Piezo Actuator Driver Schematic - Apps
Piezo Actuators: Types and ApplicationsA piezoelectric actuator converts an electrical signal into a precisely controlled physical displacement (stroke). If displacement is prevented, a useable force (blocking force) will develop. The precise movement control afforded by piezoelectric actuators is used to finely adjust machining tools, lenses, mirrors, or other equipment. A piezo actuator can be used to control hydraulic valves, act as a small-volume pump or special-purpose motor, and in other applications requiring movement or force. How Does A Piezo Actuator Work?To answer the question, “What is a piezoelectric actuator?” and to learn how the device works, it’s first helpful to understand that all actuators — from hydraulic and pneumatic to mechanical and electric — are machine components that convert a type of signal energy into a desired controlling motion. Think of what happens when an operator presses a button that prompts an electric actuator to transfer the operator’s signal into rotary motion to either open or close a valve, and you have the basics of how all actuators function.In piezo actuators, the piezo effect is of primary use.
Elementary piezoelectric materials change dimensions when a force and/or voltage is applied. That’s why these types of actuators are highly useful in applications that call for the precise positioning of mechanical devices — from mirrors on satellites and telescopes to non-magnetic and miniaturized medical devices.Plus, since piezoelectric actuators give off little heat and consume almost no power when operating in an energized state, they’re widely used across a broad selection of industries, including everything from automotive and defense applications to scientific instrumentation and ultrasonic machine controls. Discrete stacks (high-voltage stack actuators) are composite structures made by stacking separately finished piezoelectric ceramic discs or rings and metal electrode foils with an adhesive. Operating voltages ranging from 500 V thru 1,000 V are typical.Co-fired multilayer stack actuators, also called “monolithic stacks”, involve no adhesive, but rather a high temperature sintering of the complete ceramic and electrode pile. Operating voltages of a co-fired stack are up to 200 V. Rectangular cross sections are typical due to the ease of cutting processes in production.Both the discrete and co-fired stacks can be insulated with a coating material — a bare stack — or encased in stainless steel when protection from mechanical stress and environmental extremes are needed.A, also called a bending actuator, is designed to produce a relatively large mechanical deflection in response to an electrical signal.
This deflection offers a large stroke and a very limited blocking force when compared to a stack actuator. In a stripe actuator, two thin layers of piezoelectric ceramic are bonded together, usually with the direction of polarization coinciding, and are electrically connected in parallel. When electrical input is applied, one ceramic layer expands and the other contracts causing the actuator to flex. Piezoelectric Actuator Uses and ApplicationsGiven its simple design, minimal moving parts, no requirement for lubrication to operate and the high reliability characteristics, the piezoelectric actuator is used in a variety of, medical, aviation,. Piezo actuators are found in precision knitting machinery and braille machines. The silent drive characteristics make piezo actuators an excellent auto focusing mechanism in microphone-equipped video cameras and mobile phones. Finally, since piezo actuators require no lubrication to operate, they are used in cryogenic and vacuum environments.Using a stack actuator, extremely fine, virtually infinite resolution is possible with very high voltages corresponding to minute movements of expansion.
A piezo actuator can operate billions of times without wear or deterioration. Its response speed is exceptional and it is limited only by the inertia of the object being moved and the output capability of the electronic driver. When operating in an energized state, a piezoelectric actuator consumes virtually no power and generates very little heat.For more information about piezoelectric actuators and piezoelectric actuator applications, please download our reports:High-Quality Piezoelectric Actuators From APC International, Ltd.At APC International, we specialize in meeting the piezoelectric ceramic and device needs of our customers — including both piezo stack actuators and stripe actuators. Across every step of the manufacturing process, we’re here to help you get the right piezo device for your needs.Our staff is highly trained, extremely experienced and ready to support you throughout the design, construction and testing of your piezo actuators.
Our philosophy is that when you choose APC International, all of your piezoelectric needs should be met in a time-sensitive and cost-efficient manner.To learn more about our full line of piezoelectric actuators and other piezo materials, today. Call (570)-726-6961 to speak to one of our representatives.
Okay, so I saw a youtube the other day of a guy who took a piezo transducer, sort of like one, and integrated it into a pen, driven by the headphone jack in a tiny FM radio. He mentions in the video matching the impedance, as driving the transducer given the low voltage of the headphone jack apparently does not do much. He does this using transformer. I would really like to replicate this design, but I am hoping to find a transformer which is less thick. However, I do not have a good enough understanding of the electronics to know what to look for.He mentions that the output of the headphone jack is something like 3 volts, but that the transformer outputs something closer to 50 volts, which is more suitable for the transducer, which prefer high voltages even ranging into hundreds of volts. How can I go about finding a more applicable transformer, and what do I need to look for?Thanks,Ryan.
You mentioned that those particular transducers are meant to be microphones, which I had noticed. It does not quite look like the same one used in the video, though I cannot seem to find ones that do. Is there a reason these would not work, or something else I should be looking at?As for using a high-voltage power supply and amplifier, You'll have to forgive an electronics noob, but I still have no idea how I'd find the right parts, or be able to match them together, or even what I need to learn to get to that point. Any help with this would also be greatly appreciated.
Piezo Actuator Driver Schematic - Apps Download
Basically I am trying to replicate the result, being able to take a signal intended for headphones, and turn them into something you could bite down on for audio, all in as small a package as possible. You can't match capacitive reactance with a transformer, you can't transfer power to the capacitive component of the impedance, and if you match the impedance of the amplifier/driver circuit, you'll probably fry the electronics.Most audio 4 or 8-Ohm power amplifiers have a source impedance of less than 1-Ohm.
Piezoelectric Actuator Bandwidth
As you lower the impedance, you get more power out. But, if you try to get 'maximum power transfer' by matching that 1-Ohms or less impedance, you'll get smoke.I don't know what the source impedance is for an Arduino output pin, but if you match it you'll be getting more than the rated 40mA from it. (And the output voltage will be pulled-down to 2.5V.).