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Boisbriand, Canada
11-50 Employees
2003
Founded in 2003, we specialize in robotics technology and offer a wide range of products and services in this sector. We operate globally and our head office is located in Mirabel, Quebec, Canada.
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Featured
Hydraulic Robotic Arm
... of pieces: 229 Powered by water Comes with a suction cup No battery or motor required Ages: 14+ The Hydraulic Robotic Arm is easy to follow instructions with detailed graphic illustrations page the way for successful and satisfying kit building (229 pieces in total). Complement your ...
Haidian District, China
11-50 Employees
Utilize WLKATA solutions in the university courses and research of AI, IoT, and robotics. WLKATA products are chosen by thousands of educators and students in 1500+ schools, universities and institutes globally. We have delivered hundreds of robotics sets customized for educators, exhibitions, competitions and labs. Purchases are delivered in their original packages inside the corrugated cardboard boxes, with the exception of certain items. Items returned within 14 days of their original shipment delivery date in same as new condition will be eligible for a full refund.
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Wlkata Mirobot Education Kit - 6 Axis Robotic Arm -Ros & Matlab Simulation Teaching
... WLkata Mirobot is a 6 axis open source desktop robotics arm with forward and inverse kinematic algorithm, AI robotics competition. With various end-tools, controller, conveyor belts, sliding rails, visual recognition kit, rover and more, the educators and makers can create countless future ...
United States
11-50 Employees
2018
The AOT Device is solving major issues within the current drive-thru order process as the following: . The AOT device is a product interacting with customers, therefore it’s important to us to keep them at the center of attention design wise, without forgetting that it will be operated by restaurants, for which cost control is extremely important. As the AOT Company vision is to register itself not only into the current market but also into the market of tomorrow, Innovation is embedded into our design philosophy, allowing us to come up with cutting edge technology solution, helping us to deliver always improve users experience and cost efficiency.
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Aotdevice | Drive thru robotic arm
... The Aotdevice is a robotic arm powered with artificial intelligence to smooth the drive thru experience and increase operator's profitability. ...
Tustin, United States
1-10 Employees
INAC US is an expert in product development. We transform the ideas and imaginations of our customers into products with our innovative technology and over 20 years of experience. In addition to machining, modeling, and welding, we offer design and painting services. Through cooperation among branches in the three countries, we offer the highest level of services and products based on customers’ needs. A high-quality transparent model would be manufactured by our unique high transparency treatment. Cost-effective production is possible by using this technology, when creating prototypes in small quantities, such as 5 to 100.
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Robotic Arm Design Mock Up
... Robotic Arm Design Mock Up Robotic Arm Visualization Robotic Arm for a design mock up Focusing on the robotic arms that continue to operate in mass production lines, we’ve created modification samples for exhibit. Three-dimentional INAC original design robotic arms ...
United States
501-1000 Employees
We provide a comprehensive range of medical services and high quality care. We are closely following information and guidance provided by the Oklahoma State Department of Health and the Centers for Disease Control and Prevention. We are prepared should a case of COVID-19 present at one of our facilities; however, we ask for the public’s help to prevent the spread. Community Hospital’s south campus is a full-service hospital serving Southwest Oklahoma City and the surrounding communities including Blanchard, Moore, Newcastle, Norman, Mustang and Tuttle. Community Hospital’s north campus celebrated the opening of its new facility in 2016 and offers inpatient and outpatient services, including diagnostic imaging and direct access to physician offices. Community Hospital’s most important mission is to serve you and your family. A unique strength of our hospitals is the strategic relationship that we have developed with The Physicians’ Group (TPG) and OSSO physicians. This partnership between the hospitals and the medical staff provides us with new resources for continual growth.
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MAKOTM ROBOTIC-ARM ASSISTED SURGERY
... What Surgeons Say About Mako Robotic-Arm Assisted ...
Sydney, Australia
11-50 Employees
2016
We develop advanced manipulator arm solutions for harsh environments. Our products enable complex inspection and intervention in maritime infrastructure management (UWILD, NDT, CVI, Sampling), military/police operations (Special Recovery), marine science, autonomous robotics research applications, and more. We are one team built on trust, grit, integrity, and the collective pursuit of excellence in the robotic systems we develop. We are motivated by listening to the problems our clients have and developing the solutions that will impact their operations, and our world, for the better. At Reach Robotics, we are a diverse team of enthusiastic individuals, passionate about what we do. The Reach X manipulatior series is designed for mission-critical remote intervention. The world’s most lightweight, all-electric manipulator for portable ROVs, offering a complete solution for close inspection and intervention in confined or complex spaces.
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Robotic Arm Control Software
... Our Robotic Arm Control Software Package provides an interface between operator & manipulator. Find out about kinematic control and robotic arm control ...
Beijing, China
11-50 Employees
2014
It provides you with all the hardware, software, and accessories you need to build your robots. Under the hood powering MIND Kit, is MIND OS 2.0, Vincross’ updated robotics-specific operating system that can be accessed through a simple SDK, making it easier than ever to build your robot’s skills, movements, and applications, without requiring deep robotics development skills.
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Robotic Arm Kit
... Robotic Arm Kit – ...
London, United Kingdom
11-50 Employees
2016
We created Inovo Robotics to make capable, versatile, robotics accessible to all. We address the problems growing businesses have in automating repetitive, hazardous or precise tasks. We believe there is a better way and want to free your staff from the monotony of repetitive tasks so you can focus them on more valuable and rewarding work. We also believe in putting you in control by providing intuitive, easy to use interfaces, so that configuring our robots for your specific task, is as easy as possible. Our robotic arms can be used to automate a wide variety of repetitive tasks in manufacturing and research applications as well as providing a great tool for education.
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INOVO ROBOTICS - Modular Manipulator arms
... INOVO ROBOTICS - Modular Manipulator arms ...
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6-axis compact and high-speed robotic arms - Gerkon Industriezerspanung
... 6-axis compact and high-speed robotic arms - Gerkon ...
Technologies which have been searched by others and may be interesting for you:
Some interesting numbers and facts about the results you have just received for Robotic Arm
| Country with most fitting companies | United States |
| Amount of fitting manufacturers | 280 |
| Amount of suitable service providers | 202 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 2003 |
| Youngest suiting company | 2018 |
A robotic arm is a highly sophisticated piece of machinery designed to replicate the motions and, to some extent, the functionalities of a human arm. The integration of motors, actuators, sensors, and software allows it to perform a wide range of tasks with precision and efficiency. Typically consisting of multiple joints and linkages, these arms can rotate, pivot, and move in several directions, granting them the flexibility needed to carry out complex operations. In the realm of industrial automation, robotic arms have revolutionized manufacturing processes by enhancing productivity, reducing errors, and improving safety standards. They are pivotal in assembly lines, where they perform tasks such as welding, painting, and picking and placing items with unwavering accuracy. Beyond manufacturing, their applications extend into sectors like healthcare, where they assist in surgery, and space exploration, aiding in repairs and maintenance of spacecraft. The adaptability of robotic arms to various tasks and environments underscores their significance in advancing technological capabilities and operational efficiencies across multiple industries. Their ongoing development promises even greater precision and autonomy, hinting at a future where their impact transcends current limitations, further blurring the lines between human and machine capabilities.
1. Enhanced Precision and Accuracy
Robotic arms are engineered to perform tasks with a level of precision that far surpasses human capabilities. This heightened accuracy is crucial in industries where even the slightest error can lead to significant losses, such as in manufacturing microchips or conducting surgical procedures.
2. Increased Productivity
Unlike humans, robotic arms can operate continuously without breaks, fatigue, or a drop in performance. This ability to work 24/7 significantly boosts productivity, allowing businesses to achieve higher output rates and meet production targets more efficiently.
3. Improved Safety
Robotic arms can be deployed in hazardous environments where human safety is at risk. Whether it's handling toxic substances, working in extreme temperatures, or performing tasks in confined spaces, these machines can take on dangerous jobs, reducing workplace injuries.
4. Cost Efficiency
Although the initial investment in robotic technology may be high, the long-term savings are substantial. By automating repetitive tasks, companies can reduce labor costs and minimize human error, leading to a quicker return on investment.
5. Versatility
Robotic arms can be reprogrammed and equipped with different tools to perform a wide range of tasks. This versatility makes them a valuable asset across various sectors, from automotive assembly lines to delicate surgical operations, showcasing their adaptability to different work environments.
While evaluating the different suppliers make sure to check the following criteria:
1. Precision and Accuracy
Ensure the robotic arm meets your specific precision and accuracy requirements for the tasks it will perform.
2. Load Capacity
Consider the maximum weight the robotic arm can handle, ensuring it matches your project's needs.
3. Speed and Range of Motion
Review the arm's operational speed and flexibility to ensure it can efficiently complete tasks within your workspace.
4. Compatibility and Integration
Check for compatibility with existing systems and ease of integration into your current workflow.
5. After-sales Support and Warranty
Evaluate the quality of customer service, including after-sales support, maintenance services, and warranty conditions.
6. Cost-effectiveness
Balance initial costs with long-term benefits, considering energy consumption, maintenance costs, and potential downtime.
Robotic arms have revolutionized operations across numerous industries, streamlining processes that demand precision, efficiency, and reliability. In the manufacturing sector, these mechanical marvels are indispensable for assembly lines. They perform tasks with unmatched speed and accuracy, from assembling intricate electronic components to welding and painting automotive parts. This automation not only boosts production rates but also significantly reduces error margins, ensuring consistent product quality. In the realm of healthcare, robotic arms are transforming surgeries by providing surgeons with enhanced dexterity and control. These devices enable minimally invasive procedures, reducing patient recovery times and improving surgical outcomes. The precision of robotic arms is pivotal in performing delicate operations, such as those on the spine or brain, where human hands might lack the necessary steadiness or reach. Agriculture has also embraced robotic arms, utilizing them for tasks like planting, harvesting, and packaging. This technology addresses labor shortages by performing labor-intensive work, allowing for more sustainable farming practices. Robotic arms equipped with vision systems can identify ripe produce, ensuring only the best quality fruits and vegetables are picked and handled gently to reduce waste. In the logistics and warehousing industry, robotic arms expedite the sorting and packaging process. They swiftly move goods, managing tasks from picking items off conveyors to packaging them for shipment. This automation streamlines warehouse operations, enhancing efficiency and reducing the physical strain on human workers. By integrating robotic arms, businesses across these sectors are not only optimizing their operations but are also paving the way for innovative solutions that redefine what's possible within their respective fields.
Robotic arms have reached a high degree of sophistication and are considered to be at Technology Readiness Level (TRL) 9, which indicates that they are fully developed technologies that have been proven to work in operational environments. This status is attributed to their extensive implementation across various industries, including manufacturing, healthcare, and space exploration, where they perform tasks ranging from assembly line work to surgical assistance and handling of materials in outer space. The achievement of TRL 9 is due to significant advancements in precision engineering, materials science, and computer programming, which have collectively enhanced the functionality, reliability, and efficiency of robotic arms. Innovations such as machine learning algorithms and sensor technology have further improved their adaptability and sensitivity, allowing them to perform complex tasks with a high degree of accuracy and minimal human intervention. The integration of these technological advancements has enabled robotic arms to operate in highly dynamic and unpredictable environments, solidifying their status at the pinnacle of technology readiness.
In the Short-Term, robotic arms are expected to see significant improvements in precision and flexibility. Advances in artificial intelligence and machine learning algorithms will enable these machines to perform tasks with greater accuracy and adaptability. Manufacturers will likely introduce more compact and energy-efficient models, making robotic arms more accessible for small and medium-sized enterprises. Integration with IoT devices will enhance their functionality, allowing for real-time monitoring and control. The Mid-Term phase will witness the incorporation of advanced sensory capabilities, enabling robotic arms to handle delicate and complex tasks with unprecedented finesse. Haptic feedback technology will allow operators to experience a tactile sensation, making remote operation more intuitive. Additionally, the development of more sophisticated AI models will facilitate autonomous decision-making, reducing the need for human intervention. This period will also see a broader application of robotic arms across various industries, from healthcare to construction, driven by their enhanced versatility. Looking into the Long-Term, the integration of quantum computing and nanotechnology will revolutionize the capabilities of robotic arms. These technological leaps will drastically increase processing power and precision, allowing for applications in fields that require molecular-level precision, such as advanced materials manufacturing and biotechnology. Furthermore, the advent of fully autonomous robotic systems will see robotic arms operating independently, capable of self-maintenance and learning from their environment, pushing the boundaries of current applications and paving the way for innovations in virtually every sector.
