Robotic Parts on Powermatic Associates

Robotic Parts on Powermatic Associates

Robotic Parts

Essential elements in automation, robotic parts such as the robotic arm, end-effector, motors, controller, and sensors, enable robots to carry out tasks effectively. Gaining knowledge about these components aids in constructing dependable robotic systems that enhance productivity.

Found 9,518 products

8041836 on Powermatic Associates
Festo

spindle axis ELGA-BS-KF-120-100-0H-10P-ML With recirculating ball bearing guide Working stroke: 100 mm, Size: 120, Stroke reserve: 0 mm, Spindle diameter: 25 mm, Spindle pitch: 10 mm/U

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574103 on Powermatic Associates
Festo

electric cylinder ESBF-BS-63-400-25P With ball screw, electrically actuated spindle that converts the rotary motion of the motor into linear motion of the piston rod. Size: 63, Stroke: 400 mm, Piston rod thread: M16x1,5, Reversing backlash: 40 µm, Spindle

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574106 on Powermatic Associates
Festo

electric cylinder ESBF-BS-80-400-5P With ball screw, electrically actuated spindle that converts the rotary motion of the motor into linear motion of the piston rod. Size: 80, Stroke: 400 mm, Piston rod thread: M20x1,5, Reversing backlash: 30 µm, Spindle

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574105 on Powermatic Associates
Festo

electric cylinder ESBF-BS-80-300-5P With ball screw, electrically actuated spindle that converts the rotary motion of the motor into linear motion of the piston rod. Size: 80, Stroke: 300 mm, Piston rod thread: M20x1,5, Reversing backlash: 30 µm, Spindle

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1133405 on Powermatic Associates
Festo

axial kit EAMM-A-R48-87A Suitable for electric drives. Assembly position: Any, Storage temperature: -25 - 60 °C, Relative air humidity: 0 - 95 %, Protection class: IP40, Ambient temperature: -10 - 60 °C

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1132937 on Powermatic Associates
Festo

parallel gripper HGPD-16-A-G1 With gripping force backup when opening ...-G1. Size: 16, Stroke per gripper jaw: 3 mm, Max. replacement accuracy: <: 0,2 mm, Max. angular gripper jaw backlash ax,ay: <: 0,1 deg, Max. gripper jaw backlash Sz: <: 0,02 mm

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1323641 on Powermatic Associates
Festo

sensor rail DASP-G3-33-C-U suitable for bellows gripper DHEB. Size: 33, Assembly position: Any, Design structure: Sensor strip, Corrosion resistance classification CRC: 2 - Moderate corrosion stress, Ambient temperature: 5 - 60 °C

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1320818 on Powermatic Associates
Festo

bellows gripper DHEB-51-E-U-E-L Size: 51, Stroke of the bellows: 18 mm, Min. diameter to be gripped: 54 mm, Max. diameter to be gripped: 68 mm, Assembly position: Any

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1219440 on Powermatic Associates
Festo

parallel kit EAMM-U-145-S62-140A-288 Suitable for electric drives. Size: 145, Assembly position: Any, Gear unit ratio: 1:1, Max. speed: 4000 1/min, Storage temperature: -25 - 60 °C

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1453062 on Powermatic Associates
Festo

coupling EAMC-30-35-6-10 Holder diameter 1: 6 mm, Holder diameter 2: 10 mm, Size: 30, Nominal length: 35 mm, Assembly position: Any

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ItemManufacturerPriceStockDelivery
8041836 on Powermatic Associates

8041836

spindle axis ELGA-BS-KF-120-100-0H-10P-ML With recirculating ball bearing guide Working stroke: 100 mm, Size: 120, Stroke reserve: 0 mm, Spindle diameter: 25 mm, Spindle pitch: 10 mm/U

Festo

Quick Quote

574103 on Powermatic Associates

574103

electric cylinder ESBF-BS-63-400-25P With ball screw, electrically actuated spindle that converts the rotary motion of the motor into linear motion of the piston rod. Size: 63, Stroke: 400 mm, Piston rod thread: M16x1,5, Reversing backlash: 40 µm, Spindle

Festo

Quick Quote

574106 on Powermatic Associates

574106

electric cylinder ESBF-BS-80-400-5P With ball screw, electrically actuated spindle that converts the rotary motion of the motor into linear motion of the piston rod. Size: 80, Stroke: 400 mm, Piston rod thread: M20x1,5, Reversing backlash: 30 µm, Spindle

Festo

Quick Quote

574105 on Powermatic Associates

574105

electric cylinder ESBF-BS-80-300-5P With ball screw, electrically actuated spindle that converts the rotary motion of the motor into linear motion of the piston rod. Size: 80, Stroke: 300 mm, Piston rod thread: M20x1,5, Reversing backlash: 30 µm, Spindle

Festo

Quick Quote

1133405 on Powermatic Associates

1133405

axial kit EAMM-A-R48-87A Suitable for electric drives. Assembly position: Any, Storage temperature: -25 - 60 °C, Relative air humidity: 0 - 95 %, Protection class: IP40, Ambient temperature: -10 - 60 °C

Festo

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1132937 on Powermatic Associates

1132937

parallel gripper HGPD-16-A-G1 With gripping force backup when opening ...-G1. Size: 16, Stroke per gripper jaw: 3 mm, Max. replacement accuracy: <: 0,2 mm, Max. angular gripper jaw backlash ax,ay: <: 0,1 deg, Max. gripper jaw backlash Sz: <: 0,02 mm

Festo

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1323641 on Powermatic Associates

1323641

sensor rail DASP-G3-33-C-U suitable for bellows gripper DHEB. Size: 33, Assembly position: Any, Design structure: Sensor strip, Corrosion resistance classification CRC: 2 - Moderate corrosion stress, Ambient temperature: 5 - 60 °C

Festo

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1320818 on Powermatic Associates

1320818

bellows gripper DHEB-51-E-U-E-L Size: 51, Stroke of the bellows: 18 mm, Min. diameter to be gripped: 54 mm, Max. diameter to be gripped: 68 mm, Assembly position: Any

Festo

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1219440 on Powermatic Associates

1219440

parallel kit EAMM-U-145-S62-140A-288 Suitable for electric drives. Size: 145, Assembly position: Any, Gear unit ratio: 1:1, Max. speed: 4000 1/min, Storage temperature: -25 - 60 °C

Festo

Quick Quote

1453062 on Powermatic Associates

1453062

coupling EAMC-30-35-6-10 Holder diameter 1: 6 mm, Holder diameter 2: 10 mm, Size: 30, Nominal length: 35 mm, Assembly position: Any

Festo

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Robotic Parts

General Guide & Overview

In the world of industrial automation and robotics, robotic systems play a crucial role in enhancing productivity and efficiency. Behind the remarkable capabilities of these robots lie the intricate integration of various robotic parts.

Building industrial robots requires a deep understanding of the components that make them function seamlessly. From the robotic arm to the sensors, each part serves a specific purpose, contributing to the overall performance of the robot.

Modern advancements in technology have revolutionized the design and functionality of robotic parts, making them faster, more compact, and affordable. These advancements have significantly impacted industries such as automotive, heavy machinery, and railways, where industrial robots have become indispensable.

Industrial robots are typically comprised of five main components: the robotic arm, end-effector, motors, controller, and sensors. While the specific parts may vary based on the robot design, these core components form the foundation of most industrial robots.

By understanding the intricacies of these robotic parts and their integration into a robot system, companies can build and maintain reliable and efficient robotic systems. This knowledge is vital for selecting reputable industrial robot manufacturers who prioritize the quality and workmanship of their robotic parts.

The Parts of an Industrial Robot

The robotic arm, also known as the manipulator, is the part of the robot that performs various tasks. It is made up of a shoulder, elbow, and wrist, similar to a human arm. The end-effector, also called the robot's hand, is a tool device attached to the wrist of the robotic arm. It provides the robot with more dexterity and enables it to perform specific tasks.

Motors play a crucial role in powering the robotic parts and facilitating their movement. They provide the necessary torque and control for the robotic arm to perform precise actions. The controller, often referred to as the brain of the robot, is responsible for controlling all the other parts and executing commands based on the desired task.

The Role of Sensors

Sensors are essential components of an industrial robot as they detect and measure parameters in the robot's environment, ensuring safety and control. These sensors can include proximity sensors, force sensors, vision sensors, and more. They provide crucial feedback to the controller, allowing the robot to adapt and respond to its surroundings.

The integration of these different parts creates a powerful and versatile industrial robot. The structure of the robot is designed for optimal performance and efficiency, allowing it to carry out complex tasks with precision. From the robust robotic arm to the highly sensitive sensors, each component plays a vital role in the overall functionality of the robot.

Robot Motion and Control Systems

Robots can have different types of control systems that determine their behavior. Control systems play a crucial role in enabling robots to perform tasks accurately and efficiently.

Pre-Programmed Robots

Pre-programmed robots follow a fixed program that dictates their actions. These robots are ideal for performing repetitive tasks with minimal environmental input. By executing a sequence of predefined commands, pre-programmed robots can complete specific tasks on a loop, ensuring consistency and precision.

Autonomous Robots

Autonomous robots are designed to adapt to changes in their environment. These robots utilize sensors to gather information about their surroundings, enabling them to make decisions and perform tasks based on real-time data. Autonomous robots are capable of navigating complex environments, adjusting their actions accordingly to achieve their objectives efficiently.

Sensors: Gathering Environmental Information

Sensors are essential components of robot control systems. They detect and measure various aspects of the environment, providing robots with valuable information to make informed decisions. Robots employ a wide range of sensors, including visual sensors for capturing images, sound sensors for detecting auditory signals, collision sensors for avoiding obstacles, temperature sensors for measuring heat levels, and pressure sensors for determining the force in a given area.

Effectors: Enabling Robot Work

Effectors are the parts of the robot that perform the actual work. They include end-effectors or tools attached to the robotic arm. These effectors enable robots to interact with their surroundings, manipulate objects, and carry out specific tasks. Examples of effectors include grippers, welding tools, or even specialized equipment designed for specific applications.

Understanding the different parts of an industrial robot is crucial for the successful construction and maintenance of robotic systems. The quality and integration of these robotic parts play a significant role in determining the overall performance and reliability of the system. Therefore, it is essential for businesses to select reputable industrial robot brands that prioritize the excellence and craftsmanship of their components.

By choosing a reliable manufacturer, companies can ensure that they are utilizing high-quality robotic parts that meet industry standards. These parts, when integrated into the robotic structure, contribute to enhancing the overall robot performance, leading to increased productivity, improved product quality, and operational efficiency.

Moreover, having a basic understanding of robot structures and the functions of different parts also helps in the effective implementation of robots across various industries. With this knowledge, businesses can identify the specific robotic parts required for their applications and harness their capabilities accordingly. This understanding enables companies to optimize the robot's performance and tailor it to their unique requirements, thereby maximizing their return on investment.

FAQ

The main parts of an industrial robot include the robotic arm, end-effector, motors, controller, and sensors.

The robotic arm, also known as the manipulator, performs various tasks and is made up of a shoulder, elbow, and wrist, similar to a human arm.

The end-effector is a tool device attached to the wrist of the robotic arm, providing the robot with more dexterity and enabling it to perform specific tasks.

Motors are used to power the robotic parts and facilitate their movement.

The controller serves as the brain of the robot, controlling all other parts and executing commands.

Sensors detect and measure various parameters in the robot's environment, ensuring safety and control.

Pre-programmed robots perform repetitive actions based on a fixed program and limited environmental input, while autonomous robots can adapt to changes in complex environments.

Sensors gather information about the surroundings, such as visual information, sound, collision detection, temperature, and pressure.

Effectors are the parts of the robot that actually perform the work, such as end-effectors or tools attached to the robotic arm.

Understanding the different parts of an industrial robot is essential for building and maintaining robotic systems, improving performance, reliability, and efficiency.