Oriented Silicon Steel, also known as electrical steel or transformer steel, is a specialized type of steel that is designed for use in electrical power equipment, such as transformers and electric motors. It is characterized by its unique grain orientation, which is achieved through a carefully controlled manufacturing process.
Oriented Silicon Steel, also known as electrical steel or transformer steel, is a specialized type of steel that is designed for use in electrical power equipment, such as transformers and electric motors. It is characterized by its unique grain orientation, which is achieved through a carefully controlled manufacturing process.
We also provide oriented silicon steel grade 27Q120,27Q110,27Q100,23Q120,23Q110,23Q100, etc.These grades are subjected to strict control specifications and technical tests, providing reliable quality and excellent performance. We can also process and cut all kinds of shaped parts according to your needs, and do transportation on behalf of customers with fast delivery time.We support customization, welcome to consult!
High Magnetic Permeability: Oriented Silicon Steel exhibits high magnetic permeability, which means it can efficiently carry and transmit magnetic fields. This property makes it ideal for use in power transformers, where it helps minimize energy losses and improve overall efficiency.
Low Core Loss: This type of steel offers low core loss, meaning it experiences minimal energy dissipation when subjected to alternating magnetic fields. Low core loss is crucial for maintaining high efficiency in electrical devices, as it reduces the amount of energy wasted as heat.
High Saturation Flux Density: Oriented Silicon Steel has a high saturation flux density, which refers to its ability to absorb and store magnetic energy. This characteristic enables it to handle high magnetic field strengths without reaching its magnetic saturation limit.
Excellent Electrical Resistivity: It possesses excellent electrical resistivity, allowing it to resist the flow of electric current and minimize eddy current losses. Eddy current losses can occur when alternating magnetic fields induce currents in conductive materials, resulting in energy losses and heat generation.
Material Grade | Baosteel Grade | Density (kg/dm³) |
B23R90 | Thickness 0.23 mm | 7.65 |
B23R85 | Thickness 0.23 mm | 7.65 |
B23R80 | Thickness 0.23 mm | 7.65 |
B23R75 | Thickness 0.23 mm | 7.65 |
B27P90 | Thickness 0.27 mm | 7.65 |
B27P95 | Thickness 0.27 mm | 7.65 |
B23P95 | Thickness 0.23 mm | 7.65 |
B23P100 | Thickness 0.23 mm | 7.65 |
Material Grade |
Wuhan Iron and Steel Corporation Grade |
Density (kg/dm³) |
23RK90 |
Thickness : 0.23 mm |
7.65 |
23RK85 |
Thickness : 0.23 mm |
7.65 |
23RK80 |
Thickness : 0.23 mm |
7.65 |
23RK75 |
Thickness : 0.23 mm |
7.65 |
27QG95 |
Thickness : 0.27 mm |
7.65 |
27QG90 |
Thickness : 0.27 mm |
7.65 |
27QG100 |
Thickness : 0.27 mm |
7.65 |
30QG110 |
Thickness : 0.30 mm |
7.65 |
30QG105 |
Thickness : 0.30 mm |
7.65 |
30QG100 |
Thickness : 0.30 mm |
7.65 |