Fact-checked by Grok 2 weeks ago

Computer to plate

Computer-to-plate (CTP) is a technology in offset that enables the direct imaging of pages from computer files onto plates using specialized platesetters, eliminating the intermediate step of exposing plates through . Emerging in the early amid the shift toward workflows in —with the first system introduced by Agfa in 1993—CTP represented a major advancement over conventional computer-to-film methods, which relied on analog intermediates prone to errors like distortion or scratches. Early developments included thermal imaging systems introduced by companies like around 1995–1996, which used diodes to create high-resolution images on specialized plates. By the early , CTP had become the industry standard for , newspaper, and book , driven by its integration with software and raster image processors (RIP) that convert files—such as or formats—into precise plate-ready data. The core process begins with digital artwork being processed by an to generate bitmap data, which a platesetter then transfers to the plate material using lasers in the ultraviolet, visible, or spectrum. Common plate types include aluminum substrates coated with photopolymers, silver halides, or thermal-sensitive layers; for instance, thermal CTP induces physical changes via heat to form images without chemical developers, while laser systems rely on photochemical reactions. Variations like chemistry-free or processless plates further simplify operations by requiring no post-exposure processing, and direct imaging () systems combine plate-making with on-press . As of 2025, platesetters typically cost from about $50,000 for entry-level models to over $200,000 for high-end units, reflecting their capability for resolutions up to 600 lines per inch and dot sizes as small as 1%. CTP offers substantial advantages, including shortened times—from hours to as little as 45 minutes—higher productivity through electronic , and superior print quality with reduced and fewer generational losses. Economically, it cuts costs by removing film, silver-based chemicals, and manual labor, while environmentally, it minimizes , , and toxic emissions; one reported a printer reducing chemical use by 205 gallons and by 2,370 pounds annually after adopting CTP. These benefits have made CTP indispensable for modern , supporting applications from high-volume packaging to variable data jobs.

Overview

Definition and principles

Computer-to-plate (CTP) is a technology used in that enables the direct transfer of images from a computer file to a printing plate, eliminating the need for intermediate steps. This approach streamlines operations by integrating digital data processing with plate exposure, reducing handling errors and material waste associated with analog workflows. The fundamental principles of CTP rely on exposure to sensitize or alter the plate's surface, creating distinct and non-image areas based on the digital input. Central to this is raster image processing () software, which interprets digital files—such as PDFs or —incoming from applications and converts them into high-resolution patterns suitable for the imaging device. These bitmaps define the precise positioning of dots, lines, and colors, ensuring accurate of the original artwork through controlled . The core workflow in CTP begins with digital file preparation, including preflighting, color management, and imposition to arrange pages on the plate layout. This is followed by exposure in an imaging device, where the laser scans the plate according to the bitmap data to form the image. If required by the plate type, a development step removes or reveals the exposed/unexposed areas, after which the plate is mounted directly onto the printing press for ink transfer during production. CTP achieves superior image quality through resolutions typically ranging from 2400 dpi to 2540 dpi or higher, allowing for precise dot placement and screens that capture fine details unattainable in traditional film-based methods, which suffer from resolution losses due to and contact exposure variability. This precision results in sharper edges, reduced moiré patterns, and consistent color fidelity across print runs.

Historical development

The development of computer-to-plate (CTP) technology originated in the early , building on advancements in that enabled direct digital image creation and the growing need to eliminate costly intermediate film steps in traditional platemaking. Companies such as Creo, Screen, and Agfa pioneered early systems, with Agfa introducing the first CTP imaging technology in to bypass processes entirely. These innovations were driven by the desire to streamline workflows and reduce expenses associated with film materials and processing, which had become increasingly burdensome as digital tools proliferated. A pivotal milestone occurred in 1995, when Creo launched the first commercial thermal CTP systems, including the Lotem external platesetter and the , showcased at major trade shows like Drupa and Graph Expo. These systems utilized imaging to directly expose plates, marking a shift from earlier visible-light prototypes and gaining rapid attention for their potential to improve image quality and efficiency in . By the late 1990s, adoption began among large-scale printers, though high costs initially limited broader use. In the 2000s, CTP expanded significantly with the widespread adoption of thermal plates by manufacturers like and , which offered superior resolution and stability compared to earlier photopolymer options. This period also saw the rise of violet technology, which became dominant in due to its cost-effectiveness and compatibility with high-volume production, particularly in and . Key innovations included the introduction of processless plates in the mid-2000s by companies such as Agfa (2004) and (2005), which eliminated chemical development steps, further simplifying operations. Additionally, mid-2000s integration with digital workflow standards like the Job Definition Format (JDF) enabled automated data exchange across systems, enhancing overall efficiency. Growth in CTP adoption was propelled by environmental considerations, as the technology reduced reliance on hazardous chemicals and silver-based processing, aligning with regulations aimed at minimizing in operations. Economic factors, including rising prices and the push for leaner production, further accelerated its transition from niche to standard practice in commercial by the early 2010s.

Imaging systems

Internal drum imagesetters

Internal drum imagesetters represent a core technology in computer-to-plate (CTP) systems, where the printing plate is secured inside a cylindrical that rotates during . The plate is loaded flat against the drum's interior surface, and a beam from a stationary imaging head scans across the drum's width as it spins to expose the plate along its length. This design, evolved from earlier computer-to-film imagesetters, ensures precise registration by minimizing vibrations through the drum's balanced rotation. Key components include the spinning , typically driven by a for smooth, vibration-free operation; an imaging head with diodes that directs the beam via mirrors; and a hold-down to maintain plate stability against the drum surface. The imaging head moves linearly along the drum's using a high-precision motor, achieving positional accuracy as fine as 0.0004 mm. These elements work together after (RIP) preparation of digital files, directing the exposure without intermediate . This configuration offers unique advantages, such as easy plate loading and independence from plate size variations, allowing handling of large formats up to 40 by 60 inches with high accuracy and registration suitable for demanding applications like and printing. Operational specifications typically include exposure speeds of 20 to 35 plates per hour, depending on resolution and laser configuration, using (around 405 nm) or (around 830 nm) lasers for or plates. Maintenance focuses on calibration of drum alignment and laser intensity to avoid exposure distortion, often supported by automated systems like continuous calibration technology that monitor and adjust in real time. Modular designs facilitate laser diode upgrades and repairs without full disassembly, promoting longevity in high-volume environments.

External drum imagesetters

External drum imagesetters represent a key technology in computer-to-plate (CTP) systems, where a flexible printing plate is mounted on the exterior of a rotating , and a imaging head scans parallel to the drum's axis to expose the image directly onto the plate surface. This design leverages the drum's rotation to handle the circumferential scanning, while the linear movement of the imaging head addresses the axial direction, enabling efficient exposure for applications. The primary components include the external drum equipped with precise tensioning and clamping mechanisms to secure the plate uniformly, preventing distortion during high-speed rotation, and high-precision arrays or grating light valve (GLV) systems that generate fine dots for reproduction. These lasers, often operating at wavelengths around 830 nm for plates, ensure consistent energy delivery to the plate . External drum imagesetters excel in commercial environments requiring fine-line work, such as magazines and brochures, owing to their ability to produce sharp dots with minimal geometric distortion, thanks to the even tensioning and stable rotation of the . In the broader CTP , they integrate seamlessly for direct exposure, bypassing intermediates to streamline production. Performance capabilities typically include resolutions up to 4000 dpi, supporting intricate screens for high-quality output, with plate sizes ranging from approximately 400 x 300 mm to 1163 x 940 mm to accommodate various press formats. Throughput speeds vary by model but can reach 50-60 plates per hour at standard resolutions, making them suitable for mid-to-high volume operations. Innovations in this technology focus on multi-beam laser configurations, such as multiple imaging heads or GLV arrays with 512 or more channels, which enable parallel and reduce imaging time by up to 50% compared to single-beam systems, enhancing overall productivity without compromising precision.

Flatbed imagesetters

Flatbed imagesetters represent a category of computer-to-plate (CTP) imaging systems where the printing plate is positioned stationary on a flat surface, and occurs through linear movement of the head across the plate in the XY axes via a mechanism. This contrasts with drum-based systems by accommodating rigid or thicker plates that cannot be easily curved, enabling direct without mechanical distortion. The process typically involves a beam or light source directed line-by-line onto the plate, often using a rotating mirror for beam deflection to ensure precise raster scanning. Key components of flatbed imagesetters include a table that secures the plate flat against the bed to prevent movement and ensure uniform contact during exposure. The imaging system employs arrays, such as UV lasers at 405 nm, or LED arrays at 375 nm, sometimes in configurations combining multiple wavelengths for plate . Automated plate loading mechanisms, including registration systems for alignment accuracy within 5 μm, facilitate efficient handling, particularly in production environments. Dynamic features maintain optimal focus across the plate surface, compensating for any minor irregularities. These systems find primary applications in flexographic and gravure , where they excel with thicker, non-curling plates required for corrugated and specialty substrates like , aluminum, or polymer bases. They support diverse formats, including letterpress, screen stencils, and , making them ideal for and production that demands custom plate shapes and sizes. Technical specifications for flatbed imagesetters typically include exposure areas ranging up to 1400 by 1900 (approximately 55 by 75 inches), accommodating large-format plates for industrial applications. Resolutions commonly achieve 2400 to 4000 dpi, with options extending to higher levels like 6350 dpi for fine screening up to 300 LPI, ensuring sharp image reproduction on various substrates. Processing times vary by plate type and size, generally spanning 5 to 15 minutes per plate for applications, though flexographic plates may require longer exposures of 95 to 285 seconds per square meter due to material sensitivity. While effective for specialty and rigid plate imaging, flatbed imagesetters are generally slower for high-volume production compared to drum systems, with potential reductions in accuracy at plate edges due to beam deflection variations. They adapt well to digital-analog workflows, such as CTCP systems using UV exposure on conventional plates, bridging traditional and fully digital processes in mid-sized operations.

Plate materials

Photopolymer plates

Photopolymer plates for computer-to-plate (CTP) systems consist of an aluminum substrate typically 0.15-0.3 mm thick, coated with a photosensitive layer containing acrylate-based resins and photoinitiators such as benzophenones or thioxanthones, which enable hardening through cross-linking upon ultraviolet exposure, and often topped with a thin protective layer of polyvinyl alcohol (PVA). These plates operate on a negative-working principle, where the polymer base selectively polymerizes in response to UV light, forming durable image areas while leaving non-image regions soluble for removal. The mechanism relies on a violet diode at 405 nm , which activates the photoinitiators to initiate free in the exposed areas, creating oleophilic image regions that attract during , followed by to wash out the unpolymerized, hydrophilic non-image areas. This process requires an of 70-90 μJ/cm² and is compatible with various CTP imagesetters, including internal and external systems optimized for violet sensitivity. These plates exhibit high durability, supporting run lengths of up to 200,000 impressions without baking and over 1,000,000 impressions with post-exposure at 200-250°C for 10-20 minutes, alongside excellent ink receptivity in the cured image areas and resistance to chemical degradation from pressroom solutions. The oleophilic nature of the polymerized surface ensures consistent ink transfer, while the cross-linked structure provides abrasion resistance suitable for medium- to high-volume . Processing involves aqueous development using a weak alkaline or solution at 24-26°C for 20-30 seconds to remove unexposed material, often followed by a brief preheat at 105-110°C and step, with a of 12-24 months when stored in cool, dry conditions away from light and humidity. This aqueous-based method contrasts with solvent-intensive traditional processes by minimizing generation. Environmentally, plates contribute to reduced (VOC) emissions compared to conventional solvent-developed plates, as their low-chemistry or water-washable processing eliminates the need for organic solvents, lowering overall chemical usage and improving workplace safety.

Silver halide plates

Silver halide plates represent one of the foundational technologies in computer-to-plate (CTP) systems, utilizing a photosensitive derived from traditional photographic principles. These plates consist of a thin layer of crystals, primarily , dispersed in and coated onto a grained and anodized aluminum , often with an barrier layer and a protective to enhance durability and handling. The is highly sensitive to blue-violet light, typically at wavelengths around 405 , enabling direct without intermediate films. The imaging process begins with laser exposure from a CTP imagesetter, where the violet laser diodes—operating at power levels such as 30 mW—selectively illuminate the emulsion, creating a latent image by reducing silver ions to metallic silver atoms in the exposed areas through photochemical reaction. Following exposure, the plate undergoes chemical processing: an alkaline developer dissolves the unexposed silver halide, revealing the silver image in the printing areas, while subsequent steps like diffusion transfer, rinsing, and application of a finisher gum protect the plate from oxidation and prepare it for press. This diffusion transfer mechanism typically completes in about 30 seconds, followed by a 20-second finishing step, ensuring precise image formation. A primary strength of silver halide plates lies in their superior halftone dot reproduction, achieving razor-sharp edges and resolutions exceeding those of many alternatives, which supports exceptional detail in high-end applications like . They also offer wide exposure latitude and extreme —below 1 μJ/cm²—allowing consistent results across varying imaging conditions and minimizing defects from over- or underexposure. These qualities make them particularly suitable for reproducing intricate graphics where tonal gradations and fine lines are critical. In terms of performance, silver halide plates deliver run lengths of up to 350,000 impressions without post-baking, though this can extend further with additional treatments, providing reliable output for mid-volume commercial jobs. The chemical processing, while effective, involves closed-loop systems with alkaline developers and finisher baths to manage effluent, though it generates silver-laden waste requiring specialized handling. Historically, these plates served as an early standard for CTP in the 1990s, leveraging proven silver-based technology adapted from film imaging to violet lasers, but their use has declined due to environmental concerns over chemical waste and the rise of processless alternatives. They are often imaged in external drum systems to maximize precision for such high-resolution needs.

Thermal plates

Thermal plates in computer-to-plate (CTP) systems feature a heat-sensitive applied to a grained and anodized aluminum , typically incorporating infrared-absorbing dyes, resins, and acid-release agents in the photosensitive layer to enable . This composition allows the plate to respond to without reliance on light-sensitive chemistry, distinguishing it from or silver-based alternatives. The exposure mechanism employs an infrared laser operating at wavelengths of 800-830 nm, which generates localized on the plate surface, typically reaching 130-140°C for brief durations to induce chemical changes. In conventional plates, this heat causes in non-image areas by vaporizing or dissolving the , or shifts in the exposed regions, rendering them alkali-soluble while image areas remain insoluble after curing. Energy requirements for generally range from 100-250 mJ/cm², ensuring efficient reproduction with resolutions up to 1-99% at 200-450 lpi. Unique features of thermal plates include processless formulations that eliminate the need for chemical development, enabling direct-to-press imaging and ratios suitable for demanding applications. They excel in printing, supporting run lengths exceeding 100,000 impressions without baking, and up to 1 million with post-baking for enhanced durability. These plates integrate seamlessly with internal imagesetters for stable, high-speed production. Processing variants encompass conventional thermal plates, which require wet processing with alkaline developers and rinsing, versus process-free options that rely on thermal ablation, polarity conversion, or hot-melt mechanisms to form images without additional steps. The former produces chemical waste but offers robust performance for long runs, while the latter minimizes environmental impact by avoiding developers entirely. Advancements in the have shifted toward eco-friendly, low-chemistry versions, including processless plates that reduce water consumption and significantly, with some systems achieving up to 95% lower emissions and eliminating wastewater discharge. These innovations, such as Fujifilm's low-chemistry plates, cut resource use by extending developer bath life and lowering replenishment needs, promoting in commercial and .

Comparison to traditional methods

Advantages

Computer-to-plate (CTP) technology provides substantial cost savings over traditional computer-to-film (CTF) methods by eliminating the need for intermediate and associated processing materials, such as silver-based films and developer chemicals. In practical implementations, these savings can amount to $80,000 annually in costs alone for mid-sized operations, alongside reductions in chemical purchases by approximately $1,600 per year and disposal by $9,500 annually. CTP enhances print quality by delivering higher and superior dot integrity, bypassing potential distortions from handling, enlargement, or variations in CTF processes. Thermal CTP systems, in particular, support line screens exceeding 200 lpi with minimal , resulting in sharper images, finer details, and more accurate color reproduction. This direct digital transfer also achieves registration accuracy within ±2%, minimizing misalignments that could occur during -to-plate contact. The speed of production is markedly improved with CTP, as direct imaging condenses platemaking from several hours in CTF workflows—typically involving film output, development, and manual alignment—to as little as 45 minutes per plate set, enabling faster turnaround for high-volume or time-sensitive jobs like newspapers. Commercial CTP systems can output up to 60 B1-sized plates per hour at 2400 dpi, further accelerating overall efficiency by up to 50%. Environmentally, CTP reduces chemical consumption by up to 205 gallons per year and generation by over 2,300 pounds annually per operation, primarily by obviating film processing and silver-laden effluents. These reductions in waste and resource use support compliance with standards such as ISO 14001, promoting greener printing practices without compromising output. CTP ensures greater consistency through digital repeatability, where plates produced from the same file exhibit uniform quality across multiple runs, with reduced variability in dot reproduction and plate-to-plate alignment compared to CTF's analog steps. This reliability minimizes rework and errors, fostering predictable results in extended production cycles.

Disadvantages

One significant barrier to adopting computer-to-plate (CTP) is the high upfront of systems, which can range from under $50,000 for basic visible light models to over $100,000 for systems, with examples like mid-range units costing around $165,000. Additionally, ongoing maintenance, particularly for components, adds to operational expenses; replacement of a CTP head can cost between $6,500 and $11,500, with regular servicing required to prevent performance degradation. CTP plates are also slightly more expensive than traditional plates, which can impact savings for low-volume jobs. CTP systems impose stringent technical demands, necessitating precise environmental controls to ensure reliable and avoid plate defects such as uneven or loss. Recommended conditions vary by manufacturer and ; for example, platesetters operate effectively from 17–30°C (63–86°F), while certain plate types require 24–26°C with relative at 40–70%. Compatibility challenges arise when integrating CTP into legacy workflows, as older systems may require upgrades to (RIP) software to handle digital file formats and layouts effectively. For instance, transitioning from computer-to-film (CTF) setups often involves updating or replacing RIP components to support direct plate imaging, potentially incurring additional software licensing and integration costs. Furthermore, CTP's reliance on digital preparation makes it less flexible for very short print runs, where the fixed setup and imaging time per plate can reduce efficiency compared to CTF's reusable intermediates. Operators of CTP equipment require specialized in digital troubleshooting, processes, and system maintenance, which can initially elevate labor costs during the adoption phase. Such emphasizes skills like for error diagnosis and familiarity with technology, often delivered through customized onsite programs to address specific needs. A key operational risk with CTP is dependency on centralized imaging equipment, where system —due to failures, software glitches, or mechanical issues—can completely halt plate production and downstream printing, unlike more decentralized CTF setups that allow film . Outdated or poorly maintained CTP devices exacerbate this vulnerability, leading to increased error rates and production delays that impact overall efficiency.

Modern applications and advancements

Industry adoption

By 2025, computer-to-plate (CTP) technology has achieved widespread adoption in the commercial sector, driven by its efficiency in digital workflows. The global CTP market is projected at approximately USD 1.86 billion in 2025, reflecting steady growth at a (CAGR) of 3.51% through 2030, fueled by demand for high-quality, waste-minimizing solutions. This penetration is particularly evident in high-volume environments, where CTP systems have become standard for producing plates directly from digital files, reducing intermediate steps like film processing. In key printing sectors, CTP dominates applications such as and . printing accounts for a significant portion of CTP usage, with the sector projected to grow at a 4.07% CAGR from 2025 to 2030, supported by the need for precise, short-run designs in flexible and folding . exhibit high adoption rates in established markets, where CTP enables rapid plate changes for daily editions and color enhancements, as seen in workflows for broadsheets and tabloids. A notable is Heidelberg's integration of CTP systems in high-volume plants, such as those using the Speedmaster 104 press, which has been installed in over 950 units since 2021 to streamline for folding cartons and labels, achieving seamless from file to plate. Economic drivers have accelerated CTP's uptake, with substantial and lower operational costs from automated plate . The technology's ability to minimize chemical usage and production time contributes to these savings, positioning the global CTP market for continued growth. Regional variations highlight this trend: and Asia-Pacific lead adoption, bolstered by stringent environmental regulations and advanced infrastructure in countries like and , while adoption in developing markets lags due to high initial capital costs for midsize printers. CTP's integration with digital presses has further enhanced its appeal in workflows, allowing printers to combine precision with digital flexibility for variable data jobs. For instance, Heidelberg's Prinect Production Manager enables seamless connectivity between CTP plate imaging and digital output devices, optimizing short runs in commercial and environments without disruptions. This pairing supports diverse applications, from personalized to newspaper supplements, solidifying CTP's role in modern operations.

Emerging technologies

In the 2020s, processless innovations in computer-to-plate (CTP) technology have introduced inkjet-based systems for direct plate writing without lasers or chemical processing, enabling production of press-ready aluminum plates. The Glunz & Jensen PlateWriter series exemplifies this advancement, utilizing inkjet to streamline workflows and reduce operational costs associated with traditional processing equipment. These systems contribute to savings, with some modern CTP configurations achieving up to 43% lower power usage during compared to earlier models. Artificial intelligence enhancements are transforming CTP through machine learning applications for automated raster image processor (RIP) optimization and real-time defect detection, improving prepress accuracy and minimizing waste. In 2023, significant progress in integration for offset printing optimization was documented, enabling predictive adjustments to exposure and imaging parameters. Such tools facilitate seamless workflow automation, particularly in high-volume environments where defect classification during plate production can reduce reprints by identifying issues like misalignment or inconsistencies early. Sustainable shifts in CTP emphasize waterless plates and recyclable substrates to align with environmental regulations, including the European Union's , which requires enhanced recyclability and reduced waste generation. Waterless CTP plates, compatible with thermal imaging, eliminate the need for dampening solutions, complying with EU REACH standards for pollutant emission limits and supporting eco-friendly offset applications. Recyclable aluminum substrates further these efforts by enabling closed-loop material recovery, driven by broader EU sustainability targets for the printing sector. Hybrid systems combining CTP with are emerging for custom plate production, particularly in flexographic applications where traditional methods limit design flexibility. A 2024 study on demonstrated viable flexographic forms for printing solid areas and fine lines using water-based inks, offering potential for customization and reduced lead times in . These integrations build on plate advancements by incorporating for enhanced plate and variable relief depths.

References

  1. [1]
    [PDF] Map Production Using Print-On-Demand Capabilities
    The advances in digital platesetters have allowed printers to take digital data straight from the computer to the press plate eliminating costly film ...
  2. [2]
    [PDF] Computer-to-Plate Lithographic Printing Introduction - NEWMOA
    Nov 7, 2006 · CTP technology significantly shortens prepress plate preparation, and reduces or eliminates the use of hazardous chemicals and waste generation.
  3. [3]
    [PDF] The Study on Exploring the Evolution of Offset Printing in World - ijarsct
    Computer-to-Plate (CTP) Technology (1990s). Replaced traditional film-based plate making. Digital files are imaged directly onto the plates using lasers.
  4. [4]
    Direct to Plate - University of Houston
    Direct-to-plate printing technology is more environmentally safe than conventional platemaking technology. Both traditional film processing and plate ...
  5. [5]
    Modern Offset Computer-To-Plate (CTP) Technology - Fujifilm
    Computer-to-plate technology generates images in a computer program and outputs them directly onto a printing plate. With CTP technology, printing is faster, ...
  6. [6]
    [PDF] Plate Imaging with Computer-to-Plate
    CtP printing plate is composed of imaged pixels and is razor-sharp. This degree of quality cannot be achieved with Computer-to-Film (CtF) processes where ...<|control11|><|separator|>
  7. [7]
    What Are The Basic Principles Of CTP? - Industry News
    Feb 21, 2024 · CTP systems allow for the direct imaging of printing plates using digital files, eliminating the need for traditional film-based processes. The ...
  8. [8]
    Computer-to-Plate Systems for All Press Sizes - SCREEN Europe
    Very Large Format CTP · The ability to produce plates up to 1600 x 2280 mm at 2540 dpi. · Fast, high-quality imaging for packaging and large-format commercial ...
  9. [9]
    Computer-to-Plate Technologies Revolutionizes the Printing Industry
    CTP technology, however, has continued to evolve. Today CTP systems have become the go-to standard in the pre-press and printing industries. CTP solutions have ...
  10. [10]
    The Beginning of Computer to Plate (CTP) | - DEI Systems
    Oct 23, 2012 · CTP technology evolved from computer-to-film (CTF) technology which we call imagesetters. There are two types of imagesetters, drum and capstan.Missing: development | Show results with:development
  11. [11]
    Creo Marks 5000th CtP Installation, Introduces Performance Upgrades
    Apr 3, 2003 · ... first commercial thermal CTP system in 1995. Today, Creo offers the three top-selling CTP product lines in the world (Trendsetter, Lotem and ...
  12. [12]
    [PDF] Computer-to-Plate White Paper - PrintPlanet.com
    Creo was the first to come out with a thermal external drum platesetter, introducing their pioneering Trendsetter at Graph Expo in October 1995. The first ...
  13. [13]
    Computer to Plate (CtP) at drupa - WhatTheyThink
    Jun 11, 2008 · While CtP has been around a long time first appearing in the 1980s, it did not really come into the spotlight until drupa 1995. At that time it ...Missing: historical | Show results with:historical
  14. [14]
    Plates - Newspaper | Fujifilm [United States]
    First launched at Ipex 2002, Fujifilm's violet photopolymer technology offers benchmark quality and cost of ownership performance, and is now being ...<|separator|>
  15. [15]
    [PDF] Laser_Imaging_Devices (1)
    • Internal drum advantages. – Easy loading. – Plate size independence. – Accuracy (image and registration). – No balancing Issues. • External drum advantages. – ...Missing: throughput | Show results with:throughput
  16. [16]
    Here's a look at the latest CTP technology. - In-plant Impressions
    Apr 1, 2008 · The platesetters are available with throughput speeds of up to 35 plates per hour ... DPX 2 is an automated, internal drum CTP platesetter ...
  17. [17]
    3 Types of Computer-to-Plate Methods - Platesetters.com
    Internal drum imagesetters can increase the difficulty of use several lasers simultaneously. However, using one laser also provides its unique advantages, ...Missing: specs | Show results with:specs
  18. [18]
    Lüscher CTP imagesetter | CHROMOS Group AG
    Maintenance-free laser technology · Fully automatic and continuous calibration · Low energy consumption · Optional optics for multiple resolutions · Easy loading ...Missing: internal drum advantages
  19. [19]
    Lüscher Technologies | Lüscher Technologies
    Advantages of the patented Lüscher Laser Diode Technology. Maintenance-free fibre optic coupled laser diode technology. Fully automatic calibration of laser ...Missing: internal drum imagesetter
  20. [20]
    CTP - 8-up | Fujifilm [United States]
    For a more economical choice, the Javelin 8600N-E utilizes a 32-channel light source and is capable of outputting up to 14 plates per hour.
  21. [21]
    ECO3 Avalon 8-up - B1 size thermal CtP platesetters
    Avalon 8-up platesetters are thermal CtP systems with fiber-coupled laser or GLV tech, offering high-quality imaging, up to 340 lpi, and are upgradable.
  22. [22]
    Platesetter 800G/800F/800L - Hans Gronhi
    Platesetter 800G/800F/800L ; Resolution. 4000dpi ; Drum Archltecture. External ; Plate Size. Max 635x762mm. Min 250x254mm. Max 635x762mm ; Plate Thickness. 0.15-3mm.
  23. [23]
    Universal Flatbed Direct Imager UV Setter Machine - McLantis Group
    The flatbed layout of MACSETTER Multi allows the integration of custom-built registering systems for perfect alignment of the image on the printing plates. As a ...
  24. [24]
    What Type of Construction is Your Computer-to-Plate Imagesetter?
    External drum CTP image setters make it possible for machine operators to arrange multiple image heads next to each other and concurrently use several image ...Missing: specs | Show results with:specs
  25. [25]
    A Comprehensive Analysis of UV CTP Printing Plates
    Aug 27, 2025 · 1. Substrate Layer (Support). - Aluminum substrate (usually 0.15-0.3mm thick pure aluminum or aluminum alloy plate); · 2. Base Coat (Undercoat).
  26. [26]
    Low Chemistry Violet Photopolymer CTP Plate - McLantis Group
    Plate Type. Negative working. Gauge. 0.15/0.30 mm. Spectral Sensitivity. 405 nm. Exposure Energy. 70 - 90 mj/cm2. Resolution. 2% - 98% at 175lpi. Run Length.Missing: mechanism washout
  27. [27]
    Violet Photopolymer CTP Plate
    SV violet CTP plate combines wide exposure latitude with consistent, durable printing that can yield 250,000 impressions (1,000,000 impressions with post baking) ...
  28. [28]
    Violet CTP Plates: The choice for efficient and fine printing
    These plates are sensitive to violet lasers, typically with a wavelength of 405 nm, which is used to expose the image onto the plate surface. Violet CTP Plates ...Missing: mechanism polymerization washout
  29. [29]
    Positioning Solvent, Water-Wash, Thermal & Liquid Flexographic ...
    Water-wash photopolymer processors are one of the most environmentally friendly ways to create plates in the industry because they are solvent-free and reduce ...
  30. [30]
    [PDF] the properties of photographic emulsions
    Photographic emulsions consist of gelatine with silver-halide crystals, mainly silver-bromide, with crystal sizes from ~0.03 um to ~20 μm. Nuclear emulsions ...<|separator|>
  31. [31]
    [PDF] a new red-sensitive silver DTR plate system for CTP imaging
    Silver halide diffusion transfer, photopolymer and hybrid plates are sensitive to visible laser light, ranging from blue to red. They are all called 'high ...Missing: composition bromide
  32. [32]
    Types of CTP plates | HC Aluminum
    Jun 27, 2025 · Long shelf life and good storage stability. Photosensitive Plate, Violet CTP Plate, Uses 405–410 nm violet laser to expose the coating on the ...
  33. [33]
    Plates: The unsung hero of print! - Printweek
    May 26, 2010 · Sachin Shardul verifies the print performance of printing plates - including history, technology, chemistry and waste in order to help ...
  34. [34]
    Making the right choice in CTP printing plates - Agfa White Paper.
    Jan 29, 2007 · Silver halide CtP plates (from e.g. MPM or Agfa) are rated for runs of up to 350,000 and sometimes more.
  35. [35]
    CTP - trends and technology, part 1 : computer-to-plate
    Silver was used by the whole world for graphic arts film, so is well proven for laser exposure. Therefore, silver technology was a natural choice for CTP.Missing: advantages halftone
  36. [36]
    Future Development of Thermal CTP
    The basic principle of heat-sensitive CTP plate imaging is that the infrared light-absorbing dye in the heat-sensitive layer absorbs the infrared laser to ...
  37. [37]
    What is thermal CTP plates? | HC Aluminum
    Jul 24, 2025 · Exposed by a semiconductor laser diode, the ink-receptive layer absorbs energy and becomes easily soluble. Exposed by infrared laser, the ...Missing: 800-830 nm
  38. [38]
    Thermal CTP Plate(Process-less) | HC Aluminum
    They reduce hazardous waste and water consumption, making the printing process more environmentally friendly. 4. Cost savings: Chemical and water usage is ...
  39. [39]
    Thermal Plate VS Processless Plate | HC Aluminum
    Feb 28, 2025 · Environmental Advantages: With reduced chemical and water use, processless plates are viewed as a more sustainable choice compared to thermal ...Missing: VOC emissions
  40. [40]
    CTP Waterless Plates
    Sep 25, 2025 · Waterless plates eliminate chemical pollution at the source: no developer or rinse water is consumed, eliminating the discharge of wastewater ...
  41. [41]
    [PDF] Low chemistry thermal plate production - Fujifilm
    They allow higher quality print to be achieved more easily, particularly when printing demanding FM, hybrid or fine-line conventional ... 100-120 mJ/cm2. 100-120 ...Missing: cm² | Show results with:cm²
  42. [42]
    What are the advantages of CTP? | HC Aluminum
    Mar 6, 2025 · The advantages of CTP include faster workflow, cost savings, superior print quality, environmental sustainability, and precise digital imaging.
  43. [43]
    CTP Technology in the Modern Offset Printing Process
    CTP eliminates the need for film by imaging the page directly from the computer to the printing plate, which, shortens production cycles and can save on ...
  44. [44]
    Computer to Plate (CTP) Market Size, SWOT, Competitive Growth ...
    Rating 4.6 (62) High initial investment costs for CTP systems can deter small to medium-sized enterprises from adopting this technology. Additionally, the ongoing ...
  45. [45]
    Kodak Trendsetter Used machines - Exapro
    Kodak Trendsetter CTP Sold · 2017 Kodak Trendsetter CTP. Paid $165,000 new Price includes loading and laser lock down Size 28 x 40 EPI Fiery RIP Under 9000 plate ...
  46. [46]
    EcooGraphix Thermal CTP Laser Head Replacement And Repair ...
    EcooGraphix Thermal CTP Laser Head Replacement And Repair Value Added Service. Price:US $6,500-11,500 per piece MOQ:1PC. Get Best Price Chat Now.
  47. [47]
    [PDF] Temperature Compensation Technology for Computer-to-Plate ...
    Temperature and Humidity Control: Maintain a stable environment. Fluctuations in temperature and humidity can affect the plates and the imaging process. Ensure ...
  48. [48]
    Precautions for using CTP - Henan Huida Print-All Technology Co., Ltd
    Maintain a stable indoor environment. The temperature in the CTP operating room should be 24-26 ℃ and the humidity should be 40-70%.
  49. [49]
    Navigator Harlequin RIP | Xitron | United States
    Extend the life of your CtP systems by updating only the necessary software. ... From in-RIP trapping to load-balancing, pay only for the features you require.
  50. [50]
    CTP PLATE ADVANTAGES AND DISADVANTAGES - Exhibition
    Jan 3, 2019 · In CTP, if for some reason a plate is damaged, if an error occurs when it's ripped or if something has to be corrected after the plate is ...
  51. [51]
    Computer to Plate Operator (CTP Operator)Skills and Knowledge
    What skills are required for Prepress Technicians and Workers? ; Speaking - Talking to others to convey information effectively. ; Critical Thinking - Using logic ...
  52. [52]
    [PDF] KODAK OPUS - Realize the full value
    Customized onsite training based on the individual needs of your operators. This option is commonly used to provide assistance for specific applications needs, ...
  53. [53]
    7 ways your CTP equipment could be hurting your business | Kodak
    Oct 3, 2024 · Outdated imaging technology, slow imaging speeds, lack of automation, large footprint, absence of power-saving features, old software, difficult ...
  54. [54]
    Computer-to-Plate (CTP) Market Size, Share & 2030 Growth Trends ...
    Jul 22, 2025 · The Computer-to-Plate (CTP) Market is expected to reach USD 1.86 billion in 2025 and grow at a CAGR of 3.51% to reach USD 2.21 billion by ...
  55. [55]
    Computer to Plate (CTP) Market Size, Growth, Share & Forecast
    Rating 4.5 (48) Computer to Plate (CTP) Market size was valued at $3.13 Bn in 2023 & is projected to reach $5.01 Bn by 2030, growing at a CAGR of 5.51% from 2024-2030.Missing: upfront | Show results with:upfront
  56. [56]
    Process Free CTP Plates Market Size, Industry Share, Forecast, 2032
    The high adoption of printing in the newspapers, rising demand for printed books & papers, and increasing consumption of printing in the packaging of products ...
  57. [57]
    The Speedmaster CX 104, Heidelberg's bestseller: four packaging ...
    Sep 4, 2025 · The Speedmaster CX 104, Heidelberg's bestseller: four packaging case studies. With over 950 units installed since 2021, the Speedmaster CX ...
  58. [58]
    Computer-to-Plate: Reliable Investment | Print Monthly
    May 15, 2023 · “Newer and more modern CtP systems will benefit from improved productivity, increased quality, in many cases a smaller footprint, and consume ...
  59. [59]
    Computer-to-Plate Printing Market Growth & Trends 2034
    Computer-to-plate for Offset Printing Market to expand from USD 2.49 Billion in 2025 to USD 4.2 Billion by 2034, CAGR of 6%.
  60. [60]
    Computer-to-Plate (CTP) Market Size ($2.1 Billion) 2030
    The global Computer-to-Plate (CTP) market was USD 1.2 billion in 2023 and is expected to reach USD 2.1 billion by 2030, with a CAGR of 7.8% between 2024 and ...Missing: composition performance<|control11|><|separator|>
  61. [61]
    Prinect Production | HEIDELBERG
    Enhance the productivity of your inte- grated digital printing presses by setting up a hybrid workflow using a compre- hensive toolset developed especially for ...
  62. [62]
    Why CTP is more essential than ever in India's print evolution - Kodak
    Jul 22, 2025 · Kodak's systems integrate seamlessly into hybrid workflows, enabling printers to adapt quickly to new demands—whether it's variable data ...<|control11|><|separator|>
  63. [63]
    Inkjet CTP | - DEI Systems
    The industry's first inkjet Computer-to-Plate system capable of producing press-ready aluminum plates without the use of chemical processing.
  64. [64]
    Saving Energy: CTP Technology Trend #3 - Kodak
    May 20, 2019 · Kodak's latest TRENDSETTER and ACHIEVE Platesetters use up to 43% less power while imaging than our previous models and up to 93% less than ...Missing: percentage processless
  65. [65]
    Computer-to-plate for Offset Printing Insightful Analysis
    Rating 4.8 (1,980) Mar 20, 2025 · Offset printing remains the dominant segment, leveraging the precision and cost-effectiveness of CTP plates for high-volume production.Missing: history | Show results with:history
  66. [66]
    Integration of Machine Learning for Defect Classification in Printing ...
    May 22, 2025 · Real-Time Quality Control During Printing: Machine learning allows for immediate detection and classification of any defects that occur when ...Missing: Agfa AI CTP RIP 2023
  67. [67]
    EU Packaging Regulations 2025: What Print Businesses Need to ...
    Sep 27, 2025 · By January 1, 2030, all packaging placed on the EU market must be fully recyclable. This goes beyond simply using “eco-friendly” materials.Missing: waterless | Show results with:waterless
  68. [68]
    Sustainability mandates in EU driving shift toward water-based DTG ...
    Aug 22, 2025 · Explore how sustainability mandates across the European Union are accelerating the adoption of water-based DTG printing methods, ...
  69. [69]
    Application of PolyJet 3D Printing in Production of Flexographic ...
    Sep 24, 2024 · Our findings indicate that the 3D-printed plates are suitable for printing solid areas and lines with water-based inks.Missing: CTP | Show results with:CTP
  70. [70]
    3Dresyns for making printing plates
    Our 3Dresyns PP for printing plates have been designed to print Printing Plates "PP" with affordable SLA, DLP & LCD 3D printers for different printing systems.Missing: hybrid | Show results with:hybrid<|control11|><|separator|>