Found 9,462 products
radial gripper HGRT-40-A Size: 40, Max. replacement accuracy: <: 0,2 mm, Max. angular gripper jaw backlash ax,ay: <: 0,1 deg, Max. opening angle: 180 deg, Rotationally symmetrical: <: 0,2 mm
Quick Quote
cover kit EASC-S1-15-50 For covering the axis profile which is open at the top. Size: 15, Assembly position: Any, Corrosion resistance classification CRC: 2 - Moderate corrosion stress, Ambient temperature: -10 - 60 °C, Product weight: 57 g
Quick Quote
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
Quick Quote
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
Quick Quote
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
Quick Quote
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
Quick Quote
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
Quick Quote
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
Quick Quote
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
Quick Quote
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
Quick Quote
| Item | Manufacturer | Price | Stock | Delivery | |
|---|---|---|---|---|---|
 | 563912 radial gripper HGRT-40-A Size: 40, Max. replacement accuracy: <: 0,2 mm, Max. angular gripper jaw backlash ax,ay: <: 0,1 deg, Max. opening angle: 180 deg, Rotationally symmetrical: <: 0,2 mm | Festo | Quick Quote | ||
 | 562708 cover kit EASC-S1-15-50 For covering the axis profile which is open at the top. Size: 15, Assembly position: Any, Corrosion resistance classification CRC: 2 - Moderate corrosion stress, Ambient temperature: -10 - 60 °C, Product weight: 57 g | Festo | Quick Quote | ||
 | 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 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 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 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 | Quick Quote | ||
 | 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 | Quick Quote | ||
 | 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 | Quick Quote | ||
 | 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 | Quick Quote | ||
 | 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 | ||
Robotic Actuators
General Guide & Overview
Robotic actuators play a crucial role in the world of automation technology, enabling robots to move and perform tasks with precision and efficiency. These essential components convert stored energy into movement, allowing robots to interact with their environment and carry out complex actions. Whether it's the smooth movements of a robotic arm on an assembly line or the intricate motions of a surgical robot, actuators are the driving force behind robot movement.
Importance of Robotic Actuators in Robotics
Robotic actuators play a crucial role in the field of robotics, enabling robots to move and interact with their environment. They are not only responsible for making robots move but also for converting energy into motion, allowing robots to perform a wide range of tasks.
The role of actuators in robot movement cannot be overstated. They enable precise and accurate movements, making them essential for tasks that require precision, such as manufacturing or surgical procedures. Without actuators, robots would be static and unable to perform any actions.
Moreover, actuators facilitate the interaction between robots and their environment. By converting energy into motion, they enable robots to navigate through their surroundings and manipulate objects. Actuators are integrated with sensors and control systems, enhancing a robot's autonomy and intelligence.
Whether it's a humanoid robot mimicking human movements or an automated assembly line robot, actuators are at the core of their functionality. Their ability to convert energy into motion and enable robot movement is what sets robots apart from other machines.
It is through the seamless combination of actuators, sensors, and control systems that robots can perform complex tasks and adapt to changing environments. As the field of robotics continues to advance, actuators will be integral to unlocking new possibilities and pushing the boundaries of automation technology.
Types of Robotic Actuators and Their Applications
Robotic actuators are essential components that enable robots to move and perform tasks. They come in different types based on the requirements of motion: linear motion and rotational motion.
Linear Motion
For linear motion, two common types of actuators are used: linear actuators and solenoid actuators. Linear actuators are designed to push or pull a robot in a linear direction. They utilize mechanisms such as gears, belts, or screws to generate linear motion. On the other hand, solenoid actuators use electromagnetic activity to control motion. By applying a current to the solenoid coil, a magnetic field is created, which then moves a plunger back and forth in a linear manner.
Rotational Motion
In terms of rotational motion, three primary types of actuators are employed: DC motor actuators, servo motor actuators, and stepper motor actuators. DC motors are commonly used for turning motion, where the shaft rotates continuously in one direction or can be reversed. Servo motors, on the other hand, provide precise control over rotating motion. They incorporate feedback mechanisms to adjust the speed, position, and torque based on input signals. Lastly, stepper motors offer accurate and repetitive rotating activities. They use a step-by-step movement cycle, enabling precise control over position and speed.
These different types of actuators have various applications in robotics. Linear actuators and solenoid actuators are often used in applications where precise linear motion is required, such as in robotic arms or automation robots. DC motor actuators find their use in rotating joints and wheels, while servo motor actuators are suitable for tasks that demand precise position control, like robotic grippers. Stepper motor actuators are commonly utilized in applications that require accurate positioning and control, such as CNC machines or 3D printers.
Robotic actuators are the backbone of robot movement and performance. As essential components, they enable robots to interact with their environment and operate autonomously. Understanding the different types of actuators and their applications is crucial in designing and developing robots for various tasks.
These advancements in robotic actuators have revolutionized the field of robotics and automation. By converting energy into precise and accurate motion, actuators play a vital role in achieving tasks ranging from simple to complex. From manufacturing processes to surgical procedures, actuators ensure robots can perform actions with precision and efficiency.
The future possibilities for robotic actuators are vast. As research and development in robotics technology continue, we can expect to see further advancements in actuator design and performance. This will unlock even more potential for robots in various industries, including healthcare, manufacturing, logistics, and beyond.
By harnessing the power of robotic actuators, we are at the forefront of a new era in robotics. These components will continue to evolve and contribute to the advancement of robotics technology, shaping a future where robots play an increasingly prominent role in our lives.
FAQ
What is the role of robotic actuators in robotics?
Robotic actuators are essential components that enable robots to move and perform tasks. They convert stored energy into movement and play a crucial role in the field of robotics, allowing robots to interact with their environment and operate autonomously.
What types of motion do robotic actuators enable?
Robotic actuators enable both linear and rotational motion. Linear actuators and solenoid actuators are used for linear motion, while DC motor actuators, servo motor actuators, and stepper motor actuators are used for rotational motion.
What are the applications of robotic actuators in robotics?
Robotic actuators have various applications in robotics, including robotic arms, automation robots, manufacturing processes, surgical procedures, and more. They are critical for achieving precise and accurate movements required for different tasks.
How do robotic actuators contribute to a robot's autonomy and intelligence?
Robotic actuators are integrated with sensors and control systems to enhance a robot's autonomy and intelligence. They work in conjunction with these systems to provide feedback, monitor and adjust movements, and enable robots to make decisions based on environmental cues.
How are robotic actuators powered?
Robotic actuators can be powered by air, electricity, or liquids, depending on the specific type of actuator being used. The choice of power source depends on the requirements of the robot and the desired performance and efficiency.
What is the future outlook for robotic actuators?
The advancements in robotic actuators continue to unlock new possibilities in the field of robotics and automation. With further research and development, robotic actuators will continue to evolve, offering improved performance, efficiency, and versatility.