Lab robot arm

Fully-programmable humanoid robot. The result of a unique combination of mechanical engineering and software, NAO is a character made up of a multitude of sensors, motors and software piloted by a made-to-measure operating system: NAOqi OS.

Robotics is the fastest growing and most advanced technology used in education and research. With the virtual reality pack powered by RobotLAB, teachers can take students on over virtual reality field trips without leaving the classroom. This bundle is custom-built for Google Expeditions and includes everything you need to turn your classroom into a whole new world.

Helping your students explore new places and ideas has never been easier or more affordable. A high precision 4-axis robotic arm capable of grabbing, writing, drawing and 3D printing. The visual programming interface makes it easy to program it using drag and drop command functions.

It's a highly cost effective solution empowering 21st century skills and unleashing students' creativity. QTrobot is a humanoid robot, built and designed to assist in teaching new skills to children with autism spectrum disorder and help them benefit more from educational sessions. QTrobot is designed to be an engaging and easy to understand tool for children with autism. QTrobot shows facial expressions, gestures and body language and also talk with children.

Furhat is a social robot that communicates with us humans as we do with each other - by speaking, listening, showing emotions and maintaining eye contact. The Cruzr is one of the most advanced fully-programmable robot that provides a new generation of developers with service applications for a variety of industries and research fields.

RobotLAB Kits are the best solution for classrooms. A combination of our products with the right tolls and right lessons are the best option to boost your students 21st-century skills. Discover our complete turnkey solutions that enable educators and students to make the most productive and efficient use of the robots in the classroom. From equipment to software and curriculum, everything you need to make your program successful is included in a practical mobile charging cart.

The CoDrone is a tiny quadcopter drone you can easily program to do whatever you want: follow you, engage in laser battles, go through a maze and more. Bringing the rich learning environment of a classroom to a homebound or hospitalized student can be very difficult. The Double Robot enables the remote student to join the classroom in real-time, interact with other students one-on-one, and participate in group discussion.

Bring AI to life with Misty, the autonomous roaming robot your students can program to move around and interact with humans. Misty open-source platform and open hardware is designed to delight robotics enthusiasts and institutions while providing access to a high-tech tool.

Develop Problem-Solving skills and Computational Thinking. Spark the next generation of innovators by introducing procedural thinking, cause and effect, decomposition of complex tasks, pattern recognition and the ability to notice similarities or common differences, abstraction and algorithm design and the ability to develop a step-by-step strategy for solving a problem, all using Cubelets robots.Our passionate team will guide you from point A to Z and beyond.

Choose your area of interest below, and discover groundbreaking products to kick your institute into the 21st century. RobotLAB is committed to bringing this technology to the students and enhance their experience with tools that truly bring learning to life. Discover more by searching for lesson-plans for any subject, any age group and any robot. RobotLAB trough hands-on experience and the right tools, is anticipating and preparing High ed students to master the future skills requirements.

Robots are the best social companions for children with especial needs, tools such as visual learning and social skills aim to control the environment and reduced the anxiety that cause children with special needs the interaction with others.

RobotLAB offer a variety of robots that can improve the sensory stimuli from the students becoming social mediators or facilitators, improving the learning skills that students need. Category 1. Higher Ed. Special Ed. Explore ALL Solutions. International Store. About Us. Contact Us.

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Virus Fighting.Our research focuses on creating algorithms that allow robots to interact with the world. These general-purpose motion planning, machine learning, and manipulation algorithms can be applied to robots that work in homes, factories, and operating rooms. We are interested in all aspects of algorithm development; including creating efficient algorithms, proving their theoretical properties, validating them on real-world robots and problems, integrating them with sensing and higher-level reasoning, and distributing them to open-source communities.

Our lab draws on ideas in search, optimization, machine learning, control theory, and topology to develop these planning algorithms and to prove their properties. We also seek to develop algorithms which can generalize to many types of practical tasks and application areas. The goal of bridging learning and planning is to create algorithms whose performance improves with experience while maintaining generality.

Learning algorithms are good at quickly producing solutions to problems that have been encountered before, but they have difficulty generalizing to new situations. Planning algorithms are good at generalizing to new situations but at significant and sometimes prohibitive computational cost. Our work seeks to combine the best of both approaches to create a method whose performance improves as it gains more experience while retaining the ability to generalize to new situations.

As a first step in this direction, we recently developed a path planning framework that is able to use previous experience by storing and quickly retrieving previously-computed paths and adapting them to the task at hand while also running a planning algorithm in parallel.

This framework allows a robot to train itself as it performs tasks without sacrificing generality. This research opens up new directions for autonomous manipulation in many different application areas, including mobile manipulation in the home and surgical robotics, where similar tasks such as opening a refrigerator or tying a suture are performed repeatedly.

Our work in deformable object manipulation has explored planning and control methods for elastic objects as well as objects like cloth and rope.

These objects have infinite-dimensional configuration spaces and are difficult to model and simulate. The key to our approach is to find appropriate model reductions that make planning and control tractable despite these challenges. Because of their human-like morphology and capabilities, humanoid robots offer the promise of taking the place of people operating in shipboard environments and disaster sites. For instance, a shipboard maintenance robot requires the ability to autonomously traverse environments with complex geometry and respond to significant disturbances; i.

The robot must also be able to operate despite significant disturbance forces arising from e. We are developing new locomotion planning algorithms that use previous experience and integrate with perception to quickly compute effective plans for these scenarios. This project addresses a large space of tasks that cannot be fully automated because of either the limitations of current algorithms or prohibitive cost and set-up time.

This project explores accomplishing these tasks through human-robot collaboration. This project explores the integration of reasoning about how a person moves and how he or she makes decisions into a robot motion planning and decision-making framework. The research centers on the development of new algorithmic frameworks for modeling, simulating, and planning for human-robot collaboration, which requires advances in robot training, task modeling, human motion understanding, high-dimensional motion planning with uncertainty, and metrics to assess human-robot joint action.

Most robotic systems today are rigid, or composed of parts that are hard and unable to flex, morph, or change other physical characteristics. This can be an issue when a rigid robotic hand is trying to grasp something irregularly shaped. These rigid designs need precise control over position, force, and other senses to successfully pick up objects.

“Sensorized” skin helps soft robots find their bearings

The idea behind a soft robotic hand is to use soft and flexible fingers that can adapt to the objects being picked up. Although some certainty is still required, less attention needs to be given to the placement of the object in 3D space.

A soft robotic hand can simply morph to the object's shape, and then get a firm grip on it. The purpose of this project is to research the development, effectiveness, and practicality of a soft robotic hand that can be used on robots that manipulate complex objects. The initial goal established was to construct a hand prototype that could be pneumatically controlled to pick up objects of different sizes, shapes, and weights. This is an ongoing project, however, as there are many areas for expansion.

These include sensor integration, stronger fingers, and a more sophisticated control system. Now that a proof of concept has been completed, the doors have been opened for a vast range of ways to improve the quality of the hand.

Source code available on GitHub. CAD for the molds and hand. Documentation for the hand. Our approach consists of three elements: 1 a user-guided perception interface which assists the user to provide task level commands to the robot, 2 planning algorithms that autonomously generate robot motion while obeying relevant constraints, and 3 a trajectory execution and monitoring system.

See a description of the challenge here.Automate demanding research projects in laboratories that demand flexibility, efficient use of space, and seamless integration of lab peripherals. Automate your scientific workflow easily with the Thermo Scientific Spinnaker robot. This 4-axis SCARA-type robot is well suited for a wide variety of research areas including synthetic biology, drug discovery, and biotechnology.

With integrated vision, the Spinnaker microplate mover provides self-correcting precision as well as powerful sample tracking and inventory management. Combine the superior performance of industrial robotics with the application-driven benefits of a traditional Thermo Scientific laboratory robot.

The robot's advanced servo technology enables smooth motion without vibration even at full speed, optimizing efficiency and throughput. At-a-glance instrument status and health is provided by Thermo Scientific SmartShelf.

An ideal platform for drug discovery, synthetic biology, human and animal health, and other related workflows.

Perfect for labs requiring an easy-to-use, versatile, and compact solution. Momentum keeps revolutionizing your laboratory's workflow. Its unique design is highly adaptive to complex real-time conditions.

The easy-to-use visual environment allows for advanced decision-making, as well as for monitoring multiple workflows and integrating offline processes. Learn more.

lab robot arm

Note: You clicked on an external link, which has been disabled in order to keep your shopping session open. Search Thermo Fisher Scientific. Search All. Lab Robotics. See Navigation. Fast, flexible, and innovative.

Featured lab robots. Spinnaker Microplate Robot. Orbitor RS2 Microplate Mover. F5 Robot System. Momentum Laboratory Automation Workflow Software. Lab robotics videos. Spinnaker robot with integrated vision.

Build your lab's automation configuration. Specifications Sheet: Spinnaker Robot. Thermo Fisher Scientific Inc.The Robot System is a complete and affordable training program for the programming and operation of industrial robots. Through the curriculum and hands-on experience with the Robot System, students learn to create automated work cells.

The precision-built, articulated arm of the Robot represents an important step in automation and handling.

lab robot arm

A stepper motor, located in the base of the unit, provides horizontal rotation while five additional stepper motors, located in the shoulder, provide precision movements of the articulations and end effector. The Robot has five axes of rotation plus a gripper and is able to use all joints simultaneously to perform a programmed move sequence. Each articulation can be controlled and moved independently.

Combat Arms - Nemexis Labs Gameplay as ROBOT BOSS

Movements of the joints are accomplished by belts through a series of gears, while the gripper mechanism is activated by cables and belt-driven pulleys. Texts that will be displayed have been partly translated by an automatic translation system.

To view any text in its original language Englishleave the mouse pointer on this text or touch the text if you use a tablet. Product: Robot Systems. Prefered way of communication: Email Phone. Send me news about this product line.

Request Information. Share this page. RoboCIM Software. Location pin on a Gravity Feeder. Robot Calibration Tools. Robot Systems. Educational automated production cell by Lab-volt. Related solutions. Variable-Frequency Drive Training System. Robot Software Development Kit.Fully-programmable humanoid robot.

lab robot arm

The result of a unique combination of mechanical engineering and software, NAO is a character made up of a multitude of sensors, motors and software piloted by a made-to-measure operating system: NAOqi OS. Robotics is the fastest growing and most advanced technology used in education and research. With the virtual reality pack powered by RobotLAB, teachers can take students on over virtual reality field trips without leaving the classroom. This bundle is custom-built for Google Expeditions and includes everything you need to turn your classroom into a whole new world.

Helping your students explore new places and ideas has never been easier or more affordable. A high precision 4-axis robotic arm capable of grabbing, writing, drawing and 3D printing. The visual programming interface makes it easy to program it using drag and drop command functions. It's a highly cost effective solution empowering 21st century skills and unleashing students' creativity.

QTrobot is a humanoid robot, built and designed to assist in teaching new skills to children with autism spectrum disorder and help them benefit more from educational sessions. QTrobot is designed to be an engaging and easy to understand tool for children with autism. QTrobot shows facial expressions, gestures and body language and also talk with children.

Furhat is a social robot that communicates with us humans as we do with each other - by speaking, listening, showing emotions and maintaining eye contact. The Cruzr is one of the most advanced fully-programmable robot that provides a new generation of developers with service applications for a variety of industries and research fields.

RobotLAB Kits are the best solution for classrooms. A combination of our products with the right tolls and right lessons are the best option to boost your students 21st-century skills. Discover our complete turnkey solutions that enable educators and students to make the most productive and efficient use of the robots in the classroom.

From equipment to software and curriculum, everything you need to make your program successful is included in a practical mobile charging cart. The CoDrone is a tiny quadcopter drone you can easily program to do whatever you want: follow you, engage in laser battles, go through a maze and more.

Bringing the rich learning environment of a classroom to a homebound or hospitalized student can be very difficult. The Double Robot enables the remote student to join the classroom in real-time, interact with other students one-on-one, and participate in group discussion. Bring AI to life with Misty, the autonomous roaming robot your students can program to move around and interact with humans.

The US government just gave someone a $120-million robotic arm to use for a year

Misty open-source platform and open hardware is designed to delight robotics enthusiasts and institutions while providing access to a high-tech tool. Develop Problem-Solving skills and Computational Thinking. Spark the next generation of innovators by introducing procedural thinking, cause and effect, decomposition of complex tasks, pattern recognition and the ability to notice similarities or common differences, abstraction and algorithm design and the ability to develop a step-by-step strategy for solving a problem, all using Cubelets robots.

Robotis is the latest and the most advanced ROBOTIS humanoid robot platform that combines advanced computational power, sophisticated sensors, high payload capacity, and dynamic motion ability to enable many exciting research and education activities.

Bring Coding to life with Marty, the walking robot your students can build and program to move around, play songs and interact with humans. Marty comes in a kit or pre-built. Marty is a fully programmable, WiFi enabled walking robot for Makers and Coders. It's designed to gets kids familiar with robotics and electronics. It's upgradeable and can be built without any soldering involved. LittleBits has been an amazing part of our student-driven space and has given students the opportunity to explore their passions, with LittleBits being the tool to take them to places only their imaginations dreamt of before.We set out to make the smallest, all-electric underwater robotic arms in the world and succeeded.

This filled a capability gap for users of portable Remotely Operated Vehicles ROVs and enabled subsea tasks previously reserved for larger underwater vehicles. Our customers include military organisations, service providers for the oil and gas industry conducting pipe and tank inspections, and scientists wanting to further their research in underwater robotics and marine biology.

We provide a Software Developers Kit and Communication Protocol Document for developers looking to create custom interfaces. Of course! For research customers, we have available a data pack including mass-inertia, kinematic, and hydrodynamic properties, DH parameters, and approximate torque-current relationships.

See Here. Skip to content. Dexterous, Tough, Easy to Control. An advanced, all-electric manipulator for inspection class Remotely Operated Vehicles. A revolutionary capability for ROV operations.

The US government just gave someone a $120-million robotic arm to use for a year

Designed for harsh environments. See Our Products In Action. Master Arm Controller. Alpha Five. Responsive Integration Support. Responsive Remote Support. Need more information on integration? Integrated and Proven on leading Remotely Operated Vehicles. Hear what our Customers say. Trusted by. Can I get an idea of the price range? What is the standard lead time? Can I get a 3D model? Can we? Stay updated on our latest news.

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