LOLS10在线直播下注

Industrial lasers and systems in Japan

LOLS10在线直播下注This article presents the situation for industrial laser systems in a decreasing work-age population country.

FIGURE 1. The trend of Japanese quarterly GDP (Real, Seasonally adjusted) and annual GDP growth rates since calendar year 2007.
FIGURE 1. The trend of Japanese quarterly GDP (Real, Seasonally adjusted) and annual GDP growth rates since calendar year 2007.

KUNIHIKO WASHIO

LOLS10在线直播下注The population in Japan peaked in December 2004 at 127.84 million and the current population as of December 2019 is 126.15 million. The work population from 15 to 64 years of age is 75.18 million as of July 2019, a decrease of 0.52% from the previous year. The work-age population in Japan is forecast to decrease about 34.4% to 49.3 million by 2050.

LOLS10在线直播下注FIGURE 1 shows the trend of Japanese quarterly gross domestic product (GDP; real, seasonally adjusted) and a table of annual GDP growth rates since calendar-year 2007. In spite of the above-mentioned decrease in work-age population, the Japanese GDP is steadily increasing since 2012, though the average annual growth rate is about 1.2 %, which is much smaller than China’s recent years’ GDP that is in the range of about 6% to 6.8%. 

FIGURE 2 shows the annual shipment trend of laser processing equipment by laser types produced by Japanese manufacturers (including export and local production), plus imported foreign manufacturers’ laser-processing equipment sold in Japan. The data were collected from Japan Laser World & Trend’s 14th to 25th reports published yearly in September since 1995 by Simpo Corporation, which celebrated its 35th anniversary in 2019. As seen in FIGURE 2, the 4.5% compound annual growth rate (CAGR) for laser processing equipment using various lasers (including CO2 lasers, fiber lasers, and solid-state lasers), except for excimer lasers, is slightly higher than that of 3.2% for excimer laser equipment (for lithography and annealing).FIGURE 2. Trends of annual shipment of laser processing equipment by laser types by Japanese manufacturers (including export), including imported foreign manufacturers' equipment sold in Japan.FIGURE 2. Trends of annual shipment of laser processing equipment by laser types by Japanese manufacturers (including export), including imported foreign manufacturers' equipment sold in Japan.

As compared with the reports by the Optoelectronic Industry and Technology Development Association (OITDA), there are some differences in the amount of revenues partly because Simpo’s data includes oversea local production by Japanese manufacturers and sales of the imported foreign manufacturers’ equipment in Japan. Furthermore, the OITDA reports are in fiscal-year base and those by Simpo are in calendar-year base.

FIGURE 3 shows shipment of laser processing equipment in 2018 by applications by Japanese manufacturers (including export and local production), plus imported foreign manufacturers’ equipment sold in Japan. The share of 50.5% of the sheet metal cutting machines (considered to be mostly using fiber lasers or CO2 lasers) is dominantly large. The amount of shipments for sheet-metal cutting machines was 108 billion yen (about $983 million) for 2018, partly due to the fact that many devices such as displays for consumer electronics and solar-cells are now manufactured outside Japan and partly because current Japanese microprocessing equipment may not be competitive enough. The share of microprocessing machines is not so large as compared with the data reported by Industrial Laser Solutions for global revenues by laser applications.FIGURE 3. Shipment of laser processing equipment in 2018 by applications by Japanese manufacturers (including export), including imported foreign manufacturers’ equipment sold in Japan.FIGURE 3. Shipment of laser processing equipment in 2018 by applications by Japanese manufacturers (including export), including imported foreign manufacturers’ equipment sold in Japan.

FIGURE 4 shows the trend of annual shipments in units of sheet-metal cutting machines—note that most of the detailed data in the Simpo reports for various machine types are only given in units and detailed revenue data are not available. The number of 3085 units in 2018 was slightly higher than that of the peak in 2007. The average unit selling price for sheet-metal cutting machines is about 35 million yen (about $318,000) for 2018. Because of the recent trend to increasing adoption of higher-power multikilowatt lasers and innovative beam control technologies, the average unit selling price is expected to increase, at least for a few years. Although positive growth in the number of shipments is expected for 2019 and 2020, this may not occur because of the recent trade conflicts between the U.S. and China, etc.FIGURE 4. Trends of annual shipment in units of sheet metal cutting machines by Japanese manufacturers (including export), including imported foreign manufacturers’ equipment sold in Japan.FIGURE 4. Trends of annual shipment in units of sheet metal cutting machines by Japanese manufacturers (including export), including imported foreign manufacturers’ equipment sold in Japan.

According to a survey by Development Bank of Japan (DOB), the overseas capital investment ratio of Japanese manufacturing industries has rapidly increased from 29.6% for 2009 to 54.8% for 2013 after the Great Recession that occurred in late 2007, but the overseas capital investment ratio has decreased after 2013 and has remained below 52.7% since then. This means that the capital investment for local production has slowed down and the increase in domestic capital investment restarted after 2013. This agrees with the International Federation of Robotics (IFR) report that the annual growth rate of robot installation in Japan is as high as 17% since 2013. Furthermore, in 2018, the robot installation in Japan increased by 21% to 55,240 units (a new peak). These results almost agree with the trend of annual share of exports in shipment in units of the sheet metal cutting machines (FIGURE 5). The annual share of export of sheet metal cutting machines has rapidly increased from 51.1 % in 2007 to 64.0% in 2012, but it remains below 59.8% since 2013.FIGURE 5. Trends of annual share of export in shipment in units among the sheet metal cutting machines by Japanese manufacturers (including export), including imported foreign manufacturers’ equipment sold in Japan.FIGURE 5. Trends of annual share of export in shipment in units among the sheet metal cutting machines by Japanese manufacturers (including export), including imported foreign manufacturers’ equipment sold in Japan.

FIGURE 6 shows the trend of the numbers of job shops listed in the annual issues of Simpo’s Japan Laser World & Trend report. The number of job shops had a peak in the 2009 with 655 job shops and decreased to a low of 546 job shops in 2015, but the numbers are fortunately above this since 2016.FIGURE 6. Trend of the numbers of job shops listed in the annual issues of Simpo’s reports on “Japan Laser World & Trends.”FIGURE 6. Trend of the numbers of job shops listed in the annual issues of Simpo’s reports on “Japan Laser World & Trends.”

Current status of advanced laser materials processing

In 2018, Keidanren (Japan Business Federation) announced the vision and concept of Society 5.0 and proposed Japan’s action plans. Society 5.0 is an emerging form of society characterized as creative imagination society enabled by digital transformation and imagination & creativity of diverse people. The actions to realize Society 5.0 include aiming to resolve social issues in harmony with nature and to share a common direction with the blueprint of United Nations sustainable development goals (SDGs).

One of the noteworthy trends in the manufacturing industry seems to be the shift towards smart manufacturing, which is accompanied by digital transformation—for example, by effectively utilizing the Internet of Things (IoT), artificial intelligence (AI), robotics, etc. Another remarkable trend seems to be the promotion of full-scale joint studies and smart cooperation between industry, academia, and government.FIGURE 7. Amada introduced the VENTIS 3015AJ (4 kW) fiber laser cutting Machine, which is equipped with the newly developed Laser Beam Control (LBC) Technology, at the Photonix 2019 event held in Makuhari, Japan.FIGURE 7. Amada introduced the VENTIS 3015AJ (4 kW) fiber laser cutting Machine, which is equipped with the newly developed Laser Beam Control (LBC) Technology, at the Photonix 2019 event held in Makuhari, Japan.

For example, in 2019, Amada introduced the VENTIS-3015AJ 4 kW fiber laser cutting machine, which is equipped with the newly developed Laser Beam Control (LBC) technology (FIGURE 7). The LBC technology is said to enable higher-speed, higher-quality sheet metal cutting than conventional fiber laser cutting machines. Furukawa Electric Group introduced a fiber laser-arc hybrid welding system and optical coherence tomography (OCT)-based distance measurement system in 2019, with the cooperation of several leading high-tech companies (FIGURE 8). The hybrid welding system was developed by joint operation with Daihen, a company famous for arc welding and robotics. The newly developed hybrid welding system enables high-quality dissimilar material welding of zinc-coated steel and aluminum alloy by effectively utilizing Furukawa’s beam mode control technology.FIGURE 8. Furukawa Electric Group introduced a fiber laser arc hybrid welding system and OCT-based distance measurement system at the Photonix 2019 event in Makuhari, Japan.FIGURE 8. Furukawa Electric Group introduced a fiber laser arc hybrid welding system and OCT-based distance measurement system at the Photonix 2019 event in Makuhari, Japan.

Future

LOLS10在线直播下注In 2016, the New Energy and Industrial Technology Development Organization (NEDO) started “High-Brightness and High-Efficiency Laser Technology for Next-Next Generation Laser Processing” as a five-year project. Because fiscal-year 2020 is the final year of the project, many innovative laser processing machines incorporated with high brightness and high-power blue diode lasers or picosecond deep-UV pulsed lasers are expected to become commercially available in the market.

Furthermore, under the SIP (Cross-ministerial Strategic Innovation Promotion) Program of “Photonic and Quantum Technology for Society 5.0,” a new five-year project on “Laser Processing” started in 2019. Its R&D themes are as follows:

1. Proof of smart manufacturing based on advanced integration of cyber (simulators) and physical (laser material processing systems): Development of CPS-type laser materials processing systems for specific uses;

2. Smart processing based on Japan’s core spatial light modulator technology: Development of high-power resistant and highly accurate space control technologies; and

3. High-power operation of Japan original photonic crystal lasers.

Therefore, the future looks much brighter in Japan, at least in the laser material processing sector.

Dr. KUNIHIKO WASHIO (k-washio@paradigm-laser-research.jp) has his own consulting firm (Paradigm Laser Research Ltd.) and is also an Editorial Advisor on Japanese markets to Industrial Laser Solutions.

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