What Is a Linear Actuator?

Linear actuator guide

Straight-line motion, sized properly

A linear actuator converts energy into controlled straight-line motion. Learn how electric linear actuators work, how to compare force, stroke, speed, duty cycle, feedback, and IP ratings, and how to choose the right actuator for your application.

Linear actuator quick answer

A linear actuator is a device that creates motion in a straight line. Electric linear actuators usually use a motor, gearbox, and lead screw to extend and retract a rod, allowing them to push, pull, lift, tilt, slide, or position a load.

Cutaway diagram of an electric linear actuator showing motor, gearbox, lead screw, drive nut, output rod, housing, and limit switches.
Cutaway view of an electric linear actuator. The motor and gearbox turn the lead screw; the drive nut and output rod convert that rotation into useful linear travel.

Animated cutaway: linear actuator motion

Prefer the full interactive version? Open the animated cutaway or try the interactive actuator visualizer on the broader actuator guide.

Written by Robbie DicksonFounder of FIRGELLI Automations.
20+ years experienceActuators, motion control, automotive mechanisms, and automation.
Engineering reviewedMaintained by the FIRGELLI engineering team.
Last updatedJune 30, 2026. Author profile: Robbie Dickson.

What is a linear actuator?

A linear actuator creates controlled motion along a straight line. A rotary motor spins; a linear actuator uses extra mechanical parts to turn that rotation into push-pull travel. That makes it useful when a mechanism must lift, lower, slide, open, close, tilt, or hold a position.

In the FIRGELLI hierarchy, Actuators Explained is the broad parent guide for all actuator types. This article focuses specifically on electric linear actuators: rod actuators, track actuators, feedback actuators, industrial actuators, micro actuators, and lifting columns.

How does a linear actuator work?

The mechanical chain is simple:

Motor
Gearbox
Lead screw
Drive nut
Output rod

The motor creates rotation. The gearbox reduces speed and increases torque. The lead screw rotates inside the actuator body. A drive nut travels along that screw, pushing or pulling the output rod. Limit switches stop the travel at the endpoints so the motor does not stall against the mechanical stops.

For a deeper internal walkthrough, read how a linear actuator works.

Inside a linear actuator

Motor

Provides the initial rotary power, usually from a 12 VDC or 24 VDC supply.

Gearbox

Trades speed for torque. Higher reduction usually means more force and slower travel.

Lead screw

Converts rotation into linear travel. Screw pitch strongly affects force, speed, and self-locking behavior.

Drive nut and rod

The nut moves along the screw and drives the extending rod in or out.

Housing and guides

Protect the mechanism and keep the moving parts aligned.

Limit switches

Stop motion at full extension and full retraction.

Types of linear actuators

Choose the actuator style based on the load path, available space, required feedback, and whether the actuator must resist side loading.

Type Best for Strengths Limitations Relevant FIRGELLI link
Standard rod linear actuators Hatches, vents, furniture, general automation Simple, compact, broad force and stroke range Rod must not be side loaded Linear actuators
Heavy-duty linear actuators Higher-force lifting, industrial fixtures High load capacity and rugged construction Usually slower and physically larger Industrial actuators
Mini / micro linear actuators Robotics, small devices, compact mechanisms Very small package and light weight Lower force and shorter stroke Micro linear actuators
Track actuators Sliding doors, drawers, guided travel Carriage supports side-load style motion Less suitable where an extending rod is required Track linear actuators
Feedback linear actuators Position control and synchronization Position signal for controllers Requires compatible controller and wiring Feedback actuators
Lifting columns Desks, medical equipment, vertical lifts Guided telescoping lift in a compact package Designed for vertical lifting, not every linkage Column lifts
Rotary actuators Valves, pivots, angular motion Useful for turning motion Not linear actuators; use only when the load must rotate Alternative motion type

Electric vs hydraulic vs pneumatic linear actuators

Electric, hydraulic, and pneumatic systems can all create linear motion. Electric actuators are usually easiest to wire, control, and maintain. Hydraulic systems are favored for very high force. Pneumatic systems are fast and simple when compressed air already exists.

Type Power source Precision Force Maintenance Best use case
Electric Electric motor and power supply High with feedback Low to high, model dependent Low Clean automation, furniture, hatches, robotics, controlled positioning
Hydraulic Pressurized fluid, pump, valves Moderate without servo control Very high High Construction, heavy machinery, very high-force applications
Pneumatic Compressed air Lower because air compresses Moderate Moderate Fast cycling in plants with existing air systems

For deeper comparisons, see electric actuator vs hydraulic actuator and pneumatic vs electric actuators.

Linear actuator specifications explained

Force

How much push or pull the actuator can apply. Dynamic force matters while moving.

Stroke length

The usable travel between full retraction and full extension.

Speed

Travel rate under load. Higher force usually means lower speed.

Voltage

Common options include 12 VDC and 24 VDC. Voltage affects current and controller choice.

Current draw

Motor current rises with load. Size the power supply for startup and stall risk.

Duty cycle

Allowed run time versus rest time before heat becomes a problem.

IP rating

Ingress protection against dust and water.

Feedback

Position reporting from potentiometers, Hall sensors, or encoders.

Static load

Holding force when stopped.

Dynamic load

Moving force while extending or retracting.

Retracted and extended length

Physical envelope at both ends of travel.

Mounting hole size

Clevis and bracket dimensions that set pin and hardware fit.

Noise level

Important for furniture, medical, home, and office applications.

Screw type

ACME or ball screw choices affect efficiency, holding, and cost.

Gear ratio

Sets the force-speed tradeoff with the motor and screw pitch.

Static load vs dynamic load

Dynamic load is the force the actuator can move. Static load is the force it can hold while stopped. Always size the actuator from the dynamic load requirement, then check that the static rating and safety factor are appropriate for the final position.

Loading direction and side loading

A rod actuator is designed for axial push and pull. Side loading bends the rod, damages bushings, increases friction, and can shorten actuator life. If the load must slide sideways or carry off-axis force, use guides, linkages, a track actuator, or separate rails so the actuator only supplies force along its intended line.

Force, stroke, speed, and gearing

Force, speed, and duty cycle are connected. More gear reduction and a finer screw pitch increase force, but reduce speed and create more heat. A lower-force actuator can often move faster, but it must still meet the load and safety factor.

Linear Actuator Force Calculator

Estimate force for inclined loads and friction.

Actuator Stroke Length Calculator

Work out travel for hinged lids, hatches, and linkages.

Actuator Speed Calculator

Convert extension time, travel distance, and velocity.

Linear Motion Calculator

Connect distance, time, velocity, and acceleration.

Gear Reduction Calculator

Understand motor speed, gear ratio, and output motion.

Duty cycle

Duty cycle protects the motor from overheating. If an actuator has a 25 percent duty cycle, a simple rule is one minute running followed by about three minutes resting. Use the Actuator Duty Cycle Calculator and the linear actuator duty cycle guide when a system cycles often or holds high loads.

Limit switches and stroke control

Limit switches stop travel at the endpoints. Without them, the motor can stall at the mechanical end of travel, draw high current, and overheat. Internal limit switches are enough for many applications; adjustable stops or external controls are useful when the mechanism needs custom endpoints.

Mounting and brackets

Most linear actuator installations use dual-pivot mounting: one clevis bracket at the rear and one at the rod end. This lets the actuator rotate as the mechanism moves through an arc. Fixed mounting can work only when the actuator and load stay aligned through the full stroke.

Geometry matters. A small change in bracket location can dramatically change required force, travel, and mechanical advantage.

Use the Actuator Mounting Angle Calculator and match the hardware with compatible mounting brackets.

IP ratings and environmental protection

IP ratings describe protection against solids and water. Indoor furniture may not need the same protection as marine, agricultural, or washdown environments. Check cable exits, seals, mounting orientation, and condensation risk, not just the headline IP number. Start with the IP ratings of linear actuators guide when the actuator will see dust, rain, spray, or water.

Feedback, Hall sensors, potentiometers, and encoders

Feedback matters when the controller needs to know position. A potentiometer gives an analog position signal. Hall sensors and optical encoders provide pulses for digital position tracking. Limit switches only indicate endpoints; they do not provide continuous position information.

Feedback options for linear actuators

Compare common sensor choices.

Hall effect vs optical encoder feedback

Choose digital pulse feedback for control systems.

Potentiometer feedback guide

Use analog position feedback for simple control loops.

Synchronizing multiple actuators

Keep two or more actuators aligned under changing load.

Linear actuator wiring and control

Most two-wire DC linear actuators reverse direction by reversing polarity. You can control them with switches, relays, remote control boxes, motor drivers, Arduino, Raspberry Pi, or dedicated synchronization controllers. The controller must handle motor current and any feedback signals.

Wiring Diagram Generator

Create wiring diagrams for switches, relays, remotes, and controllers.

Control a linear actuator with Arduino

Starter guide for microcontroller control.

Position input motion control with Arduino

Use position input and feedback for controlled travel.

Linear actuator control boxes

Understand remotes, channels, synchronization, and controller choices.

Real-world applications

Home automation

Hidden doors, vents, appliance lifts, and adjustable fixtures.

Robotics

Compact push-pull motion where a rotary joint is not the right fit.

Industrial automation

Guards, diverters, small lifts, fixtures, and repeatable positioning.

Agriculture

Vent control, gates, hoppers, sprayers, and rugged outdoor mechanisms.

Marine

Hatches, seats, vents, and compartments where clean electric motion helps.

Automotive

Spoilers, panels, bed covers, seat mechanisms, and custom motion systems.

Medical equipment

Adjustable beds, chairs, supports, and controlled positioning devices.

Furniture and lifts

TV lifts, desks, recliners, monitor lifts, and storage lifts.

Solar tracking

Panel tilt systems that follow seasonal or daily sun angle changes.

Hatches and doors

Top-hinged doors, truck hatches, cellar doors, and enclosure lids.

Accessibility systems

Platform assists, ramps, lifts, and adjustable access mechanisms.

How to choose the right linear actuator

  1. Define the motion: lift, slide, tilt, push, pull, or position.
  2. Calculate force with load, friction, pivot geometry, and safety factor.
  3. Choose stroke length from the required travel, not just the gap size.
  4. Decide speed under load.
  5. Choose voltage and size the power supply for current draw.
  6. Check duty cycle against the expected run-rest pattern.
  7. Match the IP rating to dust, rain, washdown, or outdoor exposure.
  8. Decide whether feedback or synchronization is required.
  9. Check mounting geometry and side-load risk.
  10. Use the Linear Actuator Selector Tools and confirm with the Linear Actuator Calculator.

For a more detailed decision guide, read how to select the right linear actuator.

Linear Actuator Calculators and Engineering Tools

  1. Start here to understand linear actuator basics.
  2. Use the broader Actuators Explained page if you need rotary, hydraulic, pneumatic, or servo context.
  3. Move to the Linear Actuator Engineering Guide when you need deeper specification and design detail.
  4. Use calculators and selectors before choosing a product category.

Frequently Asked Questions

What is a linear actuator?

A linear actuator is a device that creates motion in a straight line. Electric models usually use a motor, gearbox, lead screw, drive nut, and output rod to push, pull, lift, slide, tilt, or position a load.

How does a linear actuator work?

A motor creates rotation, gears trade speed for torque, a lead screw converts rotation into linear motion, and a drive nut moves the output rod in or out.

What is the difference between a linear actuator and a motor?

A motor normally produces rotary motion. A linear actuator contains a motor plus mechanical parts that convert that rotation into controlled straight-line motion.

What are linear actuators used for?

They are used for hatches, doors, adjustable furniture, robotics, industrial automation, agricultural equipment, marine hardware, solar tracking, accessibility systems, and positioning mechanisms.

What are the main types of linear actuators?

Common types include standard rod actuators, heavy-duty actuators, mini or micro actuators, track actuators, feedback actuators, industrial actuators, and lifting columns.

How much force can a linear actuator produce?

Force depends on the model, gear ratio, screw pitch, voltage, and duty cycle. Small actuators may produce only a few pounds, while heavy-duty units can produce thousands of pounds.

What is stroke length?

Stroke length is the distance the actuator rod travels between fully retracted and fully extended positions.

How fast do linear actuators move?

Speed depends on the gear ratio, screw pitch, voltage, and load. Higher-force actuators usually move more slowly than lower-force actuators.

Why are force and speed connected?

The gearbox and screw trade speed for mechanical advantage. More force usually requires more gear reduction or a finer screw pitch, which slows movement and increases heat.

What voltage do linear actuators use?

Many electric linear actuators use 12 VDC or 24 VDC. Industrial systems may use other voltages depending on controller and power supply requirements.

What is duty cycle?

Duty cycle is the amount of run time allowed before the actuator must rest. A 25 percent duty cycle means the actuator should rest for about three times as long as it runs.

Can linear actuators push and pull?

Yes. Most rod-style electric linear actuators can extend to push and retract to pull, within their rated force limits and mounting geometry.

Can linear actuators hold position without power?

Many lead screw actuators are self-locking enough to hold position when power is removed, but the holding ability depends on the screw design and static load rating.

What are limit switches?

Limit switches stop the actuator at full extension and full retraction so the motor does not stall against the end of travel.

What is actuator feedback?

Feedback is a position signal from a potentiometer, Hall sensor, or encoder. It lets a controller know where the actuator is during travel.

Can two linear actuators be synchronized?

Yes, but reliable synchronization normally requires feedback actuators and a controller that compares position and adjusts motor output.

Can linear actuators be used outdoors?

Yes, if the actuator has an IP rating and material protection suitable for rain, dust, washdown, salt spray, or temporary water exposure.

What IP rating do I need?

Use the environment to choose the rating. Sheltered indoor use needs less protection than marine, washdown, outdoor, or dusty industrial applications.

How do I mount a linear actuator?

Most applications use clevis brackets at both ends so the actuator can pivot as the mechanism moves. Avoid side loading the rod.

How do I calculate actuator force?

Use the load weight, pivot points, lever arms, mounting angle, friction, acceleration, and safety factor. Hinged applications need geometry-based calculations.

How do I choose the right linear actuator?

Define the motion, calculate force, choose stroke, decide speed and voltage, check duty cycle and IP rating, decide whether feedback is needed, verify mounting geometry, then use a selector or calculator.

Author and review process

Robbie Dickson

Founder of FIRGELLI Automations, with more than 20 years of actuator, automotive mechanism, and motion-control experience. Profile: Robbie Dickson. Wikipedia: Robbie Dickson on Wikipedia.

Engineering review

This guide is maintained by the FIRGELLI engineering team and is reviewed against actuator sizing, mounting, wiring, control, feedback, and environmental selection requirements.

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