High Speed Adept Quattro Robots Used in Chocolate Manufacturing
www.adept.com High Speed Adept Quattro Robots Used in chocolate manufacturing at a production facility in Japan. This video demonstrates the unmatched speed of the Adept Quattro robot and technical achievements in robot system performance. This is more than simply motor speeds; to manage the robot doing this much in so little time takes a high performance motion controller, software, and electronics. To the user this means increased product throughput, but not at the cost of control over the motions. Adept’s SmartController CX and V+ programming language allow the management of the specific motions: speeds, accelerations and accel profiles, end-of-motion tolerances and behavior, etc. When manufacturers look at automation in a cost-per-pick analysis, being able to pick products faster and more reliably means an improvement to the bottom line. The unique patented design of the Adept Quattro robot enables this level of performance with its four-arm parallel kinematic (known as PAR-4). This is differentiated from the three-arm delta style robots commonly seen in the industry. The four motors share the load and contribute to the motion, thus reducing the load on the individual joints and allowing greater speeds, higher payloads, and improved performance throughout the entire robots work envelope. www.adept.com
Video Rating: 4 / 5
Automation and Industrial Robots
Automation and Industrial Robots
The importance of automation and robots in all manufacturing industries is growing. Industrial robots have replaced human beings in a wide variety of industries. Robots out perform humans in jobs that require precision, speed, endurance and reliability. Robots safely perform dirty and dangerous jobs. Traditional manufacturing robotic applications include material handling (pick and place), assembling, painting, welding, packaging, palletizing, product inspection and testing. Industrial robots are used in a diverse range of industries including automotive, electronics, medical, food production, biotech, pharmaceutical and machinery. The ISO definition of a manipulating industrial robot is “an automatically controlled, reprogrammable, multipurpose manipulator”. According to the definition it can be fixed in place or mobile for use in industrial automation applications. These industrial robots are programmable in three or more axes. They are multi-functional pieces of equipment that can be custom-built and programmed to perform a variety of operations. The major advantages of industrial robots is that they can be programmed to suit industry specific requirements and can work continuously for years, consistently meeting high manufacturing quality standards. The economic life span of an industrial robot is approximately 12-16 years. Due to their persistent accuracy industrial robots have become an indispensable part of manufacturing. Industrial robots are classified into different categories based on their mechanical structure. The major categories of industrial robots are:
Gantry (Cartesian) Robot: They are stationary robots having three elements of motion. They work from an overhead grid with a rectangular work envelope. They are mainly used to perform ‘pick and place’ actions. Gantry robots have all their axes above the work making them also ideal for dispensing applications.
SCARA Robots: (Selectively Compliant Articulated Robot Arm) These robots have 4 axes of motion. They move within an x-y-z coordinated circular work envelope. They are used for factory automation requiring pick and place work, application and assembly operations and handling machine tools.
Articulated robots: An articulated robot has rotary joints. It can have from two to ten or more interactive joints. Articulated robots are well suited to welding, painting and assembly.
Basic industrial robot designs can be customized with the addition of different peripherals. End effectors, optical systems, and motion controllers are essential add-ons. End effectors are the end-of-arm-tooling (EOAT) attached to robotic arms. Grippers or wrenches that are used to move or assemble parts are examples of end effectors. End effectors are designed and used to sense and interact with the external environment. The end effectors’ design depends on the application requirements of the specific industry. Machine Vision systems are robotic optical systems. They are built-on digital input/output devices and computer networks used to control other manufacturing equipment such as robotic arms. Machine vision is used for the inspection of manufactured goods such as semiconductor chips. Motion controllers are used to move robots and position stages smoothly and accurately with sub-micron repeatability. Industrial robots fill the need for greater precision, reliability, flexibility and production output in the increasingly competitive and complex manufacturing industry environment.
More Manufacturing Robotics Articles
Automation and Industrial Robots
The importance of automation and robots in all manufacturing industries is growing. Industrial robots have replaced human beings in a wide variety of industries. Robots out perform humans in jobs that require precision, speed, endurance and reliability. Robots safely perform dirty and dangerous jobs. Traditional manufacturing robotic applications include material handling (pick and place), assembling, painting, welding, packaging, palletizing, product inspection and testing. Industrial robots are used in a diverse range of industries including automotive, electronics, medical, food production, biotech, pharmaceutical and machinery.
The ISO definition of a manipulating industrial robot is “an automatically controlled, reprogrammable, multipurpose manipulator”. According to the definition it can be fixed in place or mobile for use in industrial automation applications. These industrial robots are programmable in three or more axes. They are multi-functional pieces of equipment that can be custom-built and programmed to perform a variety of operations.
The major advantages of industrial robots is that they can be programmed to suit industry specific requirements and can work continuously for years, consistently meeting high manufacturing quality standards. The economic life span of an industrial robot is approximately 12-16 years. Due to their persistent accuracy industrial robots have become an indispensable part of manufacturing.
Industrial robots are classified into different categories based on their mechanical structure. The major categories of industrial robots are:
- Gantry (Cartesian) Robot: They are stationary robots having three elements of motion. They work from an overhead grid with a rectangular work envelope. They are mainly used to perform ‘pick and place’ actions. Gantry robots have all their axes above the work making them also ideal for dispensing applications.
- SCARA Robots: (Selectively Compliant Articulated Robot Arm) These robots have 4 axes of motion. They move within an x-y-z coordinated circular work envelope. They are used for factory automation requiring pick and place work, application and assembly operations and handling machine tools.
- Articulated robots: An articulated robot has rotary joints. It can have from two to ten or more interactive joints. Articulated robots are well suited to welding, painting and assembly.
Basic industrial robot designs can be customized with the addition of different peripherals. End effectors, optical systems, and motion controllers are essential add-ons. End effectors are the end-of-arm-tooling (EOAT) attached to robotic arms. Grippers or wrenches that are used to move or assemble parts are examples of end effectors. End effectors are designed and used to sense and interact with the external environment. The end effectors’ design depends on the application requirements of the specific industry. Machine Vision systems are robotic optical systems. They are built-on digital input/output devices and computer networks used to control other manufacturing equipment such as robotic arms. Machine vision is used for the inspection of manufactured goods such as semiconductor chips. Motion controllers are used to move robots and position stages smoothly and accurately with sub-micron repeatability.Industrial robots fill the need for greater precision, reliability, flexibility and production output in the increasingly competitive and complex manufacturing industry environment.
AESG, Automation Equipment Services Group Inc. – experts in automation and robotic equipment maintenance and customer support. To get more information on automation and robotics, visit our website!
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