Thursday, 25 January 2018

Electric vs. Pneumatic Actuators

When it comes to designing a motion-enabled machine, engineers often have to decide between different types of actuators. Two of the most common actuators available are Electric and Pneumatic.

 A linear actuator is a fairly common device that is capable of moving a load in a straight line. It converts energy into mechanical movement to achieve some purpose.

That said, engineers developing new machines and processes need to consider a wide range of variables when deciding which device will best suit their purpose.

Linear actuators are available in dozens of different styles and choosing which to use in a project is no easy task. Pneumatic and electric actuator systems are very different and one can not easily be replaced with the other. Of course, each technology has it's advantages and disadvantages. That's what we're going to cover in this post.

Should you use electric or pneumatic actuators in your industrial application? It can be a complicated decision to make, as they're functionally similar, but have some key differences.

Pneumatic Linear Actuator

Pneumatic actuators are cylinders that are driven by compressed air. They are best suited to applications that require a high force and speed with a defined stroke. The pros and cons of pneumatic linear actuators include:


  • Tend to be inexpensive when compared to other actuator systems
  • Great for large systems with many actuators. Typically with pneumatic systems, the more actuators in the system, the lower the cost per unit to maintain
  • High force and small size


  • Not ideal for applications that require different stroke lengths at different times. They tend to operate from end of stroke to end of stroke
  • Not ideal for applications where precision positioning is required
  • Air lines that are required to run a pneumatic system tend to make the system less reliable.

Screw Drive Electric Actuators

A screw drive actuator takes the rotational force of an electric motor (brushed, stepper or AC) and converts it to linear motion by driving a nut in and out along a threaded screw. Usually this is through a gearbox to allow customization of the power/speed ratio.

Electric linear actuators are best suited to applications where precise positioning, unit customization or a wide range of control options is required. They tend to have a lower cost for small-scale operations as it's not necessary to run a compressor and air lines.


  • Different motor options available depending on your needs. Brushed DC actuators are powerful and fairly accurate whereas stepper motors have less force, but operate with higher preceision
  • Lower cost on a moderate scale
  • Wide range of control options
  • Lower maintenance than pneumatic systems as there are no air lines to rupture


  • Electric actuators have more components within the device, and can have a higher unit cost than pneumatic.
  • Not always well suited for high-speed applications.
  • Tradeoff between speed and force.

Choosing What's Right For You

When comparing the benefits of electric vs. pneumatic actuators, it's important to look at the component costs and life expectancy of each system. While the initial cost of electric actuators can be higher due to their modular design, maintenance and other operational costs associated with pneumatic systems tend to be considerably higher. There's also the downtime and hassle associated with identifying and repair air leaks in a complex pneumatic system.

We believe that for most small-mid-size operations, installing electric actuators can result in considerably lower costs over time.

If you would like to some help choosing which type of system is right for your project, give our experienced sales team a call or email, they will be happy to assist you.
Thursday, 18 January 2018

How To Change An Actuator Rod End-Tip

actuator end tip

No matter how much we expand our product offering, it's impossible to have the exact solution for every single application. Every now and then our customers contact us asking about ways that they can modify their device to better suit their needs.

One of the more common requests that we get is from customers who want to change their actuator's end tip. Fortunately, this is possible and fairly simple.

All of our micro linear actuators come with a standard clevis end tip installed. Additionally, we include a threaded end tip with our hardware kit to give you a different option for mounting. 

Engineering a motion solution can be difficult, and it can be more so if you're restricted to using a specific actuator end tip. Over the years, we have had several of our customers build their own custom end tip solutions. 

This opens up a new realm of possibility as you can choose to make your tip any size and shape you like according to your specifications. You can also create your end tip from a material that suits your needs. 

Our stock units come with plastic tips, but you can make end tips from different plastics, aluminum, brass or whatever you like. If you want to make your own end tip, the internal thread designation is M8x1.25. 

The actuator end tip is screwed into the end of the shaft, which in turn is threaded onto a delrin fiberglass drive nut within the actuator.

Incorrect removal or installation of the end tip can damage this nut. There are a few steps that are vital to ensuring that you do not damage your actuator while attempting to modify or replace the tip. I'm going to cover them below. Please follow this procedure closely.

If you'd rather watch the process, here's a video on how to change a linear actuator end tip.

1. Extend the actuator to it's full outward stroke.

2. Grip the actuator shaft firmly with your fingers - It is very important to stabilize the shaft against rotation at this point. The internal drive nut inside the actuator can not tolerate much rotary force and can be broken by a firm twisting motion, rendering your actuator useless. 

3. Using a screwdriver or other object, turn the end tip counterclockwise to release the tip.

4. Follow the same procedure to install your new end tip. The torque specification for the end tip is 7 inch pounds. If you do not have a small torque wrench handy, it's best just to tighten it finger tight to avoid busting your drive nut. That's all.

That it! Replacing your actuator end tip is a pretty simple process that can help simplify your design and meet your specific goals.

Need help with choosing the best actuator for your project? Give us a shout at or call us at 1-888-225-9198.