Although for a layman, transformers and inductors seem to be the same in appearance and construction, but those in the field dealing with these equipment know that the two devices are similar, but not the same. They differ in applications, and also have their own unique design and construction. This blog will give you detailed information about these differences so that you are no more in the belief of the myth of both transformers and inductors being the same. After reading the blog, when you understand the difference between the two, and decide on using any one of them for your application, you can approach Miracle Electronics, the leading transformer and inductor coil manufacturer in India, who can serve almost every electronic purpose for your varied applications.
Home and office appliances seem to be admired by users when they can offer maximum performance while maintaining the lowest possible power consumption. This is possible when switched mode power supplies (SMPS) are used that can convert power using switching devices that are turned on and off at high frequencies, and inductors/capacitors to supply power when the switching device is in a non-conduction state. Thus, you can create an efficient power output with an SMPS transformer. And, when you purchase one from Miracle Electronics, the leading SMPS transformer manufacturer in India, you can ensure its robustness and reliability.
Switch Mode Power Supply (SMPS) transformers are flexible and used in a variety of industries like aerospace, biomedical, telecommunications, and automation controls. The major applications for these transformers include converters, inverters, switching regulators, low power isolation power supplies, high Q filters, and RFI filters. With so many applications using these transformers, it is important that you test your transformers periodically so as to avoid any faults or breakdowns.
Transformers are those electrical devices that convert higher voltages into lower voltages to make it ideal for household usage. They transfer electrical energy between circuits without modifying the frequency. With a wide variety of transformers available, each one differs in terms of their design. However, each transformer follows the basic principle of Faraday’s Law that was invented in 1831 by an English physicist named Michael Faraday. This law explains how most electrical motors, generators, inductors, and transformers work by relating the electric circuit and magnetic field.
Toroidal inductors are insulated coils that are wire wound on a ring-shaped core made of powdered iron, ferrite, or any such material. The advantage of the ring shape is that due to its symmetry, the amount of magnetic flux that escapes outside the core is low, thus making it more efficient by radiating lesser electromagnetic interference. Toroidal inductors have more inductance per turn, and carry more current as compared to solenoids with a core of the similar material and size. This is why these inductors are used at low frequencies where large inductances are required.
A current transformer is a type of transformer that measures alternating current (AC) by producing an AC in its secondary which proportional to the AC in its primary. When the current to be measured or the system voltage of the circuit is too high, current transformers are used to provide an isolated lower current in its secondary, which is proportional to the current in the primary circuit. The induced secondary current produced is then suitable to measure instruments and process electronic equipment. This is the reason why current transformers are popularly used for metering and protective relays in the electrical power industry.
Today, many companies are adjusting their costs and expenses, and are changing internal policies that help in reducing maintenance tasks and operations in electrical equipment. This obviously brings minimized costs, but only for a short period of time. In fact, this also results in increased risks in the long term because less maintenance means amplified threats. Also, such modifications and reductions result in making such transformers work above their normal load to get the expected performance. And, ultimately this results in making it difficult to obtain maximum profit from their normal work. Therefore, reduction in maintenance operations results in negative impacts like lack of efficiency and premature ageing.