Eight selection criteria for actuation components
Electromechanical systems offer advantages over hydraulic and pneumatic actuators
When deciding between fluid-driven and electromechanical linear actuators, close consideration of long-term benefits to the intended end user can help original equipment manufacturer (OEM) system designers maximize both product value and return on investment (ROI).
Fluid-driven actuators translate electric energy motion through a column of air, gas, oil or other media. While the motion they provide is simpler than with other type actuators, the infrastructure required to support them is not. Hydraulic actuators require an external system of pumps and valves; Pneumatic actuators require complex air delivery systems. For both, stroke length is defined by a mechanical hard stop.
Electromechanical systems can handle more complex operations with a much simpler design. An electric motor — through a belt gear, a worm gear, a planetary gear or via a direct coupling — rotates a ball screw, which translates the torque into axial force through an extension tube. All key motion components are, or can be, self-contained. Motion is controlled by a programmable electronic signal.
System designers should consider the following eight criteria when choosing between fluid-driven and electromechanical actuators.
1. Motion profile control
As business volatility and complexity increase, users of actuator-driven machinery and equipment demand greater control over position, velocity or force throughout the range of motion. Fluid-driven actuators cannot provide this easily. It is difficult for them to achieve the slow, controlled speeds that may be needed in many applications. To some extent, fluid-based actuators can gain control using external systems such as proportional regulators, valves and encoders, but this adds cost and further complexity.
Because electromechanical motion is controlled electronically, the device can be programmed to stop at any point along the stroke. Force and motion profiles can be changed in software without having to shut down and reconfigure the machine. The increased controllability of electromechanical actuators often can eliminate the need for changeover when switching from one product to another. In applications such as packaging lines, where numerous package sizes may run in a single shift, this can result in significant savings (see Figure 1). Electromechanical actuators also can be networked, enabling functionality such as synchronization, making it easier for end users to work with unbalanced loads.
2. Impact on cleanliness and safety
In addition to limiting control over the motion profile, fluids make for a grimier, potentially dangerous work environment. For example, hydraulic fluids must be transported and stored. Ever-present leaks must be cleaned and can contribute to slip-and-fall accidents on the plant floor. Various filtration methods must be used to reduce contaminants. When the fluid has fully degraded, it must be changed and disposed of carefully. Pneumatic actuators present similar issues due to the presence of oil and other impurities in compressed air supplies. The exhausted air must be filtered to remove impurities before it is released into the environment.
Electromechanical actuators have no such issues. Motion is in precision-fit metal parts, which require only routine lubrication — or in some cases no lubrication at all. Given that, electromechanical actuators are especially appropriate for use in sanitary applications that require ultraclean operation such as in the food, beverage, packaging, medical and electronics manufacturing industries (see Figure 2).
Because all components are contained in sealed modules with high ingress protection, electromechanical actuators also are more suitable for environments with higher contamination risk: chemical plants, paper mills, welding operations and outdoor applications.
3. Durability and maintenance
Just avoiding the grime and contamination of fluids reduces pressure on maintenance resources, but the greatest contributor to the maintenance workload is the complexity of fluid-based systems.
Routine, break/fix-style maintenance is essential for fluid-based systems. Oil loses efficacy and must be checked. Gaskets and seals are subject to damage and wear. Infrastructure components must be monitored and replaced as needed. However, electromechanical actuators run longer with no maintenance intervention, providing consistent performance for the entire actuator lifetime.
4. Ambient noise
Noise is a significant issue with both hydraulic and pneumatic actuators. A hydraulic system consists of an electric motor, bearings, rotor/stator assembly and a fan. The motor drives a pump, which pressurizes hydraulic fluid in the cylinder via a valve. The fluid is transmitted through a system of tubing, hoses and fittings.
To maintain the pressure, this system must be kept idling continually, which produces additional baseline noise that often can be heard throughout the plant, adding to ambient environmental noise levels. This is such a concern that products offering noise mitigation on hydraulic systems are an industry in itself.
With pneumatic actuators, noise is mostly the result of air leaks, which are frequently present. Pressure losses and impurities found in compressed air supplies impact pneumatic actuators, causing increased energy usage and noise levels.
By contrast, the design of electromechanical actuators makes their operation quiet. This technology is continuously advancing to achieve quieter operation for use in applications not possible for the other media actuators. For example, there is an electromechanical actuator on the market that operates with a sound level of less than 45 dB — about the same as a typical library.
5. Energy efficiency
Fluid actuators use energy very inefficiently because they go through a two-step energy conversion process. Hydraulic systems have the advantage of being able to hold constant pressure without having to apply additional amounts of energy, but this requires keeping a pump running continuously, even when the actuator is not performing any work. With pneumatic actuators, escaping air through leaks increases energy usage and ambient noise levels.
In contrast, electromechanical technology uses energy only when doing work, and does so with high efficiency. More than 90% of the energy applied to an electromechanical ball-and-roller screw assembly is converted to work. An electromechanical device also can hold a load in place without expending additional energy or complex system assemblies.
6. Space efficiency
The fact that everything in an electromechanical actuator can be self-contained in a compact unit means that OEMs can make smaller machines. This size reduction helps end users add automation to smaller spaces, improving efficiencies for both operation and space utilization (see Figure 3). Certain manufacturers have gone one step further in making actuators with a single-mount capability, making it easier for OEMs to deliver smaller systems.
7. Integration with other applications
As industrial systems become smarter and more connected, opportunities to optimize production to new levels of quality, efficiency and cost control are emerging. Many of these involve exchanging operational data across workplaces via the cloud. Fluid actuators are not as equipped to play in those applications, as additional hardware often is required to provide what is integrated in electric actuators. This additional technology requirement makes integrating fluid actuators into process optimization or modernization strategies more costly and difficult at times.
Electromechanical actuators connect to networks with only a few wires, making it easier for them to exchange performance information among actuation devices as well as with optimization software.
8. Total cost of operations
While each selection criteria discussed thus far translates into end user value to some degree, an electromechanical actuator’s greatest contribution is most likely its role in reducing total cost of operations. Greater control over the motion profile means there is no need to buy complex add-on components, servo valves or other components to control operations.
Cleaner operation and reduced maintenance contribute to the bottom line by reducing the labor otherwise needed to monitor and repair systems. Using electromechanical actuators eliminates the expense of hydraulic oil associated with traditional hydraulic systems.
Because electromechanical actuators run longer without needed maintenance, manufacturers save on replacement purchases and inventory management. The ability for electromechanical actuators to convert 90% of energy to work allows a plant to save thousands in energy costs. In energy intensive industries, energy cost savings can justify upgrades to electromechanical actuators with system paybacks as quickly as one year.
More efficient space utilization can have a significant financial benefit, especially in areas where real estate values are high or on offshore and remote operations. Going forward, it may be that the greatest financial benefit of using electromechanical actuators is in their readiness for integration into the digital age. Companies are making gains by pulling device data into asset management software, enabling greater predictive management of processes and assets.
A key aspect for system designers is ensuring that the right components are selected and integrated to deliver accuracy, efficiency, precision, noise level and other performance characteristics. Many companies manufacturing electromechanical actuators offer online self-service sizing and selection tools that enable designers to accurately size and select linear motion systems and other components.
Sharing the benefit
Most of the same features that make electromechanical actuators more valuable than fluid-based systems to end users also make it easier for OEM system designers to deliver that value. Pneumatic or hydraulic technology requires working with complex, space-consuming infrastructures.
Electromechanical actuators are simpler and easier to size. In a few steps, designers can determine the required load and duty cycle, and specify stroke and retraction length. Modern configuration tools make this process even easier. Once an actuator is determined, the end user determines a location, mounts and wires it with a few wires and the actuator is up and running. Designers of fluid-based systems do similar calculations but must consider the additional system requirements of how to locate and sustain the fluid supply to the actuator.
Because they deliver so many benefits to end users, electromechanical actuators can help OEMs field a more competitive offering. As they are easier to work with and more versatile, electromechanical actuators also can reduce design and development costs.
Maximizing value and ROI
In addition to providing system designers with an easier and more versatile motion component than fluid actuators, electromechanical linear actuators provide significant advantages to both end users and OEMs. They are cleaner, easier to integrate, control and maintain, quieter and more energy efficient. In addition, they take up less space — all of which contribute to a lower total cost of operation and last longer without maintenance. Hydraulic and pneumatic alternatives have their place, but best practice is to consider all alternatives when deciding which actuation technology would be best for the application.
Selecting motion control components
As industrial technology advances, and electromechanical actuators and other motion control components expand in capabilities for heavy duty applications, system designers are faced with a wide variety of options for their projects.
Application and selection tools make it easier for design engineers to select the right product for their specific application needs, providing an effortless navigation experience to help identify the ideal actuator solution quickly.
To ensure the best fit, they should take into account a handful of end-user considerations when making their selections:
- How much control will the end user have over motion profiles?
- How clean is the operating environment? What are the potential hazards?
- What is the stated life cycle? How much maintenance is required?
- How quiet is the system?
- How energy-efficient is it?
- How much space is required for operation?
- How easy is it to integrate with other applications?
- What is the impact on total cost of operating?
Original content can be found at Plant Engineering.
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