A magnetostrictive linear magnetic field sensor is a type of sensor that measures magnetic fields using the magnetostrictive effect. The magnetostrictive effect refers to the phenomenon where certain materials change their shape or dimensions when exposed to a magnetic field. This effect is exploited in magnetostrictive sensors to convert magnetic field variations into measurable physical changes, which are then used to determine the magnitude of the magnetic field.
Here's a general overview of the operation of a magnetostrictive linear magnetic field sensor:
Principle of Operation: The sensor consists of a magnetostrictive material (e.g., Terfenol-D, Galfenol) and a waveguide. The magnetostrictive material is usually a ferromagnetic alloy that exhibits the magnetostrictive effect, meaning it changes its shape or dimensions in response to changes in an external magnetic field. The waveguide is typically a thin rod made of a non-magnetic material, which guides the mechanical wave generated by the magnetostrictive material.
Excitation: The sensor requires an excitation source, usually an electrical pulse, to induce a magnetic field around the magnetostrictive material. This excitation can be generated by passing an electrical current through a coil wrapped around the magnetostrictive material. The pulse creates a temporary magnetic field around the material, causing it to deform slightly.
Mechanical Wave Propagation: When the magnetostrictive material undergoes deformation due to the excitation, a mechanical wave is generated within the material. This wave propagates through the material and the waveguide at the speed of sound in the material. The propagation speed depends on the material properties and is typically well-characterized.
Interaction with External Magnetic Field: Now, suppose an external magnetic field is applied to the magnetostrictive material during the propagation of the mechanical wave. The presence of this external field will alter the propagation speed of the wave. If the external magnetic field is aligned with the initial excitation field, the speed of the wave will increase. Conversely, if the external magnetic field is opposed to the initial excitation field, the speed of the wave will decrease.
Detection: The waveguide helps to transmit the mechanical wave to a pickup coil located at one end of the waveguide. As the wave reaches the pickup coil, it induces a voltage in the coil. The voltage induced is proportional to the speed of the wave, which, in turn, is affected by the external magnetic field.
Output: The voltage signal from the pickup coil is then processed and calibrated to provide a linear response representing the magnitude of the external magnetic field. By measuring the time it takes for the wave to travel through the material and reach the pickup coil, the sensor can accurately determine the strength of the magnetic field.
Advantages of magnetostrictive linear magnetic field sensors include their high sensitivity, wide dynamic range, and robustness in harsh environments. They are commonly used in industrial applications, such as position and displacement sensing, non-destructive testing, and monitoring magnetic fields in various systems.