Kyocera : New KYOCERA a-Si Photoreceptor Drum for Document Equipment Improves Durability, Reduces Internal Friction by 30 Percent
This news release is intended for media purposes, and is current of the date of publication. Information is subject to change without notice.
March 21, 2017
Kyocera Corporation (President: Goro Yamaguchi) introduced a new imaging component that is expected to set a new standard for durability in office document equipment, including laser printers and multifunctional products (MFPs) that use electrophotographic technology.
Kyocera's new LF Series amorphous silicon (a-Si) photoreceptor drum features a coefficient of friction 30 percent lower than that of the company's conventional a-Si drum, while upholding the conventional model's status of offering the world's longest operating life (approximately 1 million printed pages without drum replacement). The new product is now available for shipment to equipment manufacturers worldwide.
|Product name||LF Series a-Si photoreceptor drum|
|Production facility||Shiga Yohkaichi Plant (Japan)|
Kyocera has promoted environment-friendly document equipment through its long-life a-Si photoreceptor technology since 1984. The company hopes that the longer equipment life made possible by its newly developed LF Series print drum will reduce environmental impact even further.
Many types of printers on the market today utilize disposable imaging components. In contrast, since the launch of Kyocera's first a-Si photoreceptor drum in 1984, the company has used its proprietary technology to continuously develop the photoreceptor drum into a durable device with a lifespan equivalent to the mechanical life of the printer itself.
Enhancing the lifespan of electrophotographic printing equipment requires not only a more durable photoreceptor drum, but also more long-lasting internal components. Reducing the friction of the photoreceptor drum surface is therefore essential, since this surface forms a contact interface with numerous other internal components that are all subjected to increasingly faster print speeds.
Kyocera developed the world's first a-Si photoreceptor drum with submicron-sized asperities by combining its proprietary thin-film forming expertise utilizing DC electricity with its surface-processing technology.
1. Surface with submicron-sized asperities reduces friction with peripheral components
The photoreceptor drum surface possesses submicron-sized asperities created through Kyocera's surface-processing technology to decrease the area of contact with peripheral components and thereby reduce the coefficient of friction by approximately 30 percent. The new photoreceptor drum thus helps extend the lifespan of peripheral components and the printer itself.
2. Contributing to higher-quality printing through improved toner-cleaning performanceHigher-quality printing can be attained using toner particles with a nearly-perfect spherical shape for uniform toner transfer. However, toner with irregularly-shaped particles is commonly used because spherically-shaped particles reduce efficiency in toner-cleaning systems. The LF Series reduces friction at the cleaning-blade interface by forming precisely controlled, submicron-sized asperities on the surface of the photoreceptor drum. This unique feature simplifies toner cleaning while enabling the use of toner particles having a nearly perfect spherical shape, thus contributing to higher-quality printing. By combining Kyocera's thin-film technologies (utilizing DC electricity) and advanced surface processing technologies for photoreceptor drums, the LS Series provides the industry's highest level of print quality while lasting up to approximately 1 million pages.
*1) Compared to Kyocera's conventional a-Si drum with similar functions.
*2) World's longest operating life among conventional a-Si drums with similar functions, based on research by Kyocera as of January 18, 2017.
*3) World's first a-Si photoreceptor drum with submicron-sized asperities for electrophotographic printing, based on research by Kyocera as of January 18, 2017.