A magnetostrictive system in underwater vehicles converts vibrations into electrical energy through a process called magnetostriction. Magnetostriction is a property exhibited by certain materials that causes them to change their shape or dimensions when subjected to a magnetic field. This property is utilized to generate mechanical vibrations or oscillations, which can then be converted into electrical energy.
Here's a simplified explanation of how the process works:
Magnetostrictive Material: The system uses a magnetostrictive material, often in the form of a rod or wire, which has the ability to change its shape when exposed to a magnetic field. Common materials used for this purpose include nickel, iron, and certain alloys.
Mechanical Vibrations: When the magnetostrictive material is exposed to a varying magnetic field, it undergoes cyclic changes in its dimensions. This results in mechanical vibrations or oscillations in the material. These vibrations can be induced by external sources such as underwater currents, pressure fluctuations, or other mechanical movements in the underwater environment.
Transducer: To capture and harness the mechanical vibrations, a transducer is used. The transducer is typically placed in contact with the magnetostrictive material and is designed to convert the mechanical vibrations into electrical signals. It works based on the principle of electromagnetic induction.
Electromagnetic Induction: As the magnetostrictive material undergoes mechanical vibrations, it causes changes in the magnetic field around it. This changing magnetic field induces an electrical current in the coils of the transducer through electromagnetic induction. The induced electrical current is an alternating current (AC) that corresponds to the frequency of the mechanical vibrations.
Rectification and Energy Conversion: The alternating current generated by the transducer is then rectified using diodes to convert it into direct current (DC), which can be stored in batteries or used to power electronic systems in the underwater vehicle. The amount of electrical energy produced depends on factors such as the intensity of the mechanical vibrations, the efficiency of the magnetostrictive material, and the design of the transducer.
Overall, the magnetostrictive system in underwater vehicles takes advantage of the magnetostrictive property of certain materials to convert mechanical vibrations caused by underwater movements into electrical energy. This energy can be used to power various systems and components of the underwater vehicle, making it a potentially efficient way to harvest energy from the surrounding environment.