Fact-checked by Grok 2 weeks ago

Actuator

An actuator is a or that converts an input signal or source into physical motion or force, serving as the output component in control systems to effect changes in an . Typically, it functions as a that transforms electrical, hydraulic, pneumatic, or other forms of into action, such as linear , , or generation. This enables precise control over systems, where actuators respond to commands from sensors and controllers to perform tasks like positioning, gripping, or . Actuators are classified into several primary types based on their operating principles and sources, including electric, hydraulic, pneumatic, and variants, each optimized for criteria like speed, , and . Electric actuators, such as DC motors, stepper motors, solenoids, and servo motors, dominate applications requiring fine and compact due to their responsiveness to electrical signals and with systems. Hydraulic and pneumatic actuators, by contrast, excel in delivering high and , making them suitable for heavy-duty operations where electrical alternatives might falter under extreme loads. actuators, including screw drives and linkages, provide reliable, low-maintenance motion conversion often used in machinery. In and , actuators underpin a wide array of applications across industries, from —where they generate forces for movement and manipulation—to automotive systems for control and braking, for flight surface adjustments, and industrial automation for operation and lines. Emerging developments include soft actuators, which mimic biological muscles using materials like polymers or fluids for flexible, biomimetic uses in wearables, medical devices, and haptic interfaces. Their design must balance factors such as , , response time, and to meet and reliability standards in critical systems.

Fundamentals

Definition and Function

An actuator is a device that converts input from sources such as electrical, hydraulic, pneumatic, or forms into output, typically in the form of linear or rotary motion, to enable tasks like positioning, application, or . This conversion process allows actuators to produce , , or movement in response to signals, making them integral to systems requiring dynamic physical interaction. In control systems, actuators serve as the primary mechanism for translating commands from sensors and controllers into tangible physical actions, often described as the "muscle" that bridges digital or fluid inputs with mechanical outputs. They are essential in , , and , where precise and repeatable motion is required to manipulate environments or objects efficiently. Various types, such as hydraulic or electric, fulfill this bridging function through distinct energy-handling approaches. Key components of an actuator generally include an to receive and the input , a conversion that transforms the into motion, and an output —such as a , , or linkage—that delivers the mechanical work to the system. This modular structure ensures reliable transfer and adaptability across applications. While often confused with motors, actuators represent a broader category; electric motors typically convert electrical energy into rotary mechanical motion, though linear motors produce linear motion directly, whereas actuators include diverse non-electrical conversions and can produce both linear and limited rotary outputs tailored to specific operational needs.

Operating Principles

Actuators function by converting input from sources such as electrical potential, kinetic , or gradients into output in the form of motion or . This transformation adheres to the principle, where inefficiencies like heat loss may occur, but the primary goal is to harness the input efficiently for controlled work. Mechanisms such as , pressure differentials in , or material expansion due to changes mediate this conversion, enabling precise manipulation of , , or in systems. At the core of actuator operation lie fundamental physics principles, particularly Newton's laws of motion, which govern force generation and resulting acceleration. Newton's second law, F = ma, describes how an actuator imparts force (F) to accelerate a mass (m) at rate a, determining the dynamic response to loads. Complementing this, the work-energy principle quantifies output through the equation W = F × d, where W represents mechanical work, F is the generated force, and d is the displacement; this relation establishes the scale of energy transfer from input to useful motion, often limited by material properties and design constraints. Many actuators operate within closed-loop control systems to achieve accuracy and , integrating from that monitor , , or . provide to a controller, which adjusts the actuator input to minimize errors between desired and actual outputs, forming a that enhances precision in dynamic environments. A of such a system includes the reference input, controller, actuator (which drives the plant or load), output measurement via , and error signal closing the . This configuration, rooted in , allows for adaptive responses to disturbances. Actuators produce either linear or rotary motion, each governed by distinct kinematic principles. Linear motion involves straight-line displacement, such as the extension of a piston, where force directly translates along a single axis to achieve position control over a distance. In contrast, rotary motion generates angular displacement through torque, enabling rotational outputs like joint pivoting, with principles focusing on angular acceleration and moment of inertia rather than linear path constraints. The choice between linear and rotary depends on application requirements, but both rely on the same foundational energy conversion to deliver controlled mechanical action.

History

Early Developments

The concept of actuators originated in ancient times with simple mechanical devices that converted input forces into controlled motion or force amplification. Lever-based systems, fundamental to early machines, enabled basic actuation through , as seen in tools like pulleys and wedges used in and across ancient civilizations. A notable example is the , developed around the 3rd century BCE by the Greek mathematician , which demonstrated early principles of motion conversion by transforming rotational motion into axial water displacement within a helical tube. This device efficiently raised water from lower to higher elevations, relying on manual cranking for operation and illustrating pre-industrial actuation principles in hydraulic lifting. The late 18th century marked a pivotal shift toward powered actuators, integrating thermal and hydraulic energy sources for greater force output. James Watt's enhancements to the during the 1760s introduced linkage mechanisms that acted as thermal-mechanical actuators, harnessing steam expansion to drive motion and convert it into rotational output for industrial machinery. Specifically, Watt's , refined and patented in 1784, guided the piston's linear reciprocation with improved straight-line accuracy, boosting engine efficiency and enabling broader mechanical applications. Complementing this, patented the in 1795, which amplified force via fluid pressure in interconnected cylinders of varying sizes, based on Pascal's principle, to achieve precise and powerful linear actuation for tasks like and pressing. This innovation demonstrated hydraulic actuation's potential for high-force multiplication with minimal input effort. Electrical actuation principles emerged in the early through Michael Faraday's pioneering work. In , Faraday constructed the first electromagnetic rotation device, a rudimentary motor that converted electrical current into continuous rotary motion by suspending a current-carrying wire near a permanent in a mercury bath. This experiment established the foundational interaction between electricity and magnetism for electromechanical conversion, laying the groundwork for future electric actuators despite its limited and practical utility at the time. These early actuators, while revolutionary, faced inherent limitations due to their dependence on manual labor, , or basic electrical setups, which restricted and introduced variability in performance. Precision was particularly challenged by the absence of feedback mechanisms, resulting in inconsistent and vulnerability to external factors like temperature fluctuations in systems or leaks in .

Modern Innovations

In the early 20th century, actuators emerged as a pivotal innovation, with the first commercial valves developed in 1910 by the Automatic Switch Company (ASCO) for reliable electric switching in industrial and electrical systems. These electromagnetic devices converted into linear motion, enabling precise and rapid in automated processes. Concurrently, in the 1920s, Russian-American engineer Nicholas Minorsky pioneered servo motors for naval applications, introducing the first theoretical framework for proportional-integral-derivative () control in automatic ship steering systems tested on U.S. Navy vessels like the USS New Mexico. This advancement marked a shift toward feedback-based precision actuation, laying the groundwork for modern closed-loop in dynamic environments. Following , hydraulic actuators gained prominence in aviation during the 1940s, driven by wartime demands for robust, high-force systems in flight controls and . Their ability to transmit power efficiently through fluid pressure supported the evolution of larger, faster . In parallel, piezoelectric actuators—based on the effect discovered by the Curie brothers in 1880—transitioned to practical use in the 1950s, particularly for micro-positioning in precision instruments and sonar devices, where their sub-micrometer displacements and fast response times proved invaluable. Shape-memory alloys, exemplified by Nitinol (a nickel-titanium compound) invented in the early 1960s at the , further expanded actuator capabilities by enabling thermally triggered shape recovery for compact, lightweight mechanisms. Entering the 21st century, innovations in introduced dielectric elastomer actuators using compliant polymer films, which deform under electric fields to achieve large strains (up to 100%) and mimic biological motion; these gained traction in the for flexible, lightweight designs. Advancements in Nitinol processing during the same period enhanced its fatigue resistance and actuation speed, broadening its use in biomedical and actuators. Broader trends since the have emphasized through micro-electro-mechanical systems (), integrating nanoscale sensors and actuators on for applications requiring extreme precision and low power. More recently, integration has enabled , allowing actuators to predict and adjust to environmental changes via algorithms for optimized performance.

Types of Actuators

Mechanical Actuators

Mechanical actuators are devices that convert input motion into output motion through the use of solid components such as linkages, cams, levers, screws, and , enabling the transmission and amplification of force without relying on external energy sources like fluids or during operation. These systems operate on principles of kinematic chains, where interconnected elements transform rotary or linear inputs into desired outputs, often achieving precise through geometric arrangements. Key mechanisms include levers, which provide by balancing effort and load around a , defined as MA = load/effort; gears and cams, which transmit while altering speed and ; and screws, such as rack-and-pinion systems that convert rotary motion of a gear into along a toothed . For instance, a rack-and-pinion converts circular gear into straight-line displacement, commonly used in applications for direct and responsive linear output. Representative examples encompass gear reducers, which amplify by reducing speed through meshed gear trains, and ball screws, which utilize recirculating balls between the screw and nut to achieve high-precision linear positioning with minimal sliding . These actuators offer advantages in simplicity of construction, reliability in passive operation without ongoing power input, and cost-effectiveness for applications requiring manual or stored-energy actuation. Design considerations focus on minimizing backlash—the clearance between components like or screws that can cause positioning inaccuracies—and mitigating wear from , which reduces over time through material degradation. Achieving optimal involves selecting component ratios to balance force amplification against speed loss, while materials like hardened steels help endure frictional stresses. In practice, mechanical actuators serve common roles in manual overrides for machinery, allowing human intervention to disengage or adjust automated systems via direct linkage.

Hydraulic Actuators

Hydraulic actuators convert hydraulic energy into mechanical motion by utilizing pressurized incompressible , such as or , to produce linear or rotary output. The fundamental operation relies on pumping the fluid into sealed chambers within cylinders or motors, where the generates to move pistons or vanes. This process is governed by Pascal's principle, which states that pressure applied to a confined fluid is transmitted undiminished and equally in all directions, allowing force multiplication based on the relation P = F/A, where P is pressure, F is force, and A is cross-sectional area. Essential components of hydraulic actuators include pumps, which generate the required ; valves, which direct and regulate flow; and actuators themselves, such as cylinders for or hydraulic motors for rotary motion. Pumps can be gear, vane, or types, while valves range from directional to pressure relief variants to ensure safe operation. Systems are classified as open-loop, where is drawn from and returned to a , or closed-loop, which recirculates directly between and actuator for in continuous applications. Hydraulic actuators offer advantages including high , enabling compact designs with substantial force output, and smooth, controllable motion suitable for heavy-duty tasks. However, they are prone to disadvantages such as fluid leakage from and connections, which can lead to losses and environmental concerns, as well as requiring regular to prevent and . A notable variant is the servo-hydraulic actuator, which integrates electronic feedback and proportional valves for high-precision and control, achieving dynamic responses in applications demanding accuracy within micrometers. These systems enhance over basic hydraulic setups by enabling closed-loop with sensors for real-time adjustments.

Pneumatic Actuators

Pneumatic actuators convert the stored in or gas into mechanical motion, typically linear or rotary, by exploiting the of the . This allows for rapid expansion and contraction, enabling quick response times in dynamic applications, though it also leads to variations in output as changes with volume. The fundamental relies on supplying pressurized gas to a sealed chamber, where it pushes against a movable like a or vane, generating proportional to the pressure difference across the element. The pressure-volume dynamics during motion follow , which describes the isothermal behavior of an : for a constant and amount of gas, pressure times volume remains constant (PV = k). As the actuator extends or rotates, the gas volume increases, causing pressure to decrease unless compensated by additional supply, which highlights the role of in both enabling speed and complicating precise control. Compressed gas drives pistons in linear configurations or vanes in rotary ones, with exhaust valves releasing the gas to reset the position. Essential components include air compressors to generate and maintain , typically up to 10 in industrial systems, and solenoid-operated valves to the and timing of gas into and out of the actuator. Cylinders serve as the primary motion-producing elements, available in single-acting designs that use for extension and a for retraction, or double-acting types that employ air for motion in both directions, offering greater versatility. Pneumatic actuators offer several advantages, including their cleanliness since they use ambient air as the medium, avoiding risks, and inherent safety in environments due to the non-flammable nature of the gas. They also provide fast response times, often under 50 milliseconds, owing to the low and of air, making them suitable for high-speed tasks. However, disadvantages include lower maximum force output—typically limited to around 10-20 kN compared to hydraulic systems—and operational noise from air exhaust, which can exceed 80 without mufflers. The reduces , leading to less precise positioning under varying loads. A common variant is the rotary vane actuator, where a pivoting vane divides a cylindrical chamber into two compartments; pressurized air enters one side to rotate the vane up to 270 degrees, producing for angular motion in valves or robotic joints. This design benefits from a compact and direct conversion of pressure to rotation without linkages. Pneumatic systems share principles with but utilize gases for lighter, more compliant setups in applications prioritizing speed over heavy loads.

Electrical Actuators

Electrical actuators convert into mechanical motion through electromagnetic or electrostatic mechanisms, enabling precise and controllable movement in systems ranging from to industrial automation. These devices typically operate by applying voltage and current to produce forces that drive linear or rotary outputs, distinguishing them from purely mechanical systems by their active electrical input. Common applications leverage their compatibility with signals for tasks requiring repeatability and . Key subtypes of electrical actuators include electromechanical variants such as solenoids, which generate by energizing a to create a that pulls or pushes an armature, and motors including , , and types that produce rotary motion through interactions between current-carrying coils and magnetic fields. These subtypes allow flexibility in design, with electromechanical options suiting compact, low-to-medium force needs. Within these, electrical actuators are categorized by motion type: linear actuators like motors, which directly translate electrical into straight-line displacement using a coil moving in a permanent , offer backlash-free operation ideal for short-stroke tasks. Rotary actuators, such as servo motors, provide controlled angular rotation, often incorporating encoders for closed-loop to achieve accurate positioning up to thousands of . Another important subtype is piezoelectric actuators, which exploit the piezoelectric effect in materials like (PZT) ceramics; applying an causes asymmetric charge displacement, resulting in small linear expansions or contractions (typically 0.1-1% , or micrometer-level displacements in stacks) with high blocking forces (up to hundreds of newtons) and extremely fast response times (sub-millisecond). They excel in ultraprecision applications such as , optical alignment, and active . The operation of electromagnetic subtypes relies on the , expressed as F = B I L \sin \theta, where F is the force, B the , I the , L the , and \theta the angle between the and ; this governs the of electrical input to in motors and solenoids. Efficiency in these actuators varies with design, typically ranging from 70-90% for motors, where applied voltage determines speed while influences , though higher loads reduce overall due to increased electrical and losses. Electrical actuators provide advantages in , where sub-millimeter accuracy is achievable through electronic modulation, and ease of via programmable interfaces like microcontrollers, facilitating seamless integration into automated systems without complex fluid handling. However, disadvantages include heat generation from resistive losses in coils and windings, which can limit continuous operation and require cooling, as well as vulnerability to that may disrupt in nearby . For enhanced performance, integration often involves for positioning, where proportional, integral, and derivative terms adjust voltage to minimize error in setups paired with gearboxes; the gearbox amplifies (e.g., by a factor of 10-100) at the cost of speed, enabling fine in applications like robotic arms.

Thermal Actuators

Thermal actuators generate mechanical motion by leveraging thermal expansion or phase transitions in materials triggered by temperature changes. These devices exploit the principle that certain materials deform predictably when heated or cooled, converting thermal energy into useful work without requiring continuous external mechanical input during the actuation phase. Common mechanisms include differential thermal expansion in composite structures, volume changes during phase transitions, and reversible phase transformations in alloys. One fundamental mechanism is the , which consists of two bonded metal layers with differing coefficients of (CTE), such as and . Upon heating, the metal with the higher CTE expands more, causing the strip to bend due to the differential expansion, approximated by \delta = (\alpha_1 - \alpha_2) \Delta T L, where \alpha_1 and \alpha_2 are the CTEs, \Delta T is the temperature change, and L is the strip length. This bending can displace components or open/close contacts in simple devices. Bimetallic strips exhibit relatively linear responses with minimal , making them reliable for moderate temperature ranges up to several hundred degrees . Wax-based actuators operate via the change of or similar materials from to , which induces a significant volume increase—typically 10-15%—that pushes a or to generate . Encased in a sealed chamber, the expands upon reaching its (around 50-80°C, depending on formulation), providing high force output over strokes of several millimeters. The reverse process occurs during cooling, contracting the and resetting the actuator, though this introduces in the temperature-response curve due to effects in the . Shape-memory alloys (SMAs), such as nickel-titanium (Nitinol), function through a solid-state between (low-temperature, deformable phase) and (high-temperature, rigid phase). Heating above the austenite start temperature (typically 30-100°C) triggers the alloy to revert to its pre-deformed shape, producing strains up to 8% and recovery forces exceeding 500 . The response curve shows pronounced , with the transformation temperatures differing between heating and cooling cycles by 10-50°C, arising from the energy barriers in the martensite- interface propagation. Often paired with electric sources for precise , SMAs enable compact, high-force actuation. The primary advantages of thermal actuators include their structural simplicity, low cost, and ability to operate without ongoing power once triggered, relying solely on ambient or applied for motion. They can produce substantial forces relative to , as seen in bimetallic strips generating torques up to 0.1 and wax actuators delivering over 100 . However, disadvantages encompass slow response times—often seconds to minutes due to —limited actuation cycles (e.g., 10^4-10^6 for SMAs before ), and sensitivity to ambient conditions, which can cause unintended actuation or drift. Applications are prominent in thermostats, where bimetallic strips regulate by snapping contacts, and in basic valves for heating systems, such as wax-driven controls that modulate flow based on ambient .

Magnetic and Soft Actuators

Magnetic actuators operate by leveraging to induce motion in ferromagnetic or conductive materials, building on electromagnetic principles for precise . Reluctance actuators extend this concept by exploiting the tendency of ferromagnetic materials to minimize , producing non-contact motion suitable for high-precision positioning. In these devices, an generates a field that aligns a movable ferromagnetic element to complete the with minimal air gap, yielding high forces over short strokes—often exceeding 100 N for gaps under 1 mm—without physical contact, thus reducing and enabling vacuum-compatible operations. Soft actuators, in contrast, employ compliant materials to achieve flexible, biomimetic motion, diverging from rigid structures. Dielectric elastomer actuators (DEAs) function via electrostatic forces, where an applied voltage across a thin induces Maxwell \sigma = \epsilon E^2, with \epsilon as the and E as the , causing in-plane expansion or out-of-plane deflection up to 100% . This enables lightweight, silent operation in , such as crawling or gripping. Pneumatic soft , fabricated from like Ecoflex, use pressurized air to inflate interconnected chambers, mimicking for adaptive grasping of irregular objects with forces around 1-5 N per finger. Magnetic actuators offer advantages in wireless control through external fields, allowing remote manipulation without onboard power, ideal for biomedical implants or confined spaces, alongside and penetrability. However, they require shielding to prevent with nearby or tissues, and face limitations in workspace due to decay over . Soft actuators excel in bio-mimicry, enabling safe human interaction and adaptability to unstructured environments via compliant deformation that absorbs impacts. Drawbacks include reduced from under cyclic loading, often limiting lifespan to thousands of cycles, and challenges in precise control due to viscoelastic . Innovations in this domain include (SMA)-magnetic hybrids, such as magnetic shape memory alloys (MSMAs), which integrate magnetic fields to trigger phase transformations in Ni-Mn-Ga crystals, achieving strains up to 6% with response times in milliseconds—far faster than thermal SMAs—while providing positioning accuracy of ±2 µm after compensation. These hybrids enhance actuation speed and for applications in precision valves and .

Applications

Industrial and Manufacturing

In and settings, actuators play a pivotal role in enabling automated processes such as assembly lines, , and precision machining. Hydraulic and pneumatic actuators are commonly employed in high-force applications like stamping presses and robotic arms, where they provide the necessary power to handle heavy loads and repetitive motions. For instance, hydraulic actuators excel in presses due to their high and ability to generate forces exceeding 1000 kN, making them ideal for metal forming and tasks. Electric actuators, on the other hand, are widely used for positioning and indexing systems, offering precise control and in dynamic production environments. Specific examples illustrate their integration in manufacturing workflows. In computer numerical control (CNC) machines, linear actuators drive the axes for tool positioning, ensuring accurate cuts and engravings in materials like metal and composites. Similarly, welding robots utilize servo actuators to achieve high precision in spot welding operations, maintaining consistent electrode force and reducing defects in automotive . These applications highlight how actuators facilitate scalable by allowing modular expansions in production lines without major redesigns. The benefits of actuators in this domain include enhanced for high-volume and the capacity to manage extreme forces, such as those required for pressing operations up to 1000 kN, which outperform manual methods in speed and reliability. However, challenges arise in integrating actuators with programmable logic controllers (PLCs) for synchronized operations, including compatibility issues with communication protocols and the need for robust error-handling to prevent downtime in interconnected systems.

Robotics and Automation

In robotics and automation, actuators play a pivotal role in enabling multi-degree-of-freedom (multi-DOF) robotic arms, which require precise and coordinated motion for complex tasks such as and . Electric servo actuators are commonly employed in these systems due to their high precision, compact design, and ability to provide for closed-loop , allowing independent movement at each . For instance, a seven-DOF robotic arm can utilize brushless servo motors to achieve versatile trajectories while minimizing backlash and ensuring repeatability. A prominent example is the S-6 series, a six-axis that relies on electric servo-driven actuators to deliver consistent high-performance handling in automated environments. These actuators enable the robot to execute multi-joint movements with payloads up to several kilograms, supporting applications like and material transfer. Soft actuators have emerged as essential components in for collaborative robots (s), where adaptability to irregular objects is crucial for safe human-robot interaction. Soft actuators, such as pneumatic ones made from or 3D-printed elastomers, conform to object shapes without rigid fixtures, providing gentle yet secure grasping for delicate items like fruits or electronics. Vacuum-based soft like the OnRobot Soft Gripper exemplify adaptable grasping, using interchangeable cups actuated without external air supplies to handle varied payloads in cobot workflows. In automated guided vehicles (AGVs), serve as integrated actuators to drive and in warehouse settings, extending manufacturing automation to dynamic, mobile platforms. These brushless DC provide high torque and efficiency for payloads up to 400 kg, enabling precise steering and obstacle avoidance through differential drive mechanisms. Nanotec's drives, for example, incorporate gearless for compact, low-maintenance operation in AGV fleets. Key aspects of actuators in these systems include real-time control to ensure responsive and operation amid varying loads. controllers, such as those using sensors in pneumatic soft robots, maintain by adjusting actuator inputs dynamically, achieving latencies under 10 ms. further relies on calculating (DOF), determined by subtracting motion constraints from the total freedoms of rigid bodies—typically six per link in space—to optimize paths and avoid singularities. Since the , a notable trend has been the integration of into robotic actuators, enhancing operator intuition in teleoperated and collaborative systems. This involves embedding sensors and variable-stiffness mechanisms in actuators to tactile cues, such as and , improving task accuracy in virtual and physical interactions. Developments in soft , including pneumatic pouch arrays, have enabled multi-modal feedback for hand-held robots, with adoption growing in applications requiring fine .

Transportation and Aerospace

In automotive applications, electric actuators play a critical role in , where electro-mechanical brakes (EMB) utilize electric motors to precisely control brake pressure and prevent wheel lockup during sudden stops. These systems, which emerged in the , replace traditional hydraulic components with compact electric motors for faster response times and integration with stability controls. Similarly, throttle-by-wire systems, introduced in the late , employ electric actuators to electronically modulate throttle position based on driver input, enabling smoother engine control and reduced emissions without mechanical linkages. Hydraulic actuators remain prevalent in systems, where they amplify steering effort by converting hydraulic pressure into linear force applied to the steering rack, improving maneuverability in vehicles. In aerospace, electrohydraulic actuators are essential for primary flight controls, such as ailerons, which manage aircraft roll by hydraulically positioning control surfaces in response to pilot commands. These actuators combine electrical signaling with hydraulic power for precise, high-force movements under varying aerodynamic loads. Shape-memory alloy (SMA) actuators offer innovative solutions for deployable structures, such as solar arrays or antenna booms, where they provide self-locking deployment mechanisms that recover shape upon heating, eliminating the need for complex motors or pyrotechnics. Notable examples include the system on the , which entered service in 1995 and uses electronic actuators to drive hydraulic servos for all primary flight controls, enhancing stability and reducing pilot workload compared to mechanical systems. In electric vehicles (EVs), actuators facilitate by reversing electric motors to generate torque that captures during deceleration, converting it to for recharge and improving overall efficiency. Actuators in these sectors must demonstrate high reliability to withstand intense vibrations, shocks, and extreme temperatures ranging from -50°C to 100°C, ensuring operation in safety-critical environments. This demands robust performance metrics focused on endurance and to maintain and integrity.

Biomedical and Consumer Devices

In biomedical applications, actuators play a crucial role in enabling precise, minimally invasive procedures and enhancing patient mobility, with a strong emphasis on and to ensure safe interaction with human tissues. Piezoelectric actuators, which convert electrical energy into mechanical motion through the piezoelectric effect, are widely used in surgical tools due to their high precision, fast response times, and compact size. For instance, they power robotic systems for MRI-guided interventions, allowing needle placement with sub-millimeter accuracy without interfering with fields. Similarly, in microsurgery, handheld tools like the Micron employ piezoelectric manipulators to stabilize instruments, providing up to 400 μm of motion range and over 100 Hz bandwidth to reduce surgeon tremor during delicate operations. These actuators must adhere to biocompatibility standards such as , which outlines biological evaluation protocols including and tests to prevent adverse tissue reactions in implantable or contact devices. Haptic actuators in prosthetic devices further advance by providing sensory that mimics natural touch, improving user dexterity and control in upper-limb prosthetics. These actuators deliver vibrations or cues to simulate grasping forces, as seen in multichannel systems that use pneumatic or vibrotactile to convey tactile from the prosthetic hand to the user's residual limb. The DEKA Arm, developed in the under the DARPA Revolutionizing Prosthetics program, integrates multiple actuators for powered motion across 10 , with later enhancements incorporating haptic to enable intuitive object manipulation and reduce during daily tasks. Low-power operation is essential here, with actuators consuming under 5 to extend battery life in wearable prosthetics, aligning with the need for prolonged, untethered use in biomedical settings. In consumer devices, actuators enhance user interaction through subtle, energy-efficient feedback, prioritizing seamless integration into everyday wearables and gadgets. Vibration motors, typically eccentric rotating (ERM) or linear resonant actuators (LRA), are standard in smartphones to produce haptic notifications that alert users without visual or auditory cues. ERMs generate broad vibrations via an unbalanced rotor on a , while LRAs offer sharper, more precise pulses through electromagnetic , improving the tactile quality of alerts in modern devices. Soft actuators, often pneumatic or elastomer-based, are increasingly employed in wearables for gesture control, enabling flexible interfaces that conform to the body and respond to hand movements with minimal rigidity. These systems leverage flexible materials for human-like interaction, supporting applications like motion-tracking sleeves that detect and amplify gestures for intuitive control in setups. Specific examples illustrate the versatility of actuators in bridging biomedical and consumer realms. Linear actuators drive insulin pumps by precisely advancing syringe plungers for controlled insulin delivery, ensuring accurate dosing with minimal power draw to support portable, patient-managed therapy. In (VR) gloves, pneumatic actuators provide immersive haptic feedback by inflating soft pouches against the fingers, simulating textures and forces for realistic object interaction in training simulations or gaming. remains a key consideration for skin-contact wearables, with compliance verifying non-toxicity and skin irritation potential, while low-power designs—often below 5 —extend usability in battery-constrained consumer products without compromising performance.

Performance Metrics

Force and Torque

In actuators, force and torque represent the primary output metrics quantifying the mechanical power delivered to perform work. For linear actuators, output is expressed as force in newtons (N), which measures the push or pull capability along a straight path. For rotary actuators, torque is used instead, quantified in newton-meters (Nm), serving as the rotational equivalent of linear force by describing the twisting effect around an axis. Stall force or torque denotes the maximum output achievable when the actuator's motion is fully arrested (zero velocity), marking the threshold beyond which the device risks overheating, structural failure, or inability to overcome the load. Measurement of these outputs typically involves specialized sensors integrated into testing setups. Load cells, which convert applied force into an electrical signal via strain gauge deformation, are standard for quantifying linear force in actuators, offering high accuracy across , , and modes. For in rotary systems, dynamometers employ similar principles, often combining load cells with rotational elements to capture twisting forces while the actuator operates under controlled conditions. In electrical actuators, output force or directly correlates with input parameters, such as current in DC motors, where is linearly proportional to armature current due to the interaction of and rotor conductors. Several factors influence the generation and effective delivery of and . Gear s in geared actuators amplify output torque proportionally to the (τ_output ≈ G × τ_motor, where G > 1 is the gear reduction), enabling compact motors to handle high loads by trading speed for strength, though this assumes ideal conditions without backlash. losses arise from , heat, and meshing imperfections in these , typically reducing transmitted power by 5-10% per stage, with higher ratios (e.g., >10:1) exacerbating cumulative losses up to 20-30% overall. These elements ensure actuators meet diverse load requirements while maintaining system integrity. Benchmarks illustrate the wide range of capabilities across actuator types, establishing scale for practical applications. Hydraulic actuators excel in high-force scenarios, routinely achieving outputs up to 10^5 N (100 kN) or more in industrial presses and heavy machinery, leveraging fluid pressure for superior . In contrast, piezoelectric actuators operate at precision scales, generating forces from micro-Newtons (10^{-6} N) in to several kilo-Newtons in stacked configurations for and vibration control.

Speed and Response Time

Speed and response time are critical performance metrics for actuators, quantifying how rapidly they initiate, accelerate, and stabilize motion in response to inputs. Key measures include maximum , typically expressed in linear units as meters per second (m/s) or angular units as radians per second (rad/s), which indicates the peak speed achievable under load; , defined as the duration for the output to transition from 10% to 90% of its final value in a ; , representing the frequency range (in hertz, Hz) over which the actuator maintains effective without significant ; and , the interval required for the output to remain within a specified (often 2-5%) of the value following a disturbance or command change. These metrics are influenced by factors such as system , which resists changes in motion and limits , and , which controls oscillations but can reduce responsiveness if excessive. For instance, higher inertia increases the time to reach peak , while damping affects the overshoot and ringing in dynamic responses. Pneumatic actuators excel in high-speed applications, achieving velocities typically up to 0.5 to 2 m/s due to rapid air compression and release, with response times often in the range of 0.5 to 1 second for operations. In contrast, thermal actuators, reliant on heat-induced expansion or phase changes, exhibit slower responses, with rise times ranging from milliseconds in microscale electrothermal designs to several seconds in larger systems, limited by thermal diffusion times. Acceleration, a core component of response dynamics, is fundamentally calculated as a = \frac{F}{m}, where a is acceleration, F is the net force generated by the actuator (constrained by its torque or force limits), and m is the effective mass or inertia of the moving components. This relationship highlights how actuator design must balance force output with load inertia to optimize speed. In control systems, settling time is particularly important for precision tasks, often targeted below 1 second in servo applications to ensure quick stabilization without prolonged error. Testing these metrics typically involves step response analysis using an to capture voltage or position traces, revealing , overshoot, and settling behavior under controlled inputs like square waves. For example, in actuators, oscilloscope evaluation of switching signals assesses up to hundreds of Hz, while for linear systems, traces differentiate between inertial delays and damping effects. is verified through frequency sweeps, ensuring the actuator handles inputs up to 50-500 Hz in high-performance designs without phase lag exceeding margins.

Efficiency and Durability

Efficiency in actuators is defined as the ratio of useful mechanical output work to the total input energy, typically expressed as a percentage: \eta = \frac{W_{\text{out}}}{E_{\text{in}}} \times 100\%. This metric quantifies how effectively an actuator converts input energy—such as electrical power in motors—into desired motion, with losses primarily arising from friction in mechanical components and heat generation in electrical elements. For electric motors commonly used in actuators, efficiencies range from 70% to 96%, depending on size, load, and design; for instance, NEMA Design B motors achieve 78.8% minimum at 1-4 hp and up to 92.4% for larger units above 125 hp. Durability refers to an actuator's ability to maintain performance over extended operation, often measured by cycle life—the number of operational cycles before failure—and (MTBF), which estimates average operational time between breakdowns. actuators, for example, typically exhibit cycle lives of 10 million to 50 million under ideal conditions, while material fatigue in components like springs or linkages can limit overall lifespan through progressive cracking under repeated . Key factors influencing durability include to minimize friction-induced , overload protection mechanisms such as thermal sensors in motor windings or torque limiters to prevent excessive , and enclosure ratings like IP codes (e.g., IP67 for dust-tight and water immersion resistance up to 1 meter), which shield internals from contaminants that accelerate . Advancements in design, such as brushless DC motors in linear actuators, significantly enhance by eliminating brush wear, extending cycle life up to 10 times compared to brushed counterparts—often reaching 10 million cycles or more—while reducing maintenance needs and improving overall reliability.

Operating Conditions

Actuators must operate reliably across a range of environmental conditions, including extremes, , exposure, and mechanical stresses like and . Typical ranges for many industrial and commercial actuators span from -40°C to 150°C, though specialized designs can extend to cryogenic levels down to -230°C or higher temperatures up to 200°C in demanding applications. Humidity and ingress are mitigated through Ingress (IP) ratings, with IP65 or higher commonly required for protection against and low-pressure jets, ensuring functionality in moderately contaminated or moist environments. and tolerances often include resistance to accelerations up to 10g, as specified in testing protocols for ruggedized systems. Environmental factors can significantly impact actuator performance; for instance, due to temperature variations alters dimensional tolerances, potentially leading to misalignment or reduced in assemblies. In pneumatic actuators, exposure to high accelerates of metal components, compromising seals and internal structures over time. These effects influence overall lifecycle by accelerating wear, though proper adaptations can extend operational reliability. To counter these challenges, actuators incorporate sealed designs such as IP67-rated enclosures to prevent contaminant ingress, alongside systems like liquid-cooled variants for in high-temperature settings. Compliance with standards like ensures testing for environmental resilience, including shock, vibration, and thermal cycling. Selection of actuators involves matching these capabilities to specific applications; for example, cryogenic-compatible designs using shape memory alloys are chosen for missions to handle extreme low temperatures without performance degradation.

References

  1. [1]
    Definitions | NIST - National Institute of Standards and Technology
    Oct 6, 2009 · An actuator is a transducer that accepts a signal and converts it to a physical action. In other words, an actuator causes an action to occur ...
  2. [2]
    actuator - Glossary | CSRC - NIST Computer Security Resource Center
    An actuator is the mechanism by which a control system acts upon an environment. The control system can be simple (a fixed mechanical or electronic system), ...
  3. [3]
    CSC 297 Robot Construction: Actuators
    Actuators are the generators of the forces that robots employ to move themselves and other objects.
  4. [4]
    [PDF] actuators - NSF Public Access Repository
    Apr 20, 2023 · The components of a pneumatic actuator include a primary motor, compressor unit, air storage tank, delivery network housing, and actuator.
  5. [5]
    Actuators — 16-223 Creative Kinetic Systems
    An actuator is a component which transduces energy into motion. Our basic actuators include electric motors, hobby servos, and solenoids. The term generally ...Missing: definition | Show results with:definition
  6. [6]
    Actuators - Visual Encyclopedia of Chemical Engineering Equipment
    Apr 6, 2022 · General Information. Two common types of mechanical actuators are machine screw and ball screw actuators.
  7. [7]
    [PDF] Status of Electrical Actuator Applications
    The fail safe operational requirements of many actua- tion systems leads to unique redundancy issues for EAs. It is the management of the different.
  8. [8]
    Soft actuators for real-world applications - PMC - NIH
    Nov 10, 2021 · Fluidic soft actuators, which are the most prevalent soft actuator type, work by controlling the fluid pressure inside the hollow channels of ...<|control11|><|separator|>
  9. [9]
    What Is An Actuator - Types and Applications - Tameson.com
    Feb 10, 2023 · An actuator is a device that receives an energy input and converts it into motion or force and is an essential component in many modern technologies and ...
  10. [10]
    What is an actuator? - Find definition, types, and more here
    An actuator is a machine that moves or controls components in a system by converting energy into physical motion.
  11. [11]
    Actuation - an overview | ScienceDirect Topics
    An actuator is defined as a mechanical device that creates physical movement within a system, utilizing various operating principles, including hydraulic, ...
  12. [12]
    What Is a Linear Actuator? Types, Applications & Selection Guide
    A linear actuator is a mechanical component that converts energy into straight-line movement, allowing you to push, pull, lift, or position loads. How to ...What Is An Actuator? · Micro Actuators · Tubular Actuators
  13. [13]
    Chapter 10: Actuators - Engineering Library
    An actuator is a device that converts fluid power into mechanical force and motion. Cylinders, motors, and turbines are the most common types of actuating ...
  14. [14]
    Difference Between Industrial Actuators and Motors | JHFOSTER
    Think of actuators as devices that help produce linear motion and motors as devices that help produce rotational movement.
  15. [15]
    HVAC – What's the Difference Between A Motor & Actuator?
    Oct 7, 2015 · The term “Actuator” typically refers to a device that provides linear motion… like a piston, a rod is pushed in a linear manner when voltage is ...
  16. [16]
    [PDF] ELECTROMECHANICS, ACTUATORS - UT Computer Science
    Characterizing actuators: torque- speed diagram. • Types of actuators. • Next up: How do we control actuators?
  17. [17]
    Chapter 13. What are Dynamics and Control?
    Robots are able to apply forces and otherwise alter the rate of change of the state using their actuators. ... Newton's laws under the second-order ...
  18. [18]
    [PDF] The effect of series elasticity on actuator power and work output
    We show that an appropriate spring constant increases the energy that an actuator can deliver to a mass by a factor of 4. The series elasticity changes the ...
  19. [19]
    [PDF] Introduction to Control Engineering - LSU Scholarly Repository
    Jan 12, 2023 · A control system consists of four major components: process, sensor, controller and actuator. The process combined with the actuator is called.
  20. [20]
    [PDF] Hybrid Position/Force Control of Manipulators1 - MIT
    The "hybrid" technique described combines force and torque information with positional data to satisfy simultaneous position and force trajectory constraints ...
  21. [21]
    Lift Water with an Archimedes Screw | Scientific American
    Jul 11, 2019 · The ancient Greeks discovered how to do just this! They developed a device called the Archimedes screw to lift water from one location to another.Missing: actuator | Show results with:actuator<|separator|>
  22. [22]
    Archimedean Screw - an overview | ScienceDirect Topics
    The Archimedean screw has been known and used from antiquity as a pump, to raise water and more recently in sewage treatment installations, to relatively low ...
  23. [23]
    [PDF] A Bulleted/Pictorial History of Mechanisms and Machines
    In 1782 James Watt (1736 – 1819) invented the six-bar Watt's linkage to convert rotational shaft motion into translating motion. He was a Scottish inventor, ...
  24. [24]
    [PDF] Topic 4 Linkages - FUNdaMENTALS of Design
    Jan 1, 2008 · The birth of the modern history of linkages is often associated with James Watt who some say invented the steam engine; however, it was not ...
  25. [25]
    JOSEPH BRAMAH - IMechE Archive and Library
    Dec 11, 2017 · Bramah was granted a patent for his hydraulic press in 1795. The press had two cylinders and pistons of different cross-sectional areas.
  26. [26]
    History of the Hydraulic Press | The Werks C&C Inc.
    The individual who is credited with inventing the first hydraulic press is Joseph Bramah. He applied and received his patent in 1795 for the Bramah Hydraulic ...
  27. [27]
    Faraday Motor – 1821 - Magnet Academy - National MagLab
    Self-taught British scientist Michael Faraday (1791 – 1867) built the first primitive motor about 1821, shortly after the discovery that an electric current ...Missing: actuators | Show results with:actuators
  28. [28]
    200 Years Ago, Faraday Invented the Electric Motor - IEEE Spectrum
    Aug 27, 2021 · Michael Faraday created this model of his electric motor in 1822, a year after his discovery. Royal Institution of Great Britain/Science Source.Missing: actuators | Show results with:actuators
  29. [29]
    The History of Solenoid Valves
    Sep 29, 2020 · The first Solenoid Valves were invented and manufactured in 1910 by Automatic Switch Company (ASCO). These valves went hand-in-hand with the ...
  30. [30]
    [PDF] Nicolas Minorsky and the Automatic Steering of Ships - Robotics
    Almost from the first introduction of the servo-controlled steering systems in 1864, thought was given to the provision of fully automatic steering: the ...
  31. [31]
    The History of Hydraulics in the Aerospace Industry - Domin
    Jul 10, 2024 · The widespread use of hydraulics in aircraft started during World War II when significant advances in aircraft hydraulic technology were made.
  32. [32]
    https://domin.com/blog/the-history-of-hydraulics-in-aerospace/
  33. [33]
    Nickel-Titanium Shape Memory Alloys - AZoM
    Apr 19, 2002 · Although the first shape memory alloy was discovered in 1932, the nickel-titanium SMAs were first discovered by Buehler only in the early 1960s.
  34. [34]
    Dielectric Elastomer Actuator for Soft Robotics Applications and ...
    This paper reviews state-of-the-art dielectric elastomer actuators (DEAs) and their future perspectives as soft actuators which have recently been considered ...
  35. [35]
    A review of NiTi shape memory alloy as a smart material produced ...
    Already in the late 1960s, Nitinol was first used for practical use in the aircraft industry - a clutch for thermomechanical connection of pipelines of ...
  36. [36]
    https://www.sciencedirect.com/science/article/abs/pii/S2214785320306738
  37. [37]
    AI and the Future of the Actuators Industry - MarketsandMarkets
    Apr 23, 2025 · The integration of AI allows these actuators to recognize complex patterns, enabling predictive responses rather than reactive controls. For ...
  38. [38]
    [PDF] Topic 5 Power Transmission Elements I - FUNdaMENTALS of Design
    Jan 1, 2008 · Chapter 6 will discuss screws and gears. Chapter 7 will discuss selection of optimal transmission ratios and actuators that use the elements in ...
  39. [39]
    [PDF] Basic Mechanical Systems for Manufacturing Technicians
    Basic Mechanical Systems introduces mechanism concepts and their importance in industrial, commercial, and residential applications.
  40. [40]
    [PDF] Understanding Linear Actuators
    Ballscrews are also much more efficient than leadscrews. Advantages of using screw drives are high thrust capacity, high accuracy, and high mechanical advantage ...
  41. [41]
    [PDF] Evaluating Strategies to Mitigate Jamming in Electromechanical ...
    EMA ballscrew jamming (a single point of failure) has been identified as a major factor in preventing EMAs from being more thoroughly considered as an actuator ...
  42. [42]
    [PDF] Analysis and Design of a Gear Shifting Mechanism for Transmission ...
    Mechanical: This is the simplest, least costly way to engage a clutch or brake. Actuation is by rods, cables, levers, or cams. Besides cost, a major.Missing: screws | Show results with:screws
  43. [43]
    Pascal's Principle and Hydraulics
    Pascal's law states that when there is an increase in pressure at any point in a confined fluid, there is an equal increase at every other point in the ...
  44. [44]
    [PDF] Chapter 9 Hydraulic and Pneumatic Systems
    Pascal's law states that pressure applied to a confined liquid is transmitted undiminished in all directions and acts with equal force on all equal areas, at ...
  45. [45]
    [PDF] WisDOT Structure Inspection Manual - Chapter 7 Hydraulic Systems
    In a closed loop circuit design a single hydraulic pump is used to drive one or more hydraulic motors. The closed loop circuit is not viable for hydraulic ...
  46. [46]
    [PDF] Principles of Small-Scale Hydraulic Systems for Human Assistive ...
    The high power and force density of hydraulic actuators, along with the ability to distribute system weight through the separation of the power supply and ...
  47. [47]
    [PDF] Introduction To Hydraulics And Pneumatics
    Pascal's Law states that when pressure is applied to a confined fluid, the pressure change occurs throughout the fluid equally in all directions, which is the ...
  48. [48]
    [PDF] Development of a hydraulic component leakage detecting system ...
    Contrary to so many advantages mentioned earlier, there are also some disadvantages. The hydraulic system has higher requirements for maintenance compared with ...
  49. [49]
    "The Controlled shutdown of a hydraulic servo-system using ...
    Hydraulic servoactuators have long been used in industry where high performance precision motion control is required. Because of their precision and ability ...
  50. [50]
    Pneumatic Actuators Explained: Types and Working Principle
    Common Drawbacks · Limited Precision & Load Capacity The compressibility of air reduces positional accuracy, especially for fine modulation or tight tolerances.Missing: Boyle's law
  51. [51]
    [PDF] FLUID POWER CONTROL Second Edition
    to the volume which leads to Boyle's law: P1V1 = P2V2. (2.3). ˆ If a ... Draw a pneumatic circuit for pneumatic actuators and valves used to open and ...
  52. [52]
    Pneumatics - Industrial Solutions Lab - UNC Charlotte
    Vane Motor: a rotary actuator​​ Air enters from the inlet, causing the rotor to rotate, producing torque. The air is then discharged from the exhaust port ( ...
  53. [53]
    Comparison of hydraulic, pneumatic and electric linear actuation ...
    Nov 28, 2023 · Different applications or industries use different systems for linear actuation, such as hydraulic, pneumatic or electric.
  54. [54]
    DC Motors and Stepper Motors used as Actuators
    Electrical DC Motors are continuous actuators that convert electrical energy into mechanical energy. The DC motor achieves this by producing a continuous ...
  55. [55]
    Moog Electrohydraulic Servo Actuators
    Moog is the premier manufacturer of electrohydraulic actuators for Industrial, Aerospace, and Defense applications.
  56. [56]
    Voice Coil Actuators - Thorlabs
    These linear actuators use a bobbin and magnet assembly to provide linear force without contact between the moving and fixed world. The voice coil converts ...
  57. [57]
    Rotary Actuators - Moog Inc.
    Moog rotary servo actuators use brush and brushless type DC motors with both neodymium and rare earth magnets for high-power performance. Learn more.
  58. [58]
    Lorentz force | Equation, Properties, & Direction - Britannica
    Sep 16, 2025 · Lorentz force, the force exerted on a charged particle q moving with velocity v through an electric field E and magnetic field B.
  59. [59]
    AB-032: DC Motors – Voltage Vs. Output Speed Vs. Torque
    The relationship between voltage, torque and output speed is a common topic of discussion between our customers and Precision Microdrives' sales engineers.Dc Motors -- Voltage Vs... · Why Change Torque? · Motor Catalogue
  60. [60]
    Advantages and Disadvantages of Actuators | JHFOSTER
    The Advantages of Electric Actuators ... Electric actuation tends to be your best choice when your application requires speed, accuracy, flexibility, and control.
  61. [61]
    Electric Actuators: Advantages and Disadvantages - T&M World
    This article explores the benefits and drawbacks of electric actuators, including their precision, cost, and environmental sensitivity.
  62. [62]
    https://jhfoster.com/automation-blogs/what-are-the-advantages-and-disadvantages-of-using-electric-actuators/
  63. [63]
    [PDF] Techniques in the Design of Thermomechanical Microactuators
    Many early thermal microactuators were bimetallic devices that fused together mate- rials with different coefficients of thermal expansion. This is similar to ...
  64. [64]
    Thermal Bending Analysis Equations
    L = free deflection length in inches. t = thickness of strip in inches. 100 pixel whitespace. Gieck's Design Formulas for BiMetallic Strips. Gieck, Kurt and ...
  65. [65]
    [PDF] Introduction to Actuators - SCME-support.org
    One type of thermal actuator is a bimetallic strip, a strip made from two different metals such as steel and copper. The two metals have different temperature ...
  66. [66]
    Thermal Actuators - MAS.865
    A very common version of this actuator uses the phase-change behaviour of wax. Essentially, the actuator simply consists of an enclosed volume of wax, a plunger ...
  67. [67]
    Feasibility of Using Phase Change Material in Photovoltaic Panels ...
    Paraffin actuators utilize the volume change associated with the wax phase transformation from solid to liquid to deliver both a large stroke and a high force. ...
  68. [68]
    [PDF] Shape Memory Alloys – Not Your Ordinary Metal
    It includes the thermal expansions of martensite and austenite as well as the phase transformation strain. eact = eLCT - eUCT. 7. austenite 50% (A50) ...
  69. [69]
    [PDF] THERMAL ACTUATION, A SUITABLE MECHANISM FOR HIGH ...
    In addition, thermal actuators have great properties such as large actuation force, low operating voltage and simplicity of design and integration. On the ...
  70. [70]
    [PDF] CYCLIC FATIGUE TESTING OF SURFACE-MICROMACHINED ...
    The main disadvantage of thermal actuators is their large power consumption -- at full displacement, our actuators required approximately 22 mW. The power is ...
  71. [71]
    [PDF] Thermostatic Radiator Valve Evaluation - eere.energy.gov
    Jan 5, 2015 · Thermostatic radiator valves (TRVs), which have been in use for many decades, are one strategy to combat this problem. They are commonly used ...
  72. [72]
    [PDF] DESIGN OF MAGNETIC ACTUATOR - IJRET
    Proportional solenoid valve designed in find out the magnetic force (N), magnetic field intensity (A/m), magnetic flux density (Tesla or wb/m2).
  73. [73]
    Recent progress on modeling and control of reluctance actuators in ...
    Reluctance actuators (RA) are a type of electromagnetic actuator that offers high forces for short-range motions. The RA takes advantage of the ...
  74. [74]
    Modeling and analysis of reluctance motion system ... - AIP Publishing
    Jul 11, 2022 · One available solution is the reluctance actuator, which provides higher acceleration and force output than the standard Lorentz actuator. A ...
  75. [75]
    Recent Advances in Dielectric Elastomer Actuator-Based Soft Robots
    σ = ε 0 ε γ U t 2. (1). where σ is the Maxwell stress, ε 0 is the vacuum dielectric constant, ε γ is the dielectric constant of the dielectric elastomer ...Missing: εE² | Show results with:εE²
  76. [76]
    Comparison of Different Technologies for Soft Robotics Grippers - NIH
    May 8, 2021 · In general, they have deformable pneumatic chambers realized with different types of silicone or other elastomers. What distinguishes them ...
  77. [77]
    Multifunctional origami magnetic-responsive soft actuators with ...
    ... magnetic field (Bm). For magnetic actuation, obvious advantages including remote control, strong penetrability, and biocompatibility can be achieved ...
  78. [78]
    Design, Control, and Clinical Applications of Magnetic Actuation ...
    Aug 11, 2024 · The disadvantages of magnetic actuation are limited workspace, restricted magnetic flux density for actuation, and the bulk and expense of the ...
  79. [79]
    Biology and bioinspiration of soft robotics: Actuation, sensing, and ...
    Sep 24, 2021 · Here, the actuation and sensing strategies in the natural biological world are summarized along with their man-made counterparts applied in soft robotics.
  80. [80]
    Design and Control of Magnetic Shape Memory Alloy Actuators - PMC
    Jun 22, 2022 · This paper presents research on the application of magnetic shape memory alloys (MSMAs) in actuator design.
  81. [81]
    Pros & Cons of Hydraulic, Pneumatic, & Electric Linear Actuators
    Oct 14, 2025 · -They are most commonly found in heavy-duty applications like construction, aerospace, and industrial presses, where high force is required.Missing: manufacturing | Show results with:manufacturing
  82. [82]
    EWELLIX High-Performance Actuators - Schaeffler medias
    These products offer very high positioning accuracy and controllability, enabling precise motion control with loads from few kilos up to 50 tons. Whether your ...
  83. [83]
    Electric Actuators: Revolutionizing Automation in Manufacturing
    Jan 20, 2025 · Electric actuators are changing the landscape in manufacturing. By offering precision, speed, energy efficiency, and lower operating costs.
  84. [84]
    Hydraulic vs. Pneumatic vs. Electric Actuators | Differences
    Typically, actuators are key parts in industrial and manufacturing operations where they activate valves, pumps, motors and switches. Actuators usually control ...
  85. [85]
    https://yorkpmh.com/resources/hydraulic-vs-pneumatic-vs-electric-actuators/
  86. [86]
    Electric servo actuators and welding robots build better autos faster
    Mar 8, 2018 · Precise positioning–Robots are programmed to deliver welds exactly at specific locations. Consistency–Robots deliver high-quality welds at the ...
  87. [87]
    Servo welding actuators improve weld quality, reduce costs
    Nov 3, 2015 · Electric servo welding actuators can help reduce costs and improve weld quality with shorter cycle times and exact weld tip pressure.
  88. [88]
    What Is an Industrial Actuator? | CoreTigo
    Hydraulic actuators offer excellent power density and can generate immense forces because they use liquid under pressure. They excel in heavy-load applications ...Electric Actuators · Hydraulic Actuators · Pneumatic Actuators
  89. [89]
    https://www.coretigo.com/glossary/industrial-actuators/
  90. [90]
    Guide to Industrial Automation Troubleshooting | CTI Electric
    Unexpected Compatibility Issues – Legacy system integration challenges can arise when older equipment struggles to communicate with new PLCs or control software ...
  91. [91]
    2.2. Degrees of Freedom of a Robot - Foundations of Robot Motion
    The number of degrees of freedom of a robot is equal to the total number of freedoms of the rigid bodies minus the number of constraints on their motion.
  92. [92]
    A Review of Robotic Arm Joint Motors and Online Health Monitoring ...
    Sep 20, 2024 · A servo motor based on brushless gimbal motors has been designed for a low-cost robot arm with seven degrees of freedom (DOF) [14]. The proposed ...
  93. [93]
    Fanuc S-6 Robot - Robots.com
    The Fanuc S-6 is a six-axis, modular construction, electric servo-driven robot that provides consistent high performance.Missing: actuators | Show results with:actuators
  94. [94]
    3D-Printed soft pneumatic actuators: enhancing flexible gripper ...
    Jun 20, 2025 · Soft actuators can adapt to the shape and size of objects, ensuring a secure grip without requiring precise positioning, which is especially ...
  95. [95]
    https://robomechjournal.springeropen.com/articles/10.1186/s40648-025-00314-5
  96. [96]
    Motors and Drives for Automated Guided Vehicles (AGV) - ElectroCraft
    ElectroCraft wheel drive systems are designed for Automated Guided Vehicles which require efficient, durable high torque for long-term reliable performance.
  97. [97]
    Wheel drives for service robots | For AGVs & AMRs - Nanotec
    Innovative wheel drives and wheel hub motors from Nanotec offer efficiency & precision for service robots & automated guided vehicles (AGVs).
  98. [98]
    Stable Real-Time Feedback Control of a Pneumatic Soft Robot
    This paper presents a real-time feedback controller for soft robots, using a limited number of actuators, and shows it preserves the stabilizing property.
  99. [99]
    Haptic Devices: Wearability-Based Taxonomy and Literature Review
    Sep 7, 2022 · ABSTRACT In the last decade, several new haptic devices have been developed, contributing to the definition of more realistic virtual ...
  100. [100]
    [PDF] Soft, Wearable Robotics and Haptics: Technologies, Trends, and ...
    We discuss considerations arising from human-wearability in soft robotic and haptic systems, and conceptual and practical implications for their design.
  101. [101]
    HaPPArray: Haptic Pneumatic Pouch Array for Feedback in Hand ...
    Abstract—Haptic feedback can provide operators of hand- held robots with active guidance during challenging tasks and.
  102. [102]
    (PDF) Research on Anti-lock Braking System of Electro-mechanical ...
    Aug 6, 2025 · Emb (electro-mechanical brake) uses electric energy as the energy source of the braking system, and uses the motor to drive the actuator to ...
  103. [103]
    Intelligent anti-lock braking system of electric vehicle ... - IOP Science
    Abstract. This article discusses the work of an intelligent anti-lock braking system (ABS), in which electric machines and friction brakes act as actuators.
  104. [104]
    (PDF) Drive-By-Wire Systems In Automobiles - ResearchGate
    The first component of the 'X-by-wire' system introduced to the market was 'throttle-by-wire' from the late 90s to early 2000 (Anwar, 2009) .
  105. [105]
    Hydraulic actuators - Ognibene Power Spa
    A hydraulic cylinder (also known as a hydraulic linear actuator) is a high power density device that converts hydraulic energy into linear motion and ...
  106. [106]
    Mike Ercolano on Electrohydrostatic Actuators - Moog Inc.
    Moog's EHAs were originally designed to replace conventional electrohydraulic actuators used in an aircraft flight control system.<|separator|>
  107. [107]
    Shape Memory Alloys for Aerospace, Recent Developments ... - NIH
    Apr 15, 2020 · Shape memory alloys (SMAs) show a particular behavior that is the ability to recuperate the original shape while heating above specific critical ...
  108. [108]
    [PDF] Design Considerations in Boeing 777 Fly-By-Wire Computers
    In general, the electronics components powered by the L/C/R flight control electrical bus controls the actuation components powered by the L/C/R hydraulic ...
  109. [109]
    Fault-Tolerant Control of Regenerative Braking System on In-Wheel ...
    30-day returnsApr 13, 2020 · In braking procedure, In-wheel motors generate electric braking torque to achieve energy regeneration. The strategy is designed to make sure ...
  110. [110]
    Aerospace Actuators 1: Needs, Reliability and Hydraulic Power ...
    ... Among system requirements while designing a precise electro hydraulic control system, reliability and safety are one of the vital issues especially for ...
  111. [111]
    Piezoelectrically Actuated Robotic System for MRI-Guided Prostate ...
    Piezoelectric motors are one of the most commonly utilized classes of actuators in MRI-guided devices, as they operate on the reverse piezoelectric effect ...
  112. [112]
    Micron: an Actively Stabilized Handheld Tool for Microsurgery - PMC
    The key components are a three-degree-of-freedom piezoelectric manipulator that has 400 μm range of motion, 1 N force capability, and bandwidth over 100 Hz, and ...
  113. [113]
    Use of International Standard ISO 10993-1, "Biological evaluation of ...
    Sep 8, 2023 · This guidance provides clarification and updated information on the use of ISO 10993-1 to support PMAs, HDEs, IDE Applications, 510(k)s, ...Missing: actuators biomedical
  114. [114]
    Multichannel haptic feedback unlocks prosthetic hand dexterity
    Feb 11, 2022 · A pneumatic wristband was designed to deliver haptic feedback by inflating eight independent actuators signaling both vibration and pressure. A ...
  115. [115]
    The DEKA Arm: Its features, functionality, and evolution during the ...
    Oct 22, 2013 · The DEKA Arm is an advanced upper limb prosthesis, not yet available for commercial use. It has functionality that surpasses currently available technology.Missing: haptic | Show results with:haptic
  116. [116]
    Linear actuators for medical applications - Xeryon
    Low power consumption (<5W). Low, safe voltage (<48V). Self-locking, meaning no power needed to hold desired actuator position. Greatly reduced energy ...
  117. [117]
    Vibration Motors - ERMs and LRAs - Precision Microdrives
    Vibration motors include ERMs, which use an unbalanced mass on a DC motor, and LRAs, which use a spring and internal mass. ERMs are also known as 'pager'  ...
  118. [118]
    Soft Sensors and Actuators for Wearable Human–Machine Interfaces
    Feb 5, 2024 · In this Review, we discuss the latest technological advances of soft sensors and actuators for the demonstration of wearable HHMIs.
  119. [119]
    How Helix Linear Supports the Medical Device Industry
    Why It Matters: Reliable dosing ensures patient safety and improves treatment outcomes. Example: Helix Micro Precision Linear Actuators driving syringe plungers ...
  120. [120]
    Pneumatic actuator and flexible piezoelectric sensor for soft virtual ...
    Jul 18, 2019 · Without additional equipment, this glove senses and transmits hand movements and provides haptic feedback. The mounted actuator is flexible and ...
  121. [121]
    ISO 10993-1:2018 - Biological evaluation of medical devices — Part 1
    In stock 2–5 day deliveryThis document specifies the general principles governing the biological evaluation of medical devices within a risk management process.Missing: actuators | Show results with:actuators
  122. [122]
    Back to Basics: Bandwidth and Rise Time - Signal Integrity Journal
    May 14, 2018 · If we want a rough measure of the highest frequency components in a signal, it is about 0.35 divided by its 10-90 rise time.Missing: actuator | Show results with:actuator
  123. [123]
    Relationship Between Rise Time and Bandwidth for a Low-Pass ...
    Rise time is measured with respect to time, while 3 dB bandwidth is measured with respect to electrical frequency. Rise time is the time separating two points ...Missing: actuator velocity
  124. [124]
    FAQ: What is settling time in a motor-driven servo system?
    Feb 15, 2016 · The time the system takes to achieve and maintain a specified range (typically 2 – 5%) around the commanded value is known as settling time.
  125. [125]
    Electric vs. Pneumatic Valve Actuators
    Faster operating speeds. They have some of the fastest movement speeds of all actuators (up to 10 m/s). These valve actuators are commonly ...Missing: thermal | Show results with:thermal
  126. [126]
    [PDF] TECH NOTE: CALCULATING MAX ACCELERATION FOR EXLAR ...
    Maximum acceleration is dependent on the Inertia of all moving components. Inertia is a conversion factor that determines how much torque is required to ...
  127. [127]
    Controlling the actuator with 5,10 mm displacement input. - MathWorks
    Oct 11, 2024 · Consequently, a PID controller is tuned to achieve a settling time of approximately 1 second. Now, the closed-loop system can track the ...
  128. [128]
    Stepper motor | Automotive oscilloscope test
    The purpose of this test is to evaluate the correct operation of the stepper motor based on the switching voltage and frequency present at each individual ...
  129. [129]
    How to measure step response of second order passive filter on ...
    Jan 6, 2018 · Connect an oscilloscope to the output. Adjust the frequency of the square wave so that the signal observed on the 'scope has "settled down" ...Missing: actuator | Show results with:actuator
  130. [130]
    Frequency Response Measurements with Oscilloscope - DigiKey
    Aug 25, 2022 · Use an oscilloscope with a square wave's fast edge, differentiate it to get an impulse, then use FFT to measure frequency response. This avoids ...
  131. [131]
    Electric Motors - Efficiency - The Engineering ToolBox
    Calculate electric motor efficiency. Electrical motor efficiency is the ratio between shaft output power - and electrical input power.Missing: definition work 70-90%
  132. [132]
    Motor Efficiency - an overview | ScienceDirect Topics
    Motor efficiency varies between 70 and 96% [1]. The portion of electric energy that is not converted to mechanical power is converted to heat, which is mostly ...
  133. [133]
    What is Mean Time Between Failure MTBF? [Calculation & Examples]
    Mean Time Between Failure (MTBF) is a metric that defines the average time that equipment is operating between breakdowns or stoppages.Mtbf Vs Mttf · How To Improve Mtbf · How To Relate Mtbf To System...Missing: actuator | Show results with:actuator
  134. [134]
    Pneumatic Solenoid Valve Lifespan - MYPC
    Jun 5, 2025 · Our pneumatic solenoid valves are rated to last 10 million to over 50 million cycles if in good working conditions.
  135. [135]
    Calculation of Durability and Fatigue Life Parameters of Structural ...
    The issues of durability and fatigue life of various structural materials occupy an important place in the operation of equipment and elements subjected to ...Missing: solenoid MTBF
  136. [136]
    Automatic Actuator - an overview | ScienceDirect Topics
    When selecting an electric rotary actuator, important factors to consider include actuator torque and range of motion. ... reliability of the protection system.
  137. [137]
    https://upkeep.com/learning/mean-time-between-failure/
  138. [138]
    https://mypneumatic.com/lifespan-for-pneumatic-solenoid-valve/
  139. [139]
    [PDF] www.iai-automation.com
    Service life. (cycles). 10 million cycles. (for horizontal and vertical). Ambient operating temperature; Humidity. –. 0–40°C; 10%–85% RH or less. Note 1: The ...
  140. [140]
    [PDF] The Impacts of Heating Actuators in Extremely Cold Space ...
    Abstract— Conventional, grease-lubricated actuators for space mechanisms can achieve long life but must be heated above about 213 K, or -60 °C, ...
  141. [141]
    Highly Efficient Passive Thermal Micro-Actuator - IEEE Xplore
    The actuator itself is designed to be operated in a temperature range from −50 °C up to +100 °C. This range is determined and limited by the occurring ...Missing: typical | Show results with:typical
  142. [142]
    Enhanced Actuation Performance and Reduced Heat Generation in ...
    The maximum working temperature of this shear-bending actuators is 150 °C higher than those of the traditional piezoelectric actuators based on commercial Pb( ...Missing: typical | Show results with:typical
  143. [143]
    Ingress Protection (IP) ratings - IEC
    The IEC has developed the ingress protection (IP) ratings, which grade the resistance of an enclosure against the intrusion of dust or liquids.
  144. [144]
    Dustproof and waterproof linear actuator's IP Rating - TiMOTION
    Aug 30, 2024 · Electric linear actuators can be customized with different IP protection types. The most common ones are: IP42, IP54, IP66, IP67/IP68, and IP69K.Missing: overload enclosures
  145. [145]
    [PDF] MIL-STD-810H-Method-516.8-Shock.pdf - CVG Strategy
    If the materiel is normally mounted on vibration/shock isolators, ensure the corresponding test item isolators are functional during the test. If the shock ...
  146. [146]
    [PDF] Thermal dilatation in functional tolerancing - HAL
    Thermal expansion impacts clearances and dimensions in functional tolerancing, as temperature changes affect parts and their dimensions. This paper considers  ...
  147. [147]
    [PDF] Selecting Pneumatic Valve Actuators in Corrosive Environments
    This paper will discuss how to specify actuators that will overcome corrosion challenges and increase the mean time between failures. We will identify the most.
  148. [148]
    How does humidity affect pneumatic actuators? - Blog
    Sep 11, 2025 · One of the most significant impacts of humidity on pneumatic actuators is corrosion. When the air contains a high level of moisture, it can ...
  149. [149]
    https://www.timotion.com/en/news-and-articles/part-5-ip-ratings-and-lubrication
  150. [150]
    Design and Comparative Analysis of a Retrofitted Liquid Cooling ...
    This paper presents an in-depth system-level experimental analysis comparing air-cooled and liquid-cooled commercial off-the-shelf (COTS) electric motors.Missing: adaptations | Show results with:adaptations
  151. [151]
    [PDF] MIL-STD-810G - U.S. Army Test and Evaluation Command
    Jan 1, 2000 · This standard covers environmental engineering and lab tests for DoD, focusing on tailoring design and test limits to service conditions and ...
  152. [152]
    Shape memory alloys for cryogenic actuators - Nature
    Jul 16, 2025 · These results indicate that Cu-Al-Mn SMAs are potential cryogenic actuators with high actuation stress and strain that would contribute to the ...
  153. [153]
    [PDF] Design of a Magnetically-Geared Actuator for Extremely Cold and ...
    May 19, 2025 · Design of a Magnetically-Geared Actuator for. Extremely Cold and Dusty Space Environments. National Aeronautics and Space Administration.