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Linotype machine

The Linotype machine was a hot-metal typesetting device invented by German-American engineer Ottmar Mergenthaler that automated the production of metal type slugs containing entire lines of text, revolutionizing the printing industry by replacing labor-intensive hand composition.^[1]^[2] Introduced commercially in 1886, it operated via a keyboard that assembled brass matrices—small engraved templates for individual characters—into a line, into which molten lead alloy was poured to form reusable "slugs" for printing presses.^[3]^[2] The machine's design allowed operators to produce up to 5,000–7,000 characters per hour, far surpassing manual methods that had dominated since Johannes Gutenberg's movable type in the 15th century.^[2]^[1] Mergenthaler, who immigrated to the United States in 1872, began developing the Linotype in Baltimore, Maryland, around 1882, drawing on earlier experiments with typesetting automation funded by figures like James O. Clephane.^[2] His breakthrough came in 1884 with a concept to integrate matrix assembly and metal casting in one process, leading to a key patent (U.S. No. 317,828) granted on May 12, 1885, for a machine that cast printing bars from embossed matrices using compressed air.^[4]^[2] The first practical model, known as the "Blower," was tested at the New-York Tribune on July 3, 1886, where it earned its name "Linotype" (short for line-of-type) from editor Whitelaw Reid; by 1889, the newspaper had 42 machines in operation.^[1]^[2] Commercial production ramped up through the Mergenthaler Linotype Company, founded in 1886 and reorganized in 1891, which leased machines globally and dominated the market with patent protections until Mergenthaler's death in 1899.^[2]^[3] In operation, the Linotype resembled a typewriter with a 90-character keyboard; pressing keys released matrices from a magazine, aligning them to form words and lines, which were justified automatically via spacebands that expanded to fill the line length.^[3]^[1] Molten metal at approximately 550°F (288°C) was then injected into the matrix assembly to cast the slug, after which the matrices were sorted and returned via a notched system for reuse, enabling efficient multi-font work with swappable magazines.^[3] Comprising around 5,000 parts, early models like the 1890 Square Base version cost about $1,000 and were built for durability in newspaper composing rooms.^[3] This mechanized workflow allowed for corrections before casting and reduced errors compared to hand-setting individual types.^[2] The Linotype's impact was profound, enabling mass production of newspapers and books by dramatically increasing typesetting speed and reducing labor needs—for instance, the New-York Tribune replaced 90 compositors with 30 machines by 1888, supporting larger editions and higher circulations.^[2] It facilitated the growth of the penny press and modern journalism, contributing to broader access to information and the rise of consumerism in the late 19th and early 20th centuries.^[2] By the 1890s, over 1,600 machines were in use worldwide, with the company selling rights internationally, such as to Britain for $2.5 million in 1889.^[2] Though phased out by phototypesetting and digital technologies in the mid-20th century—the New York Times retired its last Linotypes on July 2, 1978—the machine remained a cornerstone of hot-metal printing until the 1970s.^[1] Today, surviving examples, like the 1890 model at the International Printing Museum, underscore its role as an engineering landmark designated by the American Society of Mechanical Engineers in 1988.^[3]

History

Invention and Development

The Linotype machine was primarily invented by Ottmar Mergenthaler, a German immigrant who arrived in the United States in 1872 and settled in Baltimore, Maryland. In 1876, Mergenthaler began development under the financial backing of James O. Clephane, a Washington, D.C., court stenographer seeking an efficient method to transcribe and print shorthand notes. Initially tasked with creating a machine to emboss raised type on paper for direct printing, Mergenthaler collaborated with his brother-in-law August Hahl and others at Hahl's watchmaking shop.^[2]^[1] Early prototypes faced significant challenges, including multiple failed attempts to achieve reliable typesetting. By 1878, Mergenthaler had developed a stereotyping machine that used papier-mâché matrices to cast lines, but it suffered from slow drying times and the inability to correct errors in cast lines. A 1883 band machine, limited to 12 letters, further highlighted design flaws such as inefficiency and mechanical unreliability. These setbacks persisted until July 26, 1884, when Mergenthaler unveiled his first successful direct-casting prototype, capable of producing four lines of type per minute, which he demonstrated to newspaper experts including Stilson Hutchins of the Washington Post.^[2]^[5] Key innovations culminated in the 1885 "Blower" model, a single-matrix line-casting machine that Mergenthaler patented on May 12, 1885 (U.S. Patent No. 317,828). This prototype was publicly demonstrated at the Chamberlain Hotel in Washington, D.C., attended by figures such as President Chester A. Arthur, marking the first viable line-casting system. Further refinements addressed initial operational issues, leading to the 1886 commercial model, which was tested by the New-York Tribune and named "Linotype" by its editor Whitelaw Reid. The machine's success stemmed from Mergenthaler's persistent iterations, transforming fragmented type-setting into automated line production.^[2]^[4]^[1]

Adoption and Evolution

The first commercial installation of the Linotype machine took place in July 1886 at the New York Tribune, marking its debut in practical newspaper production where it was used to compose lines of type for the daily edition.^[1] This installation demonstrated the machine's efficiency in automating the typesetting process, which involved selecting matrices via a keyboard and casting entire lines of hot metal slugs, far surpassing hand composition speeds.^[6] Following its initial success, the Linotype rapidly spread to other major U.S. newspapers, enabling larger editions and faster production cycles, with thousands of units in operation by the early 1900s.^[7] By 1900, adoption had extended globally, transforming printing operations in newspapers across Europe, Asia, and beyond, as publishers recognized its role in scaling content output without proportional increases in labor.^[8] For instance, installations at prominent outlets like The Times in London by the mid-1890s exemplified this international uptake, integrating the machine into established workflows to handle growing demands for timely news dissemination.^[9] Technological evolution continued with iterative models that addressed operational refinements. The Linotype Model 5, introduced in 1906, incorporated a quick-change magazine system, allowing operators to switch font sets more efficiently from the front of the machine without halting production.^[10] Later variants in the mid-20th century, such as those emerging in the 1950s, integrated electric controls to automate functions like matrix selection and line justification, reducing manual adjustments and improving precision in high-volume settings.^[11] In the early 20th century, adaptations enhanced the Linotype's versatility for remote and automated input. The Teletypesetter (TTS) system, developed in collaboration with Teletype Corporation, enabled machines to read punched paper tape, permitting text transmission over telegraph lines and direct feeding into the keyboard mechanism for composition without live operators.^[12] This innovation, first implemented in the 1920s, supported distributed news workflows, where copy prepared at distant bureaus could be typeset centrally, further accelerating the machine's utility in global journalism.^[13]

Overview

Basic Principles of Operation

The Linotype machine operates through an automated process that transforms textual input into solid metal lines of type, known as slugs. An operator enters text using a specialized keyboard, which releases brass matrices—small molds engraved with individual characters—from multiple magazines. These matrices descend and align in a vertical assembler to form the desired line of text, with expandable spacebands inserted to temporarily hold spaces between words. Once the line is complete, the spacebands are adjusted upward to justify the line to the precise column width, clamping the assembly securely before it moves to the casting position.^[14] Molten type metal is then injected into the aligned matrices via a heated mold, solidifying almost instantly to form a complete slug of raised type for that line. The metal alloy used for casting consists of approximately 84% lead, 12% antimony, and 4% tin, which melts at around 240–280°C to ensure sharp impressions and durability without excessive expansion or contraction. After casting, the slug is ejected for use in printing, while the matrices and spacebands are automatically transported to a distribution mechanism that sorts and returns them to their original channels in the magazines based on notches along their edges, enabling reuse in subsequent lines.^[15]^[16] The entire cycle, from line assembly to casting and matrix return, typically takes under 9 seconds, allowing skilled operators to produce text at 3–5 times the speed of traditional hand composition. This efficiency stems from the machine's mechanical synchronization, where the keyboard input directly triggers matrix release and alignment without manual sorting.^[17] In cases of operator error, such as a mistyped word, there was no simple correction mechanism mid-line; instead, operators often completed the line by running their fingers down the first two columns of the keyboard—the most frequently used letters in English, arranged as "ETAOIN" and "SHRDLU"—to fill the remaining space with nonsense text. This "etaoin shrdlu" sequence would then be cast into a slug, which was usually melted down for reuse, though occasional oversights led to its accidental appearance in print.^[18]

Advantages and Limitations

The Linotype machine offered significant advantages over traditional hand composition, primarily through its automation, which drastically reduced the labor required for typesetting. A single operator could perform the work equivalent to five or six hand compositors, who previously set type letter by letter in a laborious process. This efficiency stemmed from the machine's ability to cast entire lines of type (slugs) in molten metal from brass matrices, combining setting, casting, and distribution in one operation controlled by a keyboard.^[19]^[6] Another key benefit was the consistent alignment of type, as each slug was cast to a precise, predetermined length, ensuring uniform lines that simplified assembly into pages and columns for printing. The machine also supported multiple fonts through its magazine system, where each magazine held matrices for a specific typeface; operators could switch magazines to access different fonts without halting production entirely, though this required physical replacement in early models. Production rates further highlighted its superiority, with a skilled operator achieving up to 6,000 ems (a unit roughly equivalent to the width of a capital M) per hour, compared to approximately 1,000–1,500 ems per hour for skilled hand compositors, enabling the rapid output necessary for mass newspaper production.^[1]^[20] Despite these strengths, the Linotype had notable limitations that constrained its flexibility. Line lengths were fixed by the machine's mold and justifier settings, typically ranging from 12 to 30 ems, which restricted its use for varying formats without adjustments or multiple machines. Corrections posed a particular challenge, as errors in a line required recasting the entire slug rather than adjusting individual characters, increasing time and material waste compared to hand methods where single letters could be swapped. Additionally, the machine's complexity made it vulnerable to mechanical breakdowns during prolonged high-speed operation, often due to issues like matrix misalignment or metal flow problems if not meticulously maintained.^[21]^[22] In comparison to hand composition, the Linotype's automation and speed transformed typesetting from a craft-dependent process into an industrialized one, though it demanded skilled operators to mitigate its error-correction drawbacks. Early competitors like the Paige Compositor, which aimed to automate individual type placement, ultimately failed due to excessive mechanical complexity—featuring 18,000 parts—and frequent breakdowns, rendering it unreliable and costly; the Linotype's simpler design proved more practical and commercially viable.^[23]

Design and Components

Matrices

The matrices of the Linotype machine are thin plates made of hardened brass, typically measuring 1.25 inches in length and 0.25 inches in width.^[24] These plates feature an incised recess on one long edge, containing the reversed impression of a character to serve as a mold for casting molten metal into a raised letterform.^[24] The depth of the character engraving is standardized at 0.043 inches to ensure consistent slug thickness across casts.^[25] Most standard matrices accommodate two character positions along the engraved edge: the normal or regular position for upright Roman letters, and the auxiliary or raised position for corresponding Italic variants or figures, allowing a single matrix to produce either form depending on alignment during assembly.^[26] This dual design optimizes storage by reducing the total number of unique matrices needed for mixed Roman and Italic composition. Boldface characters require dedicated matrix sets with thicker engravings for heavier strokes, while Italic and bold variants are often housed in auxiliary magazines for quick font changes.^[27] Matrices are stored vertically in the machine's magazine system, with a standard 90-channel magazine (91 slots numbered 0–90) capable of holding approximately 1,350–1,800 matrices (15–20 per channel) for standard type sizes, distributed across channels according to character frequency—frequent letters like "E" positioned near the top for faster access and replenishment.^[28]^[29]^[30] Each matrix includes a unique series of up to seven notched teeth along its upper edge, encoding a binary pattern that enables precise sorting during redistribution (as detailed in the distribution system).^[30] Special matrices, known as pi matrices, are provided for rare symbols, accents, or non-standard characters not assigned to regular channels; these feature a complete set of teeth to prevent automatic return to the magazine, requiring manual extraction after use.^[31] Such pi matrices ensure flexibility for occasional elements like mathematical symbols or foreign diacritics without disrupting the primary font inventory.^[27]

Magazine System

The magazine system of the Linotype machine consists of a trapezoidal brass assembly containing multiple vertical channels that store brass matrices aligned one above the other, with standard configurations featuring 90 channels (numbered 0 through 90) for character matrices, though variants with 72 or fewer channels were used for specialized applications. Matrices within each channel are sorted and stocked according to letter frequency, ensuring that commonly used characters like 'e' or spaces have more copies available—typically 15 to 20 per channel in a full magazine—to minimize depletion during extended composition runs. Up to four superimposed magazines could be installed in advanced models, allowing operators to switch fonts or styles by raising or lowering the assembly via a hand lever or wheel mechanism, facilitating quick changes without halting production.^[32]^[33]^[34]^[35] The escapement mechanism at the base of each channel precisely controls matrix release, employing a star wheel in conjunction with a trigger-actuated verge and pawls to eject one matrix at a time in response to keyboard signals. This setup includes two pawls per channel—one retaining and one releasing—operated by a plunger and spring-loaded verge that tilts to allow gravity-fed descent of the lowermost matrix into the stick channel below. The star wheel, integrated into the assembler's transfer rail, then captures and positions the released matrix accurately within the line assembly elevator, preventing misalignment or jams.^[36]^[34] Maintenance of the magazine system is essential to ensure reliable operation, involving daily inspection of channel entrances for debris or misalignment and lubrication of the vertical channels with light oil to prevent matrices from sticking due to metal shavings or residue buildup. Cleaning procedures include monthly brushing of escapement components and wiping of matrix lugs with gasoline to remove gum or rust, which could otherwise cause irregular releases or jams; graphite is sparingly applied to pawls for dry lubrication without attracting dust. The system typically supports 12-point type as standard, with magazines designed for capacities of 14 to 20 matrices per channel, and quick-change features in later models allow swapping for different sizes or styles in under a minute by a single operator.^[37]^[36]^[35]

Keyboard and Composition

The Linotype machine's keyboard served as the primary operator interface for composing lines of text, featuring a specialized 90-key layout arranged in five rows to optimize efficiency based on letter frequency. Black keys on the left side corresponded to lowercase letters, white keys on the right to uppercase letters, and blue keys for punctuation and lowercase special characters, eliminating the need for a shift key through dedicated positions for each case. This logarithmic arrangement prioritized high-frequency characters like "e," "t," and "a" in accessible positions, allowing skilled operators to achieve typing speeds of up to 5,000 characters per hour.^[3]^[38] Spacebands, essential for variable word spacing, were stored in a dedicated box adjacent to the keyboard, typically holding around 200 tapered brass wedges designed to expand during justification. When the operator pressed the spacebar key, a spaceband was released from the box and inserted into the line assembly, providing initial rough spacing between words based on the tapered design that allowed for later expansion without fixed width. These spacebands hung below the matrix line in the assembler, their long tails preventing interference while enabling precise alignment.^[21]^[39] The assembler elevator, functioning as a mechanical "stick" analogous to hand compositing tools, collected released matrices and spacebands into a vertical channel where they aligned face-to-face along adjustable rails. Matrices rested on upper rails by their ears, while spacebands suspended below on parallel lower rails, ensuring the composing faces formed a continuous line; the overall line length was fixed by movable stops at the channel's end, typically set to standard newspaper column widths of 12 to 13 picas. This mechanism automatically oriented characters in reading sequence from left to right, with the operator monitoring the assembly through a slotted front plate to insert additional spacebands as needed for even rough justification before transferring the line upward.^[26]^[40] In the composition process, the operator began by typing the desired text on the keyboard, with each keystroke actuating cams and levers to release the corresponding matrix from the magazine into a descending chute leading to the assembler elevator. Concurrently, spacebands were inserted at word boundaries to approximate justification, creating a loosely spaced line that filled the assembler's fixed length without final tightening. Upon completing the line—signaled by the last matrix or spaceband reaching the stop—the assembled stick elevated the components for transfer, allowing the operator to proofread and correct errors before proceeding to casting, thus streamlining the transition from input to slug production.^[1]^[38]

Casting Mechanism

The casting mechanism of the Linotype machine is responsible for transforming the assembled line of matrices into a solid metal slug through a rapid process of melting, injection, justification, and ejection. Once the line of matrices and spacebands is prepared in the justification vise, it is positioned against the mold disk, where molten metal is forced into the impressions formed by the matrices. This process ensures the creation of a precisely formed line of raised type on one side of the slug, ready for printing use.^[41] The mold disk is a rotating brass disk featuring multiple slots of varying widths to accommodate different line lengths (measures), such as 12–26 picas for standard newspaper columns, which align precisely with the assembled line for casting. During operation, the disk rotates a quarter-turn to position the selected mold slot in front of the matrix line, locking into place via studs and blocks in the vise frame to ensure a secure fit. The disk is water-cooled to facilitate rapid solidification, preventing warping and maintaining accuracy across repeated cycles.^[41] Molten metal is held in the crucible, an electric- or gas-heated pot maintained at temperatures between 535°F and 550°F to keep the alloy in a fluid state suitable for casting. A plunger, fitting closely within the pot's well, is activated to force the molten metal through a mouthpiece into the mold slot under mechanical pressure, filling the character impressions and spaceband gaps in under two seconds. Proper plunger fit and vent adjustments are critical to produce solid slugs without voids, with oversize plungers available for worn components to maintain pressure integrity.^[41] Justification occurs dynamically during casting as the spacebands, which have tapered brass shanks and expanding lead wedges, slide upward under the pressure of the vise and molten metal, filling the line to the exact mold width. Clean spacebands and minimal clearance (0.003 to 0.005 inches) between the mold and matrices ensure even expansion and prevent thin spots. After filling, the metal cools briefly in the mold, solidifying into a slug approximately 0.918 inches high with raised type on one face.^[41] The solidified slug is then ejected downward by an ejector blade adjusted to the slug's length, passing through trimming knives that shear the back and sides for parallel edges and precise dimensions. The trimmed slug drops into a galley for collection and cooling, completing the casting cycle in seconds and allowing the machine to produce up to eight lines per minute under optimal conditions. The mold disk then retracts and rotates to prepare for the next line.^[41]

Distribution System

After the line of type is cast, the matrices are automatically transported to the distribution system for sorting and reuse. This process begins with the line being elevated by a second elevator, operated by cam No. 6, which raises the matrices from the transfer position to the distributor box at the top of the machine. The distributor bar, suspended between continuously rotating distributor screws and fastened rigidly to the distributor beam by machine screws and dowel pins, serves as the primary sorting component. It features seven parallel combination rails with precisely cutaways and V-shaped teeth that interact with the notched edges of the matrices as they are propelled along the angled bar by the screws' revolving action.^[27] Each matrix bears a unique pattern of seven teeth on the sides of its upper triangular opening, encoding a 7-bit binary configuration that distinguishes up to 128 possible character variations. As the matrix advances, the rails provide support via their teeth and grooves until reaching a point where the specific cutaway for its tooth pattern removes the support, causing the matrix to drop into the corresponding channel of the magazine below.^[42]^[43] In machines with multiple magazines for different fonts, additional distributor bars—each tailored to the channel count of its magazine, such as 92 for the main or 28 for auxiliaries—are employed to route matrices accurately without cross-contamination. The transport involves an endless matrix conveyor belt and three distributor screws (two front and one rear) that ensure smooth progression, with a star wheel aiding transfer between rails to the delivery channel.^[28] From the distributor bar, matrices enter the primary distributor box, where slot combinations cut into the matrix bottom align with fixed bridges to direct them into specific magazine channels; flexible partitions at channel entrances prevent misalignment. Matrices with all seven teeth intact (binary code 127), typically pi or damaged ones, fail to drop at any point and are diverted to a dead box for manual retrieval and repair.^[42] This automated sorting eliminates manual intervention, enabling uninterrupted cycles and high throughput; for instance, later models using two-pitch distributor screws (two threads per inch) achieved twice the speed of earlier four-pitch designs by reducing clogs and accelerating matrix movement.

Impact and Legacy

Revolution in the Printing Industry

The introduction of the Linotype machine dramatically transformed labor in the printing industry by accelerating typesetting speeds, allowing a single operator to produce type at rates 4 to 8 times faster than traditional hand composition. Whereas hand compositors typically set around 1,200 ems per hour—equating to several hours for a full newspaper page—the Linotype enabled outputs exceeding 5,000 ems per hour, reducing the time required for page composition to a fraction of previous durations and slashing labor requirements by approximately 50%.^[8] This efficiency was pivotal for enabling daily mass-circulation newspapers, such as Joseph Pulitzer's New York World, which adopted the machine to produce larger editions and reach circulations exceeding 300,000 by the 1890s, far surpassing what manual methods could support.^[8]^[1] The Linotype shifted the printing sector from an artisanal craft reliant on skilled manual labor to an industrialized process, fostering the expansion of daily journalism and advertising by the early 20th century. By 1911, over 25,000 machines were in daily operation worldwide, permitting newspapers to increase page counts, publish multiple editions, and incorporate more content, which in turn spurred a boom in advertising revenue as publishers could afford expansive layouts.^[8] This mechanization democratized information dissemination, transforming journalism from elite-oriented reporting to broad public engagement and fueling the growth of urban dailies that covered diverse topics for mass audiences.^[7] Economically, the Linotype lowered production costs, making newspapers more affordable and accessible, with prices dropping to the penny level and circulations soaring across the U.S. and Europe. However, these efficiencies also reshaped labor dynamics, contributing to tensions with unions as automation displaced traditional compositors; this culminated in major disputes, such as the 1962–1963 New York City newspaper strike led by the International Typographical Union, where 17,000 workers, including Linotype operators, halted production for 114 days to resist computerized typesetting that threatened their roles.^[44]^[45] In comparison to contemporaries, the Linotype proved superior for high-volume newspaper work due to its line-casting efficiency, outperforming the Monotype system's individual character casting, which was better suited for book production requiring frequent corrections but slower for daily deadlines. The Intertype, a licensed variant essentially copying the Linotype design, offered minor mechanical simplifications but lacked the original's extensive matrix library and market dominance. An early rival, the Typograph, briefly competed in the 1890s but failed to match the Linotype's reliability and adoption rate, as evidenced by the New York World's initial use of 100 Typographs before transitioning to Linotypes.^[39]^[8]

Decline and Modern Preservation

The decline of the Linotype machine began in the 1950s with the advent of phototypesetting technologies, which offered greater flexibility and efficiency over hot-metal casting. Early phototypesetters, such as the Lumitype (also known as Photon), emerged in the early 1950s as the first successful second-generation systems, projecting characters onto film or photosensitive paper without the need for molten metal.^[46] By the 1960s and 1970s, these systems proliferated, with innovations like cathode-ray tube (CRT) displays enabling faster composition for newspapers and magazines, gradually displacing Linotype in major publishing operations.^[47] The transition accelerated in the 1980s as computer-based desktop publishing tools, including the 1985 introduction of the Apple Macintosh combined with Adobe PostScript and Aldus PageMaker, allowed direct digital typesetting, rendering hot-metal methods obsolete for most commercial use.^[47] Major U.S. newspapers phased out Linotype machines by the late 1970s to early 1990s, with the industry-wide shift to digital workflows completing the decline by around 1995.^[47] Despite widespread obsolescence, the Linotype persisted in niche applications, particularly specialty printing where its tactile, high-quality output remained valued. In the United States, the Saguache Crescent, a weekly newspaper in Saguache, Colorado, continues to use a 1920s-era Mergenthaler Model 14 Linotype machine for casting slugs as of 2025, making it the last known newspaper in America to do so.^[48] This persistence highlighted the machine's durability in small-scale, rural settings, though parts scarcity and maintenance challenges limited broader revival.^[49] Modern preservation efforts focus on archiving and restoring surviving units to safeguard printing history. The Smithsonian Institution's National Museum of American History holds the Mergenthaler Linotype Company Records, a comprehensive archive documenting typeface development and company innovations from 1886 to 1997.^[50] The Museum of Printing in North Andover, Massachusetts, maintains three operational Linotypes—including an 1883 model and a 1972 Elektron II—through fundraising for repairs and operator training, while offering public demonstrations.^[49] Other institutions, such as The Henry Ford museum and the Oregon Historical Society, house restored machines for exhibits, supported by hobbyist communities that share repair expertise.^[51]^[52] In contemporary contexts, Linotype machines serve educational and artistic purposes, fostering appreciation for typography's mechanical roots amid digital dominance. Museums conduct workshops and seminars to teach operation, emphasizing the machine's role in historical mass communication.^[49] Hobbyist groups and letterpress revivalists use preserved units to create custom slugs for artisanal prints, blending traditional craftsmanship with modern design in events like Dublin's Printfest, where Linotype demonstrations attract enthusiasts combating "digital fatigue."^[53] These initiatives underscore the Linotype's enduring legacy as a bridge between analog precision and today's printing heritage.^[53]

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[PDF] LINOTYPE KEYBOARD OPERATION - Drukwerk in de Marge
After a matrix line has been cast, it is transferred to the top of the machine to a distributing mechanism, which automatically sorts out the matrices and ...Missing: core workflow
[37]
Linotype and Intertype - Letterpress Commons
The Linotype is considered to be the first commercially successful automated typesetting machine. While the development of the machine was iterative, ...
[38]
[PDF] Linotype Instruction Book - GalleyRack.com
In the figure the matrices shown at 46 are in the raised, or italic, position, and the matrices shown at 47 are in the lower, or roman, position. These two ...
[39]
General Maintenance Part III - Casting - Linotype.org
Line Stop-On all late-model machines the line stop is automatically carried to the right each time a line is transferred to the second elevator. The tension ...Missing: per | Show results with:per
[40]
FAQs, Myths, & Misconceptions (Linotype/Intertype) - Circuitous Root®
Each main magazine holds a single "matrix font." This is a single style of type (e.g., Caslon) at a single body size (e.g., 12 point). At first each Linotype ...Missing: switching | Show results with:switching
[41]
Six Centuries of Type & Printing 9780999489772, 9780999489789
Each Linotype matrix has a unique pattern of teeth jutting out from a V ... This is effectively a 7-bit binary code allowing for up to 128 combinations.
[42]
How the 1962-63 Newspaper Strike Crippled a Newspaper Town
### Summary of 1962-63 Newspaper Strike Related to Printing Technology and Unions
[43]
The Great Newspaper Strike of 1962-63 | On the Media
Fifty years ago this month, 17000 New York City newspaper workers went on strike, shuttering the city's seven daily papers for 114 days.
[44]
The first phototypesetting machine | Type Network
Oct 6, 2024 · In 1970 a new Linotype hot-metal machine cost $30,000. It was probably not a coincidence that their smallest, computerized phototypesetter, ...Missing: decline | Show results with:decline
[45]
The day the typesetting industry died - WhatTheyThink
Dec 16, 2011 · Typesetting declined due to phototypesetting, desktop publishing, and designers bypassing services, with a decline from 1985 to 1995.
[46]
The forgotten Linotype machine - Itemlive
For nearly 100 years, the Linotype machine was the mainstay of nearly every newspaper in the world. Its importance was so significant ...<|separator|>
[47]
Help Save the Linotype - Museum of Printing
The Linotype's historical impact is at risk due to few remaining machines, lack of operators, and hard-to-find parts. The Museum is fundraising to preserve it.
[48]
Mergenthaler Linotype Company Records | Smithsonian Institution
Mergenthaler Linotype Company Records, 1886-1997, Archives Center, National Museum of American History. Arrangement. The collection is arranged into 13 series.
[49]
Linotype Composing Machine, circa 1915 - The Henry Ford
Free delivery over $75 Free 30-day returnsDimensions ; Height: 81.5 in ; Width: 53.5 in ; Length: 56.5 in ...Missing: ems | Show results with:ems
[50]
“Imagine the headlines!”: A 1915 Linotype Machine's New Home at ...
Apr 19, 2022 · The Oregon Historical Society's museum officially welcomed a new object to its collection, a 1915 Linotype machine that was once used by the “Oregonian” and “ ...
[51]
From linotype to letterpress, the joy of hands-on printing
Mar 31, 2018 · Dublin's National Print Museum's classes and workshops show the medium is far from dead.