What is Electrical Load Calculation?

Electrical load calculation is the process of determining the total electrical power demand of a building or facility. It involves identifying every piece of electrical equipment, determining its power rating, applying demand factors to account for diversity, and calculating the resulting current that the supply system must carry.

An accurate electrical load calculation is required for:

  • Sizing the utility supply — requesting the correct supply capacity from the electricity authority
  • Transformer sizing — selecting the correct kVA rating for the HV/LV transformer
  • Main LV switchboard sizing — busbar ratings, incomer switch and protection devices
  • Standby generator sizing — ensuring the generator can carry all essential loads
  • Main incoming cable sizing — selecting the correct cable cross-section area
  • UPS system sizing — for critical and essential power loads
  • Power factor correction — sizing capacitor banks to meet utility PF requirements

Connected Load vs Design Load — Key Difference

The two most important figures in any electrical load calculation are the connected load and the design load. These are different and must not be confused.

Connected Load

The connected load is the sum of the rated power of all electrical equipment in the building, assuming every single item is running at 100% of its rated power simultaneously. This is the theoretical maximum — in practice it never occurs because not all equipment runs at the same time or at full load.

Connected Load (kW) = Sum of all equipment rated power in kW

Design Load

The design load (also called the maximum demand) is the connected load multiplied by demand factors that account for the reality that not all equipment operates simultaneously or at full rated power. The design load is what the electrical system must actually be designed to carry.

Design Load (kW) = Connected Load (kW) x Demand Factor

ParameterConnected LoadDesign Load
DefinitionSum of all rated equipment powerRealistic maximum demand
Demand factor appliedNo — assumes 100% everythingYes — accounts for diversity
Used forIndividual circuit sizingMain switchboard, transformer, generator
Typical ratio100%60 to 80% of connected load

What is Demand Factor in Electrical Load Calculation?

The demand factor is the ratio of the maximum demand of a system to its total connected load. It accounts for the fact that not all electrical loads operate simultaneously and not all equipment runs at its full rated power at the same time.

Demand Factor = Maximum Demand / Total Connected Load

A demand factor of 1.0 means 100% of the connected load is assumed to be on simultaneously — used for lighting and critical equipment. A demand factor of 0.5 means only 50% of the connected load is assumed active at peak — used for general power outlets in office buildings.

Load CategoryDemand FactorReference StandardNotes
Lighting — general1.0IEC 60364-3All lights could be on simultaneously
Lighting — emergency1.0BS 5266Must always be available
Office power outlets0.4 – 0.5CIBSE Guide KNot all outlets used at once
Dedicated workstations0.6 – 0.7CIBSE Guide KHigher usage than general outlets
Server room / IT0.9CIBSE Guide KNear continuous full load
Chillers0.8 – 0.9CIBSE Guide KPart load most of the time
AHUs and fans0.75 – 0.85CIBSE Guide KVariable speed drives common
FCUs and split ACs0.7CIBSE Guide KNot all spaces at peak load
Duty pumps0.75 – 0.85CIBSE Guide KVariable flow systems
Fire pumps1.0NFPA 20 / BS 9990Must always be available at full load
Lifts and escalators0.5CIBSE Guide KNot all running simultaneously
Catering equipment0.7 – 0.8CIBSE Guide KDiversity in kitchen equipment

How to Calculate kVA from kW

Once the design load in kW is established, it must be converted to kVA (kilovolt-amperes) to size the transformer, generator and main supply. The relationship between kW and kVA is determined by the power factor.

kVA = kW / Power Factor

The power factor is the ratio of real power (kW) to apparent power (kVA). A power factor of 1.0 means all the apparent power is doing useful work. In practice, electrical loads in buildings have power factors below 1.0 due to inductive loads such as motors and fluorescent lighting.

Building TypeTypical Overall Power FactorNotes
Modern office building (LED lighting, VFDs)0.90 – 0.95After PF correction
Commercial building without PF correction0.75 – 0.85Before capacitor bank
Industrial facility0.70 – 0.85Large motor loads
Hospital0.85 – 0.90Mixed loads
Data centre0.90 – 0.95UPS systems typically have good PF
Retail / Shopping mall0.80 – 0.90Mixed lighting and power

How to Calculate Current per Phase

The current per phase (in Amps) is calculated from the total kVA and the supply voltage. This figure is used to size the main incoming cables and the main incomer protective device.

For 3-phase supply:

Current (A) = kVA x 1000 / (Square Root of 3 x Voltage)

Current (A) = kVA x 1000 / (1.732 x 400)   — for 400V 3-phase supply

For single phase supply:

Current (A) = kVA x 1000 / Voltage

Current (A) = kVA x 1000 / 230   — for 230V single phase supply

Total kVACurrent at 400V 3-Phase (A)Cable Size (approx)MCCB Rating (A)
50 kVA72 A25 mm² copper100 A
100 kVA144 A70 mm² copper200 A
200 kVA289 A150 mm² copper400 A
315 kVA455 A240 mm² copper630 A
500 kVA722 A2 x 240 mm² copper800 A
630 kVA909 A2 x 300 mm² copper1000 A
1000 kVA1443 A3 x 300 mm² copper1600 A

Motor Efficiency and Electrical Load Calculation

When calculating the electrical load of motors — including HVAC fans, pumps, compressors and other mechanical equipment — it is important to use the electrical input power, not the shaft output power. The relationship between them is the motor efficiency.

Electrical Input Power (kW) = Shaft Power (kW) / Motor Efficiency

For example, a pump with a shaft power of 7.5 kW driven by an IE3 motor with 90% efficiency will draw 7.5 / 0.90 = 8.33 kW of electrical power.

IEC Efficiency ClassEfficiency RangeApplicationNotes
IE1 — Standard0.80 – 0.88Being phased outNot permitted for new installations in EU/UK
IE2 — High Efficiency0.84 – 0.91Limited applicationsBeing replaced by IE3
IE3 — Premium Efficiency0.88 – 0.95Standard for new installationsMandatory in EU, UK, Middle East from 2023
IE4 — Super Premium0.90 – 0.96High efficiency applicationsVFD driven motors

Power Factor Correction

Most utilities require buildings to maintain a minimum power factor — typically 0.90 or above. Buildings that fail to meet this requirement may face financial penalties on their electricity tariff. Power factor correction is achieved by installing capacitor banks that supply reactive power locally, reducing the reactive power drawn from the utility.

Required kVAR for PF correction = kW x (tan(arccos(existing PF)) – tan(arccos(target PF)))

Existing PFTarget PF 0.95kVAR per 100 kW loadNotes
0.700.9572 kVARLarge correction needed
0.750.9562 kVARSignificant correction
0.800.9542 kVARCommon in older buildings
0.850.9529 kVARModerate correction
0.900.9516 kVARMinor correction
0.950.950 kVARNo correction needed

IEC 60364 Requirements for Electrical Load Calculation

IEC 60364 (Electrical Installations of Buildings) is the primary international standard governing electrical load calculation and system design. Key requirements include:

  • All electrical installations must be designed with a minimum 20% spare capacity above the design load per IEC 60364-3
  • Demand factors must be applied based on the type of installation and actual usage patterns
  • Motor circuits must be sized for the full load current with an additional 25% for starting current per IEC 60364-4-43
  • Power factor must be maintained above the utility requirement — typically 0.90 minimum
  • Standby equipment must NOT be included in load calculations — only duty equipment
  • Fire protection systems must use a demand factor of 1.0 and must be supplied from a dedicated circuit
  • Hospital essential systems (Category 1 and 2) must have dedicated circuits with UPS and generator backup

Spare Capacity Requirements

IEC 60364 and most project specifications require a minimum spare capacity to be added to the design load before sizing the main electrical infrastructure. This spare capacity allows for future load growth and unforeseen additions without requiring a complete infrastructure upgrade.

Building TypeMinimum Spare CapacityReference
Standard commercial building20%IEC 60364-3
Hospital — general areas25%HTM 06-01
Hospital — critical care30%HTM 06-01
Data centre25 – 40%TIA-942 / Uptime Institute
Industrial facility20 – 25%IEC 60364-3
Mixed use development20%IEC 60364-3

Frequently Asked Questions

What is the difference between connected load and maximum demand?

The connected load is the sum of all rated equipment power assuming everything operates at 100% simultaneously — the theoretical maximum. The maximum demand (design load) is the connected load multiplied by demand factors that account for diversity — the realistic peak load the system must carry. The maximum demand is always lower than the connected load for buildings with mixed load types.

How do I calculate kVA from kW for a building?

Divide the design load in kW by the overall power factor to get kVA. For example, a building with a design load of 500 kW and a power factor of 0.85 requires 500 / 0.85 = 588 kVA of transformer capacity. Always add the required spare capacity (minimum 20% per IEC 60364) before dividing by the power factor.

What demand factor should I use for office power outlets?

Per CIBSE Guide K, general office power outlets should use a demand factor of 0.4 to 0.5 (40 to 50%). This means only 40 to 50% of the outlet capacity is assumed to be in use simultaneously at peak load. Dedicated equipment outlets such as server racks, photocopiers and AV equipment should use higher demand factors of 0.7 to 0.9.

Should standby pumps and fans be included in the electrical load calculation?

No — standby equipment must NOT be included in the electrical load calculation. Standby equipment only operates when the duty equipment fails and does not contribute to the normal running load. Including standby equipment would double-count the load and result in oversized and unnecessarily expensive electrical infrastructure.

What is a typical power factor for a commercial building?

A modern commercial building with LED lighting and variable frequency drives on HVAC equipment typically achieves an overall power factor of 0.88 to 0.95 after power factor correction. Without correction, the natural power factor of a commercial building is typically 0.75 to 0.85 due to inductive motor loads and older lighting equipment. Most utilities require a minimum power factor of 0.90.

How much spare capacity should I add to the electrical load?

IEC 60364-3 requires a minimum of 20% spare capacity above the design load for all new electrical installations. For critical facilities such as hospitals and data centres, 25 to 30% spare capacity is typically specified to allow for future expansion without requiring transformer or switchboard replacement.

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