Electrical

Wire Size Calculator

AWG wire gauge sizing. Fast, accurate, and completely free.

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Recommended Wire Size

📏 Calculation Details

Required Cross-Section
Actual Voltage Drop
Voltage Drop %
Power Loss

📋 AWG Reference Table

AWG mm² Max A (Cu) Ω/km (Cu)

Mathematical Formula

A = \frac{2 \times \rho \times L \times I}{V_{drop}}

A = Required conductor cross-section (m²)

ρ = Resistivity of conductor (Copper: 1.68×10⁻⁸ Ωm, Aluminum: 2.65×10⁻⁸ Ωm)

L = One-way cable length in meters

I = Load current in Amperes

Vdrop = Maximum allowable voltage drop in Volts (Voltage × Drop%/100)

How to Use this Calculator

  1. Enter the load current in Amps that the wire must carry.

  2. Enter the one-way cable length from the power source to the load in meters.

  3. Enter the system voltage (e.g., 230V for Indian mains, 120V for US mains).

  4. Set the acceptable voltage drop percentage (3% is standard for branch circuits, 5% for feeders).

  5. Select the conductor material — Copper is standard, Aluminum is lighter and cheaper for large runs.

  6. Review the recommended AWG gauge, actual voltage drop, and power loss in the cable.

Why Wire Sizing Matters

Selecting the correct wire size is one of the most critical decisions in electrical installation. An undersized wire creates excessive resistance, causing voltage drop at the load, power loss as heat in the cable, and potentially dangerous overheating that can melt insulation and cause fires. Oversized wire wastes money on unnecessary copper or aluminum. Proper wire sizing balances safety, performance, and cost.

Understanding Voltage Drop

Every wire has resistance, and current flowing through that resistance causes a voltage drop (V = IR). For a round-trip circuit (supply to load and back), the total wire length is twice the one-way distance. Most electrical codes limit voltage drop to 3% for branch circuits and 5% for the combined feeder and branch circuit. Excessive voltage drop causes motors to overheat, lights to dim, and electronic equipment to malfunction.

AWG (American Wire Gauge) System

The AWG system is the standard wire sizing system used in North America and widely referenced globally. The gauge number is inversely proportional to wire diameter — smaller numbers mean thicker wire. AWG 14 (2.08mm²) is typical for 15A lighting circuits, AWG 12 (3.31mm²) for 20A outlets, and AWG 10 (5.26mm²) for 30A appliances. For very high currents, sizes go below AWG 1 into the "aught" range: 1/0, 2/0, 3/0, and 4/0.

Copper vs. Aluminum

Copper has approximately 60% better conductivity than aluminum (resistivity: 1.68×10⁻⁸ vs 2.65×10⁻⁸ Ωm), meaning aluminum wire must be roughly 1.6 times larger in cross-section to carry the same current. However, aluminum is about one-third the weight and significantly cheaper per unit length. For large feeder cables and utility distribution, aluminum is often preferred. For branch circuits and residential wiring, copper is standard due to its superior conductivity, mechanical strength, and resistance to oxidation.

Safety Considerations

Always follow local electrical codes (NEC in the US, IS 732 in India, BS 7671 in the UK) for minimum wire sizes. These codes account for ampacity (maximum safe current), ambient temperature derating, conduit fill factors, and bundling adjustments that this calculator does not cover. This tool provides a voltage-drop-based sizing recommendation and should be used alongside, not instead of, code-required ampacity tables.

Frequently Asked Questions (FAQ)

What is an acceptable voltage drop for residential wiring?

The general standard is 3% maximum for individual branch circuits and 5% for the combined feeder plus branch circuit. For sensitive electronics and motors, keeping voltage drop below 2% is recommended.

Why is the return wire counted in the calculation?

Current must flow from the source to the load AND back. Both the live and neutral wires have resistance, so the total wire length for voltage drop calculation is twice the one-way distance. This is why the formula uses 2 × L.

Can I use this calculator for DC circuits?

Yes, this calculator works perfectly for DC circuits. The voltage drop calculation is identical for DC. In fact, DC circuits don't have the additional impedance effects (inductive reactance) that AC circuits can have in larger conduits.

How do I convert between AWG and mm²?

There's no simple formula — AWG is a logarithmic scale. Common conversions: AWG 14 = 2.08mm², AWG 12 = 3.31mm², AWG 10 = 5.26mm², AWG 8 = 8.37mm², AWG 6 = 13.3mm², AWG 4 = 21.2mm², AWG 2 = 33.6mm². The reference table in the results shows all standard sizes.

What wire size do I need for a 30A circuit?

For a short run (under 15m) at 230V in copper, AWG 10 (5.26mm²) is typically adequate. For longer runs, you may need AWG 8 (8.37mm²) or larger to keep voltage drop within acceptable limits. Always check local code requirements for the specific installation.

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