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Company type | Public KK |
---|---|
TYO: 6954 TOPIX Core 30 Component TOPIX 100 Component Nikkei 225 Component | |
Industry | |
Founded | 1958[1] (as a subsidiary of Fujitsu) 1972 (as an independent company) |
Founder | Seiuemon Inaba[1] |
Headquarters | Oshino-mura, Minamitsuru-gun, Yamanashi Prefecture, Japan 35°26′43.8″N 138°50′34.1″E / 35.445500°N 138.842806°E |
Area served | Worldwide |
Key people | Dr. Eng. Seiuemon Inaba (Honorary Chairman) Dr. Eng. Yoshiharu Inaba (President & CEO) |
Products | |
Revenue | ¥536.94 billion (2017)[2] |
¥153.22 billion (2017)[2] | |
¥127.70 billion (2017)[2] | |
Total assets | ¥1564.77 billion (2017)[2] |
Total equity | ¥1381.80 billion (2017)[2] |
Number of employees | 8,256[3] |
Website | Official website |
Footnotes / references [1][4][5] |
FANUC (/ˈfænək/ or /ˈfænʊk/; often styled Fanuc) is a Japanese group of companies that provide automation products and services such as robotics and computer numerical control wireless systems.[6] These companies are principally FANUC Corporation (ファナック株式会社, Fanakku Kabushikigaisha) of Japan, Fanuc America Corporation of Rochester Hills, Michigan, USA, and FANUC Europe Corporation S.A. of Luxembourg.
FANUC is one of the largest makers of industrial robots in the world. FANUC had its beginnings as part of Fujitsu developing early numerical control (NC) and servo systems. FANUC is acronym for Fuji Automatic Numerical Control.[7]
FANUC is organized into 3 business units: FA (Factory Automation), ROBOT, and ROBOMACHINE. These three units are unified with SERVICE as "one FANUC". Service is an integral part of FANUC and the company famously supports products for as long as customers use them.[8]
In 1955, Fujitsu Ltd. approached Seiuemon Inaba (ja:稲葉清右衛門), who was then a young engineer, to lead a new subsidiary purposed to make the field of numerical control. This nascent form of automation involved sending instructions encoded into punched cards or magnetic tape to motors that controlled the movement of tools, effectively creating programmable versions of the lathes, presses, and milling machines. Within three years after spending heavily in R&D, he and his team of 500 employees shipped Fujitsu's first numerical-control machine to Makino Milling Machine Co.[9] In 1972, the Computing Control Division became independent and FANUC Ltd. was established.[10] The next phase of expansion would be computer numerical control, which relied on G-code, a standard programming language. At the time, the 10 largest CNC companies in the world were based in the U.S., however by 1982, FANUC had captured half of the world CNC market.[11]
FANUC is listed on the first section of Tokyo Stock Exchange and is a constituent of the TOPIX 100[12] and Nikkei 225[13] stock market indices. It is headquartered in Yamanashi Prefecture.
In 1982, FANUC entered into a joint venture with General Motors Corporation (GM), called GMFanuc Robotics Corporation, to produce and market robots in the United States. The new company was 50 percent owned by each partner and was based in Detroit, with GM providing most of the management and FANUC the products.
In 1986, GE Fanuc Automation Corporation was jointly established in the US by FANUC and General Electric (GE). Under the joint venture company, three operating companies, GE Fanuc Automation North America, Inc., in the U.S., GE Fanuc Automation Europe S.A. in Luxembourg, and Fanuc GE Automation Asia Ltd. in Japan were established (the Asian company was established in 1987). GE stopped making its own CNC equipment and turned its Charlottesville, Virginia, plant over to the new company which produces FANUC CNC devices. FANUC adopted the German engineering slogan Weniger Teile, which means "fewer parts;" machines with fewer parts are cheaper to produce and easier for automatons to assemble, resulting in higher reliability and lower manufacturing costs.
The company's clients include numerous U.S. and Japanese automobile and electronics manufacturers. Use of industrial robots has allowed companies like Panasonic in Amagasaki to run factories which produce 2 million television sets a month (mostly high-end plasma LCD screens) with just 25 people.[14]
FANUC has over 240 joint ventures subsidiaries, and offices in over 46 countries.[15] It is the largest maker of CNC controls by market share with 65% of the global market.[16] and is the leading global manufacturer of factory automation systems.[17]
FANUC is organized into three business units: FA, ROBOT, ROBOMACHINE.
The FA group produces automation equipment and systems that can be implemented into custom industrial automation solutions. Products include servomotors, HMIs, and controls. FA is a foundational FANUC technology with roots back to the 1970's when FANUC was marrying its servomotor product with computers to create the field of computer numerical control technology. Today, FA products continue to be used to create automated systems in over 100 countries around the world. It is common for the FA group to deliver controls and servomotors to machine tool builders who integrate them into a conventional CNC machine. A significant proportion of the world's CNC machines are powered by FANUC controls.
The robot group integrates FANUC servomotor and control technology into robotic arms for use in industrial environments.
FANUC also produces a range of finished machines included ROBODRILL machining centers, ROBOSHOT injection molding machines, and ROBOCUT EDM machines.
FANUC Europe Corporation S.A., a sister company, is headquartered in Luxembourg, with customers in Europe, and which provides sales, service and support in Europe and abroad.
FANUC America Corporation is responsible for FANUC operations in North and South America. The current incarnation, organized in 2013, unifies FANUC activities in the Americas, including the former FANUC Robotics America Corporation (1992-2013) and FANUC CNC America (2010-2013), which succeeded an earlier incarnation of FANUC America Corporation.
FANUC Robotics America Corporation (1992-2013) supplied robotic automation in North and South America, with over 240,000 robots installed. It also produced software, controls, and vision products that aid in the development of robotic systems. Headquartered in Rochester Hills, Michigan, the company had 10 regional locations in the U.S., Canada, Mexico, and Brazil. The company provided these systems for applications including automotive and fabricated metals to medical devices and plastics. It was founded in 1982 as a joint venture between FANUC Ltd and General Motors Corporation, named GMFanuc Robotics Corporation. A staff of 70 began work at the GM Technical Center in Warren, Michigan. In 1992, the company became a wholly owned subsidiary of FANUC Ltd of Oshino-mura, Japan. The company was a member of the Robotics Industries Association (RIA) and of the International Federation of Robotics (IFR).
In 2010, FANUC America Corporation and the prior CNC business unit from GE Fanuc Intelligent Platforms in the US were combined into a new company by the name of FANUC CNC America. This business unit was a wholly owned subsidiary of FANUC Ltd. of Japan and offered CNC systems, lasers, Manufacturing Intelligence software products, field repairs and advanced technical services, expanded training classes, a vast inventory of CNC replacement parts, PCB motor repair and return, field support, and CS-24 after hours support. It was headquartered in the Chicago suburb of Hoffman Estates, Illinois. It offered CNC and laser technical services, training, replacement parts, PCB and motor repair and return, field support, and after hours support. It had over 30 locations in the U.S., Canada, Mexico, Brazil, and Argentina. The company provides these services to machine tool builders, machine tool dealers, and small mom and pop tool shops across a variety of industries. In 1977, the company was established as a wholly owned subsidiary of FANUC Ltd of Oshino-mura, Japan.
GE Fanuc Intelligent Platforms (1986-2010) was a joint venture between General Electric and FANUC Ltd. In 2009, GE and FANUC Ltd. agreed to split, with FANUC Ltd. retaining the CNC business. GE renamed its part of the business GE Intelligent Platforms.[18][19][20]
FANUC India operations are now led by Yuki Kita, who succeeded Sonali Kulkarni.
Each generation of the FANUC numerical control system has different levels of device control capabilities, and these are generally referred to by a model or series number.
Each controller model is typically available with several device control capabilities, depending on what software functions are licensed for use on that device. Some common control capabilities are:
Within each model name, there can also be generational updates for each model, usually indicated by a trailing letter.
Model 0 is somewhat unusual in that both the number zero and the letter O are used interchangeably to indicate the model.
There is no specific syntax for distinguishing the model from the device type and series, with spaces or dashes or slashes, which can result in difficulty searching for information, parts, and service for this equipment. For example, in the FANUC-0 series, these are all valid identifications for various types of NC controls and machines:[21]
Various model names | Type | Series | Notes |
---|---|---|---|
FANUC-0MA, FANUC 0-MA, FANUC 0M-A, FANUC 0M/A, FANUC 0-M-A, FANUC 0-M/A, FANUC 0 M-A, FANUC 0 M/A, FANUC-0M Model A, FANUC 0-M Model A, FANUC 0/M Model A | Milling | A | number 0 |
FANUC-OPA, FANUC O-PA, FANUC OP-A, FANUC OP/A, FANUC O-P-A, FANUC O-P/A, FANUC O P-A, FANUC O P/A, FANUC-OP Model A, FANUC O-P Model A, FANUC O/P Model A | Punching | A | letter O |
FANUC-0TB, FANUC 0-TB, FANUC 0T-B, FANUC 0T/B, FANUC 0-T-B, FANUC 0-T/B, FANUC 0 T-B, FANUC 0 T/B, FANUC-0T Model B, FANUC 0-T Model B, FANUC 0/T Model B | Turning | B | number 0 |
FANUC-0TTB, FANUC 0-TTB, FANUC 0TT-B, FANUC 0TT/B, FANUC 0-TT-B, FANUC 0-TT/B, FANUC 0 TT-B, FANUC 0 TT/B, FANUC-0TT Model B, FANUC 0-TT Model B, FANUC 0/TT Model B | Twin Turret | B | number 0 |
FANUC-0GC, FANUC 0-GC, FANUC 0G-C, FANUC 0G/C, FANUC 0-G-C, FANUC 0-G/C, FANUC 0 G-C, FANUC 0 G/C, FANUC-0G Model C, FANUC 0-G Model C, FANUC 0/G Model C | Grinding | C | number 0 |
When separate computer aided manufacturing software is used to control these different systems, the model differences can be used to tell the manufacturing software how to more efficiently use the system programming capabilities. Some FANUC NC controllers include:
Control name | Series or version | Differences and capabilities |
---|---|---|
FANUC 20 | Series A | Series 20A was a two axis (usually lathe) NC controller that used stepper motors. Resolution was 10μm. Optional tool offsets were via "decade" switches and selected by program. A machine reference point was optional. |
FANUC 20 | Series B | Series 20C had a 1μm resolution |
FANUC 30 | Series A | Series 30A was a three axis (milling) NC controller that used stepper motors. Resolution was 10μm. |
FANUC 30 | Series B | Series 30C had a 1μm resolution |
FANUC 2000 | Series A | Series 2000C was a 2 axis (usually lathe) CNC controller that used DC thyristor drives and had a 1 μm resolution. User memory was optional. Data was displayed by a one-word LCD, addresses (letters such as G, F, X, Y, &etc.) were selected by buttons on the control panel. A two-line position display was optional. |
FANUC 3000 | Series A | Series 3000C was a 3 axis (usually milling) CNC controller that used DC thyristor drives and had a 1 μm resolution. User memory was optional. Data was displayed by a one-word LCD, addresses (letters such as G, F, X, Y, &etc.) were selected by buttons on the control panel. A three-line position display was optional. |
There is no model 4/4000, likely because it is a Japanese unlucky number. But in recent days[when?] these models are also available because of the application requirement. | ||
FANUC 5 | Series A | System 5 was similar to 2000/3000, it was an 8 bit CNC that used a standard paper tape drive and optional user memory with battery back up. 5T had options of constant surface speed, Multiple repetitive cycles G71, G72, G73, G74, G75, and G76. Tool nose radius compensation was available. Incremental and absolute programming were possible in the same block. The display was a one-word LCD the same as the 2000/3000. |
FANUC 7 | Series A | FANUC System 7 was a joint venture between FANUC and Siemens because FANUC were then unable to produce a 5 axis controller. |
FANUC 6 | Series A | System 6A was the first FANUC controller based on the Intel 8086 16 bit micro processor. System 6A had the standard one-word LCD, but was optionally available with a 9" CRT. It was available with Custom Macro (variable programming with user defined calculations) and could hold multiple programs in its memory. Non-volatile Bubble memory was used. |
FANUC 5 | Series B | |
FANUC 6 | Series B | System 6B had a standard CRT, up to 512 kb of memory and most of the programming features found in modern CNC machines. Whereas the earlier systems were obsolete within a few years of manufacture, system 6 machines are still in operation today (2018), 35 years later. Early system 6 machines used the "Black Cap" thyristor drives from earlier controls, later machines from 1981 onwards used the legendary "Yellow Cap" transistor drives. AC spindle drive were optional with system 6 and these were reliable, unlike the earlier DC units. 8 bit paper readers or RS232C ports were used to input programs. 8 kb of bubble memory was standard, 128 kb was a $10,000 + option. System 6 level two came out in 1983 and is distinguished by 3 extra buttons on the control panel. Level 2 had many bug fixes and a few extra features, notably, 5 axis milling. later 6MB systems had an optional 14" CRT with expanded operator panel and optional FAPT programming. System 6 had a built in PLC. |
FANUC 3 | Systems 3 and 2 were low-cost alternatives to system 6, although a fully optioned system was quite powerful, if somewhat slow in processing. System 3 used battery-backed CMOS memory with 4 kb being standard. System 3TF had a 12" 4 colour CRT and FAPT automatic programming. 3M and 2T controllers were typically used on simple machines like CNC drills and gang-tooled lathes. | |
FANUC 10 | ||
FANUC 11 | ||
FANUC 15 | ||
FANUC 0 | Series A, 1985–1986 | |
FANUC 0 | Series B, 1987–1989 | |
FANUC 0 | Series C, 1990–1998 | |
FANUC 6 | ||
FANUC 12 | ||
FANUC 16i | ||
FANUC 18i | ||
FANUC 21i | ||
FANUC 30i[22] | First production: 2003 | |
FANUC 31i[22] | First production: 2004 | |
FANUC 32i[22] | First production: 2004 | |
FANUC 160[23] | ||
FANUC 180[23] |
FANUC produces the largest range of industrial robots in the world, with payloads ranging from 1 to 2,300 kg capacity. Most models are of the 6-axis articulated arm style common in industrial environments but specialty models are also produced with varying axis configurations and application focuses. Some specialty models have fewer or more axes or special characteristics that help them perform in certain environments (such as in clean rooms or in wet/dirty wash down areas).
A typical FANUC robot system comprises a robot arm (also called the mechanical unit), a controller, and a teach pendant. This equipment comes standard with any FANUC robot and can be customized during the ordering process to suit each application.
The robot arm is what most people think of when they think of a robot: this is the servomotor-articulated machine that performs the work. Robot arms are sold without any attachments, or end effectors, to perform work. Integrators or end users design or purchase custom end effectors suitable for their application and attach these to the robot's faceplate. Through-arm cable sets allow the robot to pass signals or pressurized air from the base of the robot out to the end effector. Signals carry useful information from end effector sensors back to the robot to, for example, confirm when a part is being held by the robot or is missing. Signals can mean basic IO signals (on/off) or more advanced communication such as ethernet. The pressurized air is used to actuate grippers or power vacuum cups (through venturi generators) to grip and move parts.
The controller contains computers that control the arm, power supply and regulation equipment, and sometimes auxiliary hardware specific to an application such as IO or networking equipment. Due to the variety of automation applications being deployed, controllers must contain hardware that enables the robots to be used in many different applications and with other technologies. To that end, all FANUC controllers contain the computers and connections required to use 2D/3D cameras, they can function as PLCs, and even operate as a web server to allow technicians to remotely access the robot from a browser.
The teach pendant is the robot programmer's primary interface with the robot when teaching and maintaining. During normal operation, the teach pendant is usually stowed out of the way so the robot can automatically run through programmed motion. The teach pendant contains a touch screen display and keypad to view and edit program data, as well as a deadman switch that the operator must hold in order to enable the robot to move. This allows the programmer to safely operate the robot while being in close proximity to the arm. During normal operation humans are kept away from the robots for safety reasons.
Handling robots are widely used in industry to handle goods, perform assembly tasks, and inspect parts. This class is essentially the standard robot offered and is suitable for most general industry applications. Many robots are produced within this class and are grouped into distinct payload groups and arm families.
Robot series included in this designation include the LR Mates, M-10, M-20, M-900, M-1000, and M-2000 series.
FANUC produces a range of industrial robots with the required safety sensors and software to enable power and force limited collaborative operation. This allows the robots to safely work alongside humans in a collaborative fashion without endangering workers.
FANUC's collaborative robot series include the CR-Series and the newer CRX-Series.[24]
Palletizing applications are unique in that they have no need for 6 axis of articulation common to other industrial robots. Since boxes are picked, placed, and only rotated along the floor plane, a full 6 axes of articulation in the arm is unnecessary. To simplify robot arm design and improve rigidity, palletizing robots[25] are produced with 4 axis of articulation. These robots use a "parallel link" design that keeps the wrist at a fixed orientation that is parallel with the floor. This lets the operator program the robot to pick and place boxes without worrying about keeping the box level with the pallet.
These robots are sometimes referred to as "spider robots" due to the shape and movements of their arms. These are low-payload high-speed robots commonly used to pick or place objects off fast conveyor belts. It's common to see several of these robots arranged along a conveyor belt, all picking or placing objects at high speed.
Delta robots use 3 arms, each controlled by a single axis servo motor. The 3 arms connect underneath the robot and support the faceplate, similar to an inverted camera tripod. By adjusting the position of each arm, the faceplate is moved around underneath the robot. Because of the lower mass and fewer moving parts, delta style robots tend to be very fast with the downside being reduced payload and reach.
These robots[26] are suitable for use in paint booths. Automotive painting was the most common market but it is becoming increasingly common to see paint robots in other industries due to the hazardous nature of having humans paint. Paint robots have characteristics that make them explosion-proof and suitable for use in hazardous environments. An atomizer at the faceplate distributes paint particles towards the painted part.
This is a unique series of robots designed to be mounted to a rail that runs over CNC machines for rapid servicing. Mounting one robot on an overhead rail allows the robot to slide from machine to machine, servicing them as required.
The ARC designation means that these robots are intended for welding applications. They normally have hollow faceplates for easy mounting of welding tips and space on the arm for mounting of welding equipment. ARC robots are generally adapted from other Handling Robots, with minor modifications made so they resist weld splatter better.
SCARA robots are a unique style of 3 link robots suitable for high speed applications with minimal part rotation and work envelopes. Because of the lower number of joints to control, these robots tend to be more rigid and faster than their 6-axis counterparts. FANUC SCARA robots have special controllers that are more compact and energy efficient than the normal robots.
FANUC produces several controllers, each geared towards a certain size of robot. Generally, smaller robots make use of smaller controllers and larger robots requirer larger controllers.
This is the most common controller[27] and is used on most handling, palletizing, and welding robots.
This smaller controller is used on the LR Mate series of handling robots.
This is the smaller controller FANUC produces and is used with SCARA robots. It has many of the same capabilities as the larger controllers but with smaller power amplifiers for the SCARA robots.
Used exclusively for the CRX-Series robots, this controller is smaller than a Mate and is specially optimized for use with CRX robots. It is the latest generation controller from FANUC, being released in 2019.
iRVision, sometimes stylized "iRVision" is FANUC's robot vision product. This group of products encompasses 2D and 3D imaging sensors (cameras) and software that allows programmers to incorporate vision into robot tasks. Vision is commonly used to allow robots to locate parts on a surface and pick them. This allows parts to be fed into a work cell flexible (such as on a conveyor or a pallet) and removes the need for precise fixturing. Inspection is another common use for vision, allowing the robot to inspect a part for defects, confirm assembled parts are present, or perform other quality control tasks. Cameras can be fixed in a work cell or mounted to the robot itself.
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