Step-Up Transformer Calculator
Calculate step-up transformer specifications including turns ratio, current ratings, core dimensions, wire gauge, and efficiency for various transformer applications.
Step-Up Transformer Principle
Primary (Low V) Core Secondary (High V)
┌─────┐ ┌───┐ ┌─────┐
Vp ──┤ Np │ │ ⟂ │ │ Ns ├── Vs
│ ))) │ │ ⟂ │ │ ((( │
Ip ──┤ │ │ ⟂ │ │ ├── Is
└─────┘ └───┘ └─────┘
Vs/Vp = Ns/Np = Turns Ratio (>1 for step-up)
Ip/Is = Ns/Np (Current steps down)
Power: Vp×Ip ≈ Vs×Is (minus losses)
Step-Up Characteristics:
- Secondary voltage > Primary voltage
- Secondary current < Primary current
- Turns ratio > 1
- Power remains approximately constant
About Step-Up Transformers
Step-up transformers increase voltage from primary to secondary while decreasing current proportionally. They are essential in power transmission and various industrial applications.
Key Characteristics:
- Voltage Increase: Secondary voltage > Primary voltage
- Current Decrease: Secondary current < Primary current
- Power Conservation: Input power ≈ Output power (minus losses)
- Turns Ratio: Greater than 1 for step-up operation
Applications:
- Power transmission systems
- Distribution substations
- Industrial motor drives
- High-voltage testing equipment
Design Considerations:
- Proper core material selection for efficiency
- Adequate insulation for high voltages
- Thermal management and cooling
- Protection against overcurrent and overvoltage