Actuator

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An actuator is a component of a machine that is responsible for moving or controlling a mechanism or system, for example by actuating (opening or closing) a valve; in simple terms, it is a "mover".

An actuator requires a control signal and a source of energy, the control signal is relatively low energy and may be electric voltage or current, pneumatic or hydraulic pressure, or even human power. The supplied main energy source may be electric current, hydraulic fluid pressure, or pneumatic pressure. When the control signal is received, the actuator responds by converting the energy into mechanical motion.

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), software-based (e.g. a printer driver, robot control system), a human, or any other input.[1]

History[edit]

The history of the pneumatic actuation system and the hydraulic actuation system dates to around the time of World War II (1938), it was first created by Xhiter Anckeleman (pronounced 'Ziter')[citation needed] who used his knowledge of engines and brake systems to come up with a new solution to ensure that the brakes on a car exert the maximum force, with the least possible wear and tear.

Hydraulic[edit]

A hydraulic actuator consists of cylinder or fluid motor that uses hydraulic power to facilitate mechanical operation, the mechanical motion gives an output in terms of linear, rotatory or oscillatory motion. As liquids are nearly impossible to compress, a hydraulic actuator can exert a large force, the drawback of this approach is its limited acceleration.

The hydraulic cylinder consists of a hollow cylindrical tube along which a piston can slide, the term single acting is used when the fluid pressure is applied to just one side of the piston. The piston can move in only one direction, a spring being frequently used to give the piston a return stroke, the term double acting is used when pressure is applied on each side of the piston; any difference in pressure between the two sides of the piston moves the piston to one side or the other.[2]

Pneumatic[edit]

Pneumatic rack and pinion actuators for valve controls of water pipes

A pneumatic actuator converts energy formed by vacuum or compressed air at high pressure into either linear or rotary motion. Pneumatic energy is desirable for main engine controls because it can quickly respond in starting and stopping as the power source does not need to be stored in reserve for operation.

Pneumatic actuators enable considerable forces to be produced from relatively small pressure changes, these forces are often used with valves to move diaphragms to affect the flow of liquid through the valve.[3]

Electric[edit]

An electric actuator is powered by a motor that converts electrical energy into mechanical torque, the electrical energy is used to actuate equipment such as multi-turn valves. It is one of the cleanest and most readily available forms of actuator because it does not directly involve oil or other fossil fuels.[4]

Thermal or magnetic (shape memory alloys)[edit]

Actuators which can be actuated by applying thermal or magnetic energy have been used in commercial applications. Thermal actuators tend to be compact, lightweight, economical and with high power density, these actuators use shape memory materials (SMMs), such as shape memory alloys (SMAs) or magnetic shape-memory alloys (MSMAs). Some popular manufacturers of these devices are Finnish Modti Inc., American Dynalloy and Rotork.

Mechanical[edit]

A mechanical actuator functions to execute movement by converting one kind of motion, such as rotary motion, into another kind, such as linear motion. An example is a rack and pinion, the operation of mechanical actuators is based on combinations of structural components, such as gears and rails, or pulleys and chains.

3D printed soft actuators[edit]

Soft actuators are being developed to handle fragile objects like fruit harvesting in agriculture or manipulating the internal organs in biomedicine that has always been a challenging task for robotics. Unlike conventional actuators, soft actuators produce flexible motion due to the integration of microscopic changes at the molecular level into a macroscopic deformation of the actuator materials.

The majority of the existing soft actuators are fabricated using multistep low yield processes such as micro-moulding,[5] solid freeform fabrication,[6] and mask lithography.[7] However, these methods require manual fabrication of devices, post processing/assembly, and lengthy iterations until maturity in the fabrication is achieved. To avoid the tedious and time-consuming aspects of the current fabrication processes, researchers are exploring an appropriate manufacturing approach for effective fabrication of soft actuators. Therefore, special soft systems that can be fabricated in a single step by rapid prototyping methods, such as 3D printing, are utilized to narrow the gap between the design and implementation of soft actuators, making the process faster, less expensive, and simpler, they also enable incorporation of all actuator components into a single structure eliminating the need to use external joints, adhesives, and fasteners. These result in a decrease in the number of discrete parts, post-processing steps, and fabrication time.[8]

3D printed soft actuators are classified into two main groups namely “semi 3D printed soft actuators” and “3D printed soft actuators”. The reason for such classification is to distinguish between the printed soft actuators that are fabricated by means of 3D printing process in whole and the soft actuators whose parts are made by 3D printers and post processed subsequently, this classification helps to clarify the advantages of 3D printed soft actuators over the semi 3D printed soft actuators due to their capability of operating without the need of any further assembly.[9]

Shape memory polymer (SMP) actuators are the most similar to our muscles, providing a response to a range of stimuli such as light, electrical, magnetic, heat, pH, and moisture changes. They have some deficiencies including fatigue and high response time that have been improved through the introduction of smart materials and combination of different materials by means of advanced fabrication technology, the advent of 3D printers has made a new pathway for fabricating low-cost and fast response SMP actuators. The process of receiving external stimuli like heat, moisture, electrical input, light or magnetic field by SMP is referred to as shape memory effect (SME). SMP exhibits some rewarding features such a low density, high strain recovery, biocompatibility, and biodegradability.

Photopolymer/light activated polymers (LAP) are another type of SMP that are activated by light stimuli. The LAP actuators can be controlled remotely with instant response and, without any physical contact, only with the variation of light frequency or intensity.

A need for soft, lightweight and biocompatible soft actuators in soft robotics has influenced researchers for devising pneumatic soft actuators because of their intrinsic compliance nature and ability to produce muscle tension.

Polymers such as dielectric elastomers (DE), ionic polymer metal composites (IPMC), ionic electroactive polymers, polyelectrolyte gels, and gel-metal composites are common materials to form 3D layered structures that can be tailored to work as soft actuators. EAP actuators are categorized as 3D printed soft actuators that respond to electrical excitation as deformation in their shape.

Examples and applications[edit]

In engineering, actuators are frequently used as mechanisms to introduce motion, or to clamp an object so as to prevent motion; in electronic engineering, actuators are a subdivision of transducers. They are devices which transform an input signal (mainly an electrical signal) into some form of motion.

Examples of actuators[edit]

Circular to linear conversion[edit]

Motors are mostly used when circular motions are needed, but can also be used for linear applications by transforming circular to linear motion with a lead screw or similar mechanism, on the other hand, some actuators are intrinsically linear, such as piezoelectric actuators. Conversion between circular and linear motion is commonly made via a few simple types of mechanism including:

Virtual instrumentation[edit]

In virtual instrumentation, actuators and sensors are the hardware complements of virtual instruments.

Performance metrics[edit]

Performance metrics for actuators include speed, acceleration, and force (alternatively, angular speed, angular acceleration, and torque), as well as energy efficiency and considerations such as mass, volume, operating conditions, and durability, among others.

Force[edit]

When considering force in actuators for applications, two main metrics should be considered, these two are static and dynamic loads. Static load is the force capability of the actuator while not in motion. Conversely, the dynamic load of the actuator is the force capability while in motion, the two aspects rarely have the same weight capability and must be considered separately.

Speed[edit]

Speed should be considered primarily at a no-load pace, since the speed will invariably decrease as the load amount increases, the rate the speed will decrease will directly correlate with the amount of force and the initial speed.

Operating conditions[edit]

Actuators are commonly rated using the standard IP Code rating system, those that are rated for dangerous environments will have a higher IP rating than those for personal or common industrial use.

Durability[edit]

This will be determined by each individual manufacturer, depending on usage and quality.

See also[edit]

References[edit]

  1. ^ "About Actuators". www.thomasnet.com. Retrieved 2016-04-26. 
  2. ^ "What's the Difference Between Pneumatic, Hydraulic, and Electrical Actuators?". machinedesign.com. Retrieved 2016-04-26. 
  3. ^ "Pneumatic Valve Actuators Information | IHS Engineering360". www.globalspec.com. Retrieved 2016-04-26. 
  4. ^ "Electric & Pneumatic Actuators". www.baelzna.com. Retrieved 2016-04-26. 
  5. ^ Feng, Guo-Hua; Yen, Shih-Chieh (2015). "Micromanipulation tool replaceable soft actuator with gripping force enhancing and output motion converting mechanisms". 2015 Transducers - 2015 18th International Conference on Solid-State Sensors, Actuators and Microsystems (TRANSDUCERS). pp. 1877–80. doi:10.1109/TRANSDUCERS.2015.7181316. ISBN 978-1-4799-8955-3. 
  6. ^ Malone, Evan; Lipson, Hod (2006). "Freeform fabrication of ionomeric polymer‐metal composite actuators". Rapid Prototyping Journal. 12 (5): 244–53. doi:10.1108/13552540610707004. 
  7. ^ Kerdlapee, Pongsak; Wisitsoraat, Anurat; Phokaratkul, Ditsayuth; Leksakul, Komgrit; Phatthanakun, Rungreung; Tuantranont, Adisorn (2013). "Fabrication of electrostatic MEMS microactuator based on X-ray lithography with Pb-based X-ray mask and dry-film-transfer-to-PCB process". Microsystem Technologies. 20: 127–35. doi:10.1007/s00542-013-1816-x. 
  8. ^ Zolfagharian, Ali; Kouzani, Abbas Z.; Khoo, Sui Yang; Moghadam, Amir Ali Amiri; Gibson, Ian; Kaynak, Akif (2016). "Evolution of 3D printed soft actuators". Sensors and Actuators A: Physical. 250: 258–72. doi:10.1016/j.sna.2016.09.028. 
  9. ^ Zolfagharian, Ali; Kouzani, Abbas Z.; Khoo, Sui Yang; Gibson, Ian; Kaynak, Akif (2016). "3D printed hydrogel soft actuators". 2016 IEEE Region 10 Conference (TENCON). pp. 2272–7. doi:10.1109/TENCON.2016.7848433. ISBN 978-1-5090-2597-8. 
  10. ^ Sclater, N., Mechanisms and Mechanical Devices Sourcebook, 4th Edition (2007), 25, McGraw-Hill