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Voltage Drop Calculator

Understanding Voltage Drop

What is Voltage Drop?

Voltage drop is the reduction in voltage that occurs along an electrical conductor due to the resistance of the wire. It's an important consideration in electrical design as excessive voltage drop can lead to poor performance or failure of electrical equipment.

Key Factors

  • Wire size (gauge)
  • Wire length
  • Current flow
  • Wire material (copper vs aluminum)
  • Circuit type (single-phase vs three-phase)

Calculation Methods

Single Phase: Vdrop = 2 × I × R
Three Phase: Vdrop = √3 × I × R
Where:
I = Current in amperes
R = Wire resistance in ohms

Design Guidelines

Recommended maximum voltage drop:

  • Feeders: 2% of supply voltage
  • Branch circuits: 3% of supply voltage
  • Combined drop: 5% maximum

Frequently Asked Questions

How to Calculate Voltage Drop?

To calculate voltage drop:

  • For DC circuits: Vdrop = I × R
  • For AC single phase: Vdrop = 2 × I × R × cos φ
  • For AC three phase: Vdrop = √3 × I × R × cos φ
  • Where:
    - I = Current in amperes
    - R = Conductor resistance
    - cos φ = Power factor

How to Calculate Voltage Drop Across a Resistor?

Calculate voltage drop across a resistor using:

  • Use Ohm's Law: V = I × R
  • Measure current through resistor
  • Multiply by resistance value
  • Result is voltage drop in volts

How to Calculate Voltage Drop in Series Circuit?

For series circuits:

  • Total voltage = Sum of individual drops
  • Current is same through all components
  • Calculate each component's drop
  • Add all voltage drops together

How to Calculate Voltage Drop in Parallel Circuit?

For parallel circuits:

  • Voltage drop is same across all branches
  • Current divides between branches
  • Calculate branch currents first
  • Use Ohm's law for each branch

Complete AWG Wire Reference

AWGDiameterTurns/inchTurns/cmArea (mm²)Ω/kmΩ/1000ft
0000 (4/0)11.6842.170.8561070.16080.04901

Values are for bare copper wire at 20°C. Insulated wire may have slightly different characteristics. Always consult local electrical codes for proper wire sizing requirements.

Tips

    Temperature Effects

      This table shows common AWG wire sizes used in electrical applications. Larger AWG numbers indicate smaller wire diameters. The resistance values are for copper wire at 20°C.

      Major Causes of Voltage Drop

      1. Wire Material

      Conductor material significantly affects voltage drop. Common materials include:

      • Silver (best conductivity)
      • Copper (most common, excellent conductivity)
      • Gold (good conductivity)
      • Aluminum (lower cost option)

      2. Wire Size

      Wire gauge affects voltage drop characteristics:

      • Larger diameter = Less voltage drop
      • Every 6-gauge decrease doubles wire diameter
      • Every 3-gauge decrease doubles cross-sectional area
      • Metric gauge = 10 × diameter in millimeters

      3. Wire Length

      Length considerations:

      • Longer wires increase voltage drop
      • Critical for long-distance runs
      • Important for outbuilding wiring
      • Less critical for in-house circuits

      4. Current Load

      Current affects voltage drop through:

      • Higher current = Greater voltage drop
      • Ampacity limits maximum current
      • Temperature affects current capacity
      • Bundle derating may apply

      Quick Reference

      Wire Properties

      Resistivity (Ω·mm²/m):
      Copper: 0.0168
      Aluminum: 0.0278

      Design Tips

      • • Use larger wire for long runs
      • • Consider voltage drop in sizing
      • • Account for ambient temperature
      • • Check local electrical codes
      • • Include safety margins

      Common Applications

      Typical Scenarios

      • • Building wiring
      • • Motor circuits
      • • LED lighting
      • • Solar installations
      • • Battery systems