But the region was never wealthy, and Hisao Yamazaki, the company’s founder, saw potential in the place where the raw silk industry once flourished. He envisioned a new industry that would restore vitality to the area and the lives of locals. Yamazaki returned to Suwa to take over the family business.

Together with Suwa’s Mayor and other prominent business leaders, Yamazaki approached Shoji Hattori, the managing director of Daini Seikosha (now Seiko Instruments) with the prospect of developing more precision instruments.

The group believed that Suwa’s climate was like Switzerland’s with low summer humidity, so it would be a perfect environment for a precision industry. They believed Suwa could be the Switzerland of the East and began clock assembly operations. The company had only nine employees.

In the 1980s, as awareness of risks to the ozone layer became an issue, Seiko Epson became the first company in the world to pledge to go CFC-free. Tsuneya Nakamura, a former CEO, said, “We cannot use something that we know is hurting the environment. Technology and information have no value in themselves but only become useful and valuable through humanity and creativity in the hands of people who use them.” In 1992, the company achieved a complete elimination of specified CFCs in Japan, and the following year we achieved this worldwide.

Nakamura said, “In the absence of an effective alternative, our CFC-free activities, proceeded without clear prospects for success, and challenged what's possible. We received the US Environmental Protection Agency’s Stratospheric Ozone Protection Award, which I accepted in Washington on behalf of all our employees. This was a memorable experience.”

Eighty years after our establishment, our beliefs and values remain unwavering. In 2016, we launched the PaperLab A-8000, an office papermaking system that destroys confidential paper documents and recycles the paper in a dry process, thus conserving a precious resource, water.

We have included sustainability in our long-term vision statement. Our Environmental Vision 2050 states that we will become carbon negative and underground resource free — a lofty goal that we intend to accomplish.

This event marked the beginning of efficient, compact, and precision technologies. Project 59A (its internal designation) would become the watch to change watchmaking.

The name refers to the year 1959, and “A” marks the project’s importance. It kicked off with three proposals: an electronic tuning fork watch, an area where another company already had the lead, a watch with an electric balance wheel, and a quartz timer, which was about the size of a locker at the time.

The first two proposals had critical weaknesses, so efforts went into the quartz timer, which would alter the course of horology. The first quartz timepieces we developed were still the size of table clocks, but the company began entering timepieces in the Neuchâtel Chronometer Competition in Switzerland, which determines the benchmark for timepieces. While repeatedly striving to reduce size and improve accuracy, the company began taking awards for the marine chronometer and board categories, showing the world a new level of standards. While refining technology through the Observatory Chronometer Competition, the company further reduced size and power efficiency through practical applications such as the Antarctic observation team and the Shinkansen bullet train. By 1969, ten years after the 59A project, Seiko introduced the world’s first quartz wristwatch, the Seiko Quartz Astron 35SQ.

The company not only continued to develop quartz watch technology but also pursued the advances in accuracy in mechanical watches, rivaling some big names in the Neuchâtel Chronometer Competition. In 1964, Seiko entered its first mechanical watch, placing poorly at 144th.

However, that poor result inspired improvement, and in 1968 at the Geneva Observatory Chronometer Competition, Seiko dominated the top places in the mechanical wristwatch category. This effort verified our precision technology. Among the winners was Kyoko Nakayama, the first woman to hold the title of Contemporary Master Craftsperson and the first woman in the competition’s long history to enter and win the regulateur’s prize.

High-precision competitions are like F1 races and are distinct from commercial products. To make better products available to more people, the technology and skills used to develop watches came to life in the Grand Seiko brand.

We didn’t reserve its technology to develop compact, efficient, and accurate watches for a select few. Instead, we made the technology available so that everyone could enjoy world-quality, accurate watches. The result was quartz wristwatches, a technology developed in Japan, spread around the world, putting accurate time on the wrists of the global population.

Today, Seiko Epson remains steadfast in the belief that technology alone doesn’t solve problems; the mindset of employees does.

Compact, efficient, and precision technologies reduce environmental impacts, and this corporate stance has broadened to provide confidence and hope to not only employees but also to communities around the world.

Science was the theme of this event, and Seiko, with the slogan, “A step ahead of conventional timekeeping,” was selected as the official timekeeper. Epson, a Seiko Group company and then named Suwa Seikosha, played a part in the Games. The company had developed a crystal chronometer based on quartz watch technology from the 59A project. In addition, the company developed, and for a time marketed, a printing timer. This quartz oscillator-type digital stop clock offered electronic timekeeping, a digital display, and a printing option.

These innovations paved the road to unprecedented speed and accuracy, and the company’s timekeeping business flourished. The words, “for the first time no one complained about the timekeeping,” spoke volumes.

This success was followed by the world’s-first compact, lightweight digital printer, the EP-101 (1968). The following year, the world’s first quartz watch, the Seiko Quartz Astron 35SQ, was launched.

The challenge to develop a quartz wristwatch continued. The goal was to reduce a quartz clock to the size of a wristwatch, saving space and power. To achieve this goal, the company had to overcome many hurdles. Specifically, it had to produce a crystal oscillator, electronic circuits, and motor in sizes that didn’t exist. Ultimately, Epson made them in-house, as procuring them from outside sources would bring a new set of problems.

In 1969, the company introduced the world’s first quartz wristwatch, the Seiko Quartz Astron. This ushered in a new era of timekeeping many other achievements and accolades would follow, including a prestigious IEEE Milestone Award (2004) and Heritage of Future Technology (2018 and 2019), acknowledging the company’s contributions to technological development for the world. Among the achievements was the first LCD digital quartz watch with a six-digit display, launched in 1978.

From the printing timer and the EP-101 to the commercialisation of the quartz watch, all products represent innovation. If something doesn’t exist, we make it ourselves. This spirit of creativity and challenge has never wavered and remains today.

Epson began developing one of its core businesses, inkjet printers, in 1978, using piezo technology for printer heads — the key technology in Epson’s inkjet printers. The method doesn’t use heat to eject ink, so the printheads are more durable and maintain superior performance for far longer. Advancements in piezo technology led to PrecisionCore printhead technology, which delivers stunning image quality at substantially higher speeds while consuming little power. This core technology enables a wide range of applications in home, office and industrial and commercial settings.

Our technology

Piezo method at the start of printing innovation.
The continuous evolution in technology and societal contribution

Major technical challenges had to be overcome to develop Micro Piezo technology. First, the piezoelectric elements are made of a ceramic. The conventional way to produce the elements was to bake the ceramic like a brick, slice it thinly, and then polish it to the desired thickness. However, ceramic becomes very brittle when baked and the piezoelectric elements would crack or break when reduced below a certain thickness.

To overcome this technical issue, the development team came up with the idea of creating piezoelectric elements by stacking many thin layers of about 20 micrometers like a ceramic capacitor and dicing them into appropriate shapes to make an actuator. Thus, a thin-form piezo was achieved by creating the multi-layered structure before baking and stacking the piezoelectric elements in strips. This method was a game-changer in piezoelectric technology.

This is how Epson, through a length process of trial and error, successfully developed the Micro Piezo printheads which paved the way to thinner piezoelectric elements and smaller printheads.

Micro Piezo printhead development started in 1990, and mass production was achieved by the end of 1992. In 1993, the Epson Stylus 800 monochrome inkjet printer became the first product equipped with as Micro Piezo printhead. Micro Piezo technology continued to evolve. The next generation heads were dubbed ML Chips (multi-layer ceramic with hyper integrated piezo segments). Their piezoelectric elements were less susceptible to damage, which made the heads easier to produce in quantity. The were followed by TFP (thin film piezo) printheads, which had the thinnest piezoelectric elements possible, and finally by Precision Core printheads, which held the key to higher speed and image quality. Micro Piezo printheads not only deliver superb performance, precision, speed, and image quality, but they also operate on low power, making them better for the environment. These features have enabled Micro Piezo printheads to quickly expand into the commercial, industrial, and office printing segments.

Epson’s Micro Piezo printheads have the potential to evolve even further and meet an even wider range of needs. Printheads that are denser and more compact will enable higher image quality at a lower cost. Those with more nozzles will be able to print at even faster speeds. Advances like these will allow Epson to provide more reliable commercial and industrial inkjet printers.

Epson will continue to ceaselessly innovate and evolve Micro Piezo technology into the future.

Microdisplay technology lies at the heart of Seiko Epson’s LCD projectors and other visual communications products. It combines Epson’s proprietary HTPS (high-temperature polysilicon TFT liquid crystal) panel technology with various optical and design technologies.

Before LCD projectors, projectors were large and heavy, not portable, and required room darkening due to their low brightness. However, Epson’s 3LCD projectors, the world’s first projectors to use three HTPS panels, are characterised by their brightness and ease on the eyes. Not only has it contributed to the culture of large-screen presentations, but it has also been used in educational settings and home theaters. Thus, we have maintained the top share in the 500+ lumen projector market during the 20 years from 2001 to 2021.

Epson’s microdisplay technology has its origins in the Seiko Quartz LC V.F.A. 06LC, the world’s first digital watch with a six-digit LCD display, introduced in 1973. The product was highly regarded for its display which offeres low power consumption and high visibility. Epson went on to launch a liquid crystal business for areas other than wristwatches. This eventually evolved into the current projector business.

However, not all was smooth sailing at first in the projector business.

As a leading printing company, we looked for solutions to paper waste after printing.

The fruit of our pursuit was the “PaperLab”. PaperLab is the world’s first¹ dry process office papermaking system that can produce new paper from used paper using virtually no water². We exhibited the system at Eco-Products 2015, the International Exhibition on Environment and Energy, creating a big hit with the public.

The PaperLab is equipped with “Dry Fiber Technology,” which turns paper into fibers by impact force without the use of water. It helps to build a small cycle of paper recycling, enabling recycling and use of paper in places like the office, for example. Our concept of this cycle is not “recycling. It’s “upcycling”, a way of adding new value. Currently, we are pursuing the application and evolution of “Dry Fiber Technology” to materials other than paper, together with a wide range of co-creation partners.

We will continue our efforts to deliver new value to the world toward achieving sustainability and enriching communities.

Our technology

Innovations that envision the future:
Dry Fiber Technology

Note¹: Among all dry process office papermaking systems. Source: Epson’s research conducted in November 2016
Note²: A small amount of water is used to maintain humidity inside the system.

A new challenge:
Recycling paper in a virtually water-free process

Once the challenge was identified, the technology development team focused on how to build a recycling method that uses virtually no water and yields high-quality paper.

However, it was a challenging goal to achieve. When they shred the paper too finely, the paper fibers were chopped, and high-quality paper could not be made. Trial and error continued. Even after more than 100 different experiments such as scraping paper with mortars and grinding them with mixers, no solution could be found.

The breakthrough came when Ichikawa tore off a piece of washi, traditional Japanese paper, with his fingers, and noticed that the fibers along the torn edges were loose and could be teased out. He thought that maybe it would be better to separate these fibers by loosening and untangling them instead of through a cutting, rubbing, or crushing process.

This idea led to the development of Epson’s Dry Fiber Technology, which features a combination of processes in which used paper is defibrated (thus securely destroying all the printed information on a page) and new paper is produced from those fibers. To verify whether this technology would really be accepted by the market, Epson demonstrated PaperLab, the world’s first² dry process office papermaking system that can produce new paper from used paper using virtually no water¹ at Eco-Products 2015, the International Exhibition on Environment and Energy. The PaperLab became a big hit with the public.

What can we do for the future?
Achieving sustainability and enriching communities

Epson is currently working with like-minded partners to develop “Dry Fiber Technology” upcycling applications for a variety of materials in addition to paper. We are also working on ways to use “Dry Fiber Technology” to produce new materials to replace petroleum-based materials such as plastics. Epson will continue to develop technologies, products, and solutions that are sustainable and that enrich communities.

Note¹: A small amount of water is used to maintain humidity inside the system.
Note²: Among all dry process office papermaking systems. Source: Epson’s research conducted in November 2016