the copy was to be made, then another oiled paper, etc.

Prior to the introduction of inks made with aniline dyes in 1856, the quality of copies made on letter copying presses was limited by the properties of the available copying inks. Some documents that were to be copied with copying presses were written with copying pencils rather than copying ink. The cores of copying pencils, which appear to have been introduced in the 1870s, were made from a mixture of graphite, clay, and aniline dye.

By the late 1870s, an improved method for moistening pages in copying books had been invented, and by the late 1880s it had been widely adopted. Rather than using a brush or damper to wet the tissues, the clerk inserted a thin moist cloth or pad between each oil paper and the following tissue.

In the late 1880s, adoption of improvements in office systems for filing unbound documents increased the demand for copying machines that made unbound copies of letters, as opposed to copies in bound books. In 1886, Schlicht & Field, Rochester, NY, introduced the Rapid Roller Damp-Leaf Copier, a roller copier, which used pressure supplied by rollers to copy letters onto a roll of dampened paper. After copies were pressed onto the paper, the paper entered the cabinet under the copier, where it dried on a large roller. An attachment was used to cut dried copies off the roll.

Copies could be made more quickly with a roller copier than with a letter copying press. It was claimed that nearly 100 papers could be copied in two minutes with a roller copier. Roller copiers competed with carbon paper technology. It was claimed that a roller copier could make a half dozen copies of a typewritten letter if the letter was run through the copier several times. It could make a dozen copies if the letter was written with a pen and good copying ink.

The Process Letter Machine Co., Muncie, IN, offered the New Rotary Copying Press, a loose-leaf copier, in 1902. This machine was similar to roller copiers but copied onto loose-leaf paper.

Hectographs[edit]

Main article: Hectograph

The hectograph introduced in 1876 or shortly before, was a technology in which a dye-impregnated master copy, not unlike a ditto master, was laid on top of a cake pan full of firm gelatin. After the dye soaked into the gelatin, sheets of paper could be laid on top of the gelatin to transfer the image. This was good for 50 copies at most. Hectography was slow and clunky, but it could inspire great intrepidity in its users. While good-quality, reasonably rapid copies from a hectograph require fairly specific materials (Aniline dye is the most effective), passable copies can be produced from a bewildering array of improvised materials on makeshift equipment. Practically speaking, any dye that soaks into the gelatin and can then be drawn out by the available paper will work. This meant that improvised hectography assumed the role of reproducing nearly every sort of censored material from subversive literature to pornography.[further explanation needed]

Mimeographs[edit]

Main article: Mimeograph
1918 illustration of a mimeograph machine.

The mimeo machine (mimeograph) invented by Albert Blake Dick in 1884 used heavy waxed-paper "stencils" that a pen or a typewriter cut through. The stencil was wrapped around the drum of the (manual or electrical) machine, which forced ink out through the cut marks on the stencil. The paper had a surface texture (like bond paper), and the ink was black and odorless. A person could use special knives to cut stencils by hand, but handwriting was impractical, because any closed loop letterform would cut a hole and thus print as a black blob. The technology was soon refined to control this problem, also allowing the use of typewriters to prepare mimeograph masters. If the user put the stencil on the drum wrong-side-out, the copies came out mirror-imaged.

Spirit duplicators[edit]

Main article: Spirit duplicator

The ditto machine (spirit duplicator) sold by Ditto, Inc., used two-ply "spirit masters" or "ditto masters". The top sheet could be typed, drawn, or written upon.[citation needed] The second sheet was coated with a layer of colored wax. The pressure of writing or typing on the top sheet transferred colored wax to its back side, producing a mirror image of the desired marks. (This acted like a reverse of carbon paper.) The wax-supply sheet was then removed and discarded, and the other sheet (containing the images) was fastened onto the drum of the (manual or electrical) machine, with the waxed (back, or reverse-image) side out.

The usual wax color was aniline purple, a cheap, moderately durable pigment that provided good contrast, though other colors were also available. Unlike mimeo, ditto had the useful ability to print multiple colors in a single pass, which made it popular with cartoonists. Spirit duplicators were incapable of double-sided printing, since the saturation of the paper with solvent inherent to the process would destroy a previously printed image. One well-made ditto master could at most print about 500 copies, far fewer than a mimeo stencil could manage. To produce further copies, an entirely new master would have to be reconstructed in the same way as the original master.

Notoriously, dittoed images would gradually fade with exposure to light[citation needed], limiting their usability for permanent labels and signage. Dittoed copies now pose a serious challenge to archivists responsible for document textual and artistic preservation.

Comparison of mimeographs and spirit duplicators[edit]

Ditto machines and mimeograph machines were competing and complementary technologies during the first half of the 20th century. Mimeography was in general a more forgiving technology, and still survives in various forms into the 21st century.

Ditto machines required much finer operating tolerances and careful adjustments to operate correctly. Overall print quality of spirit duplicators was frequently poor, though a capable operator could overcome this with careful adjustment of feed rate, pressure, and solvent volume.[citation needed]

During their heyday, tabletop duplicators of both sorts were the inexpensive and convenient alternatives to conventional typesetting and offset or letterpress printing. They were well suited for the short runs used for school worksheets, church newsletters, and apazines. Even the least technically minded teachers, professors, clergy, and self-publishers could make use of them[citation needed]. The machines owed most of their popularity to this relative ease of use, and in some cases, to their lack of a requirement for an external power source.

Mimeograph machines predated the spirit duplicator, had a lower cost per impression, superior print quality, finer resolution, and if properly adjusted could be used for multi-pass and double-sided printing. Also, mimeographed images were as durable as the paper they were printed on, and didn't bleach to illegibility if exposed to sunlight, the way that dittoed pages did. A good mimeo master could produce many more copies than the best ditto master. As with ditto masters, mimeo stencils could be saved and reused for later print jobs.

Mimeograph had a largely unwarranted reputation for being messier than spirit duplication. In truth, they weren't significantly messier; and if spilled mimeo ink was hard to get out of the operator's clothing, ditto's aniline purple dye was well-nigh impossible to remove. The perception may have been a side effect of their engineering. Mimeography, with its loose tolerances, relative absence of noxious solvents, and consequent open architecture (which put its inky pads and rollers on display), may simply have looked messier, and hence seemed more daunting. Spirit duplicators, whose demanding tolerances and constant fog of solvent fumes necessitated precisely machined metal parts and closed architecture, tended to have a deceptively clean and simple look.

There are still diehard mimeography enthusiasts in the United States and Canada, and mimeo technology is still in everyday use in the Third World. The technology is simple and robust, relatively easy to troubleshoot and repair, and economical. Significantly, many low-cost mimeograph machines do not require electricity to operate.

Offset Duplicators[edit]

In the United States an offset press with a sheet size smaller than 14 x 20" is classified as a duplicator. In Europe this distinction is made between presses that have cylinder bearings, and duplicators that do not. Duplicators were manufactured by Heidelberg (T-offset), American Type Founders (Chief and Davidson lines), A.B. Dick Company, and Addressograph-Mulitilith.

Digital duplicators[edit]

Main article: Risograph

In 1986, the RISO Kagaku Corporation introduced the digital duplicator. It uses the basic mimeograph technology but improves on it, in that the operator does not have to create the stencil directly. The stencil, called a master, is made by use of a scanner and thermal print head. A used master is automatically removed and placed in a disposal box, as a new one is created. This way the operator should not have to touch the used master material that is coated in ink.

There are also cost advantages over a copier at higher volume. For smaller print runs, the main cost is in the master material. This ranges between 40 – 80 cents per master depending on the manufacturer. When spread over 20 or more copies, the cost per copy (2 to 4 cents) is close to photocopiers. But for every additional copy, the average cost decreases. At 100 prints, the master cost per copy was only 0.4–0.8 cents per copy, and the cost of the paper printed upon will start to dominate. A master is capable of making 4000–5000 prints, and then a new master easily be made if needed for further copies.

Other manufacturers have adapted the technology including:

How digital duplicators work[edit]

Like the mimeo machine, digital duplicators have a stencil (called a master), ink, and drum—but the process is all automated.

  1. The original is placed on a flat bed scanner or fed through a sheet feed scanner, depending on the model.
  2. When the start button is pressed, the image is scanned into memory by reflecting light off the original and into a CCD.
  3. The image is burned onto the master material that is coated or laminated on one side, in a series of small holes by the thermal print head.
  4. As the new master is burning it is stored while the old master is removed.
  5. There is a clamp plate on the drum that opens by motor. The drum turns and the old master material is fed into the disposal rollers and into the disposal box.
  6. The new master is fed into the clamp which closes, then the drum is turned, pulling the master onto the drum.
  7. The outside of the drum is covered in screens and the inside is coated in ink. The screens make sure the ink flow is regulated.
  8. The paper is fed to the drum, and the ink only comes through the master material where there are holes.
  9. A pressure roller presses the paper to the drum and transfers the ink to the paper to form the image.
  10. The paper then exits the machine into an exit tray. The ink is still wet.

See also[edit]

References[edit]

  • The Dead Media Project
  • M P Doss, Information Processing Equipment (New York, 1955)
  • Irvin A. Herrmann, Manual of Office Reproduction (New York, 1956)[citation needed]
  • W B Proudfoot, The Origin of Stencil Duplicating (London, 1972)

External links[edit]