When piezo switch issues occur, troubleshooting becomes essential to ensure the smooth operation of vending machines and minimize downtime. However, like any other electronic device, they can experience issues over time. Complete piezo stages can be created by incorporating piezo actuators with cross roller bearings or miniature guides, and these stages can be stacked to provide X-Y or X-Y-Z motion.Piezo switches are reliable and durable components used in various industries, including vending machines. Piezo actuators are commonly used to replace solenoids in valves, pumps, and dispensing equipment, but they are also able to withstand extreme environments, such as the high vacuums found in semiconductor processing equipment and the strong magnetic fields found in MRI machines and aerospace components. Similarly, blocking force is the maximum force that can be generated when the maximum allowable voltage is applied and the actuator is not allowed to move.Ī piezo actuator is considered to be optimized for the application when it provides the required force at one-half its free deflection. Free deflection is the movement achieved when the maximum allowable voltage is applied and no force is generated. When specifying a piezo actuator, two parameters are usually considered-free deflection (X f) and blocking force (F b). The result is a bending motion with relatively large displacement-typically several millimeters-but low force generation. In a bending actuator, the applied voltage causes one piezo element to expand while the other contracts. When a contracting actuator is mounted to a base or substrate, a bending actuator is created. Contracting and expanding piezo actuators have small displacements-typically up to 20 microns-but can generate hundreds of Newtons force. These actuators use the transverse piezoelectric effect and typically produce motion in just one direction. Image credit: Noliac Contracting actuatorsįlat actuators with two piezo elements can produce contracting (or expanding) motion when both elements act together. Piezo tube actuators can generate axial, radial, or lateral displacement. Piezo tube actuators are not suitable for producing forces, but they provide micron-level travel for scanning microscopes and nanoliter dosing and pumping applications. These actuators can experience axial, radial, or lateral (bending) motion, depending on how the voltage is applied relative to the electrodes. Tube actuators have radial polarization and use the transverse piezoelectric effect to create displacement. Image credit: PI Ceramic GmbH Tube actuators Polarization (P), electrical field (E), and displacement (L) of a piezo shear actuator. The height of shear actuators is limited by shear stresses and bending, but they are often combined with longitudinal actuators in multi-axis systems. The resulting displacement occurs in the horizontal plane, creating a shear-type motion. For shear piezo actuators, the elements are polarized horizontally and the electrical field is applied orthogonally. But they differ in how the voltage is applied and the type of motion created. Shear actuators are similar to longitudinal versions, in that they consist of multiple layers of piezo elements. Longitudinal piezo actuators also have high resonant frequencies, which makes them well-suited for dynamic applications. They have a high force density-typically in the range of 30 N/mm 2-resulting in useful force in the thousands of Newtons. These actuators use the piezoelectric effect to generate linear displacements from 0.1 to 0.15 percent of the actuator length. Longitudinal actuatorsĪlso called piezo stacks, longitudinal piezo actuators are created by layering multiple piezo elements on top of each other, thus combining the effect of each element’s expansion to produce a useful movement and force. There are four main types of piezo actuators, distinguished by the arrangement of their piezo elements and by the type of movement they generate. Some actuators, however, operate on the transverse piezoelectric effect, in which motion occurs orthogonally to the electrical field. The piezoelectric effect produces motion that is parallel to the electrical field. They also generate high forces relative to their small size, giving them a significant power-to-size ratio.īecause of their conversion of electrical energy to mechanical energy, piezo devices are often referred to as motors, but the term “actuators” is used interchangeably. (Conversely, piezo materials will also generate energy when a mechanical stress is applied.) Piezo actuators harness this motion to provide very short strokes with high frequency and fast response times. Piezo materials are a special type of ceramic that expands or contracts when an electrical charge is applied, generating motion and force.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |