Calculate demand charges on your electric bill. Enter peak kW demand and your utility's demand rate to understand this often-overlooked billing component.
Demand charges are a billing component based on your highest instantaneous power draw (measured in kW) during a billing period, rather than total energy consumed (kWh). They are common on commercial electricity bills and increasingly on residential bills in some states. A demand charge of $5–$20 per kW can add $50–$500+ per month to a commercial electric bill.
The utility measures your peak demand in 15-minute intervals throughout the month. The single highest 15-minute average becomes your demand charge for the entire month. This means a brief period of high power draw — like starting multiple large motors or running all HVAC systems simultaneously — can significantly increase your bill even if your total energy use is modest.
This calculator shows how demand charges affect your bill. Understanding this component is the first step to reducing it through load management, staggered equipment startup, and demand response strategies.
This analytical approach supports both immediate cost reduction and long-term sustainability goals, helping organizations balance economic and environmental priorities in their energy management.
Demand charges can represent 30–70% of a commercial electric bill but are poorly understood. This calculator isolates the demand component so you can evaluate load management strategies and demand reduction investments. Having accurate metrics readily available streamlines utility bill analysis, budget forecasting, and investment planning for energy efficiency projects and renewable energy installations.
Demand Charge ($) = Peak kW × Demand Rate ($/kW)
Result: $625.00/month
A facility with a 50 kW peak demand at $12.50/kW pays 50 × $12.50 = $625.00 in demand charges per month. Reducing peak demand by just 10 kW saves $125/month or $1,500/year.
Your electric bill has two main components: energy charges (total kWh consumed) and demand charges (peak kW during the billing period). Energy charges reflect how much electricity you use. Demand charges reflect the maximum rate at which you use it. Think of energy as gallons of water and demand as the pipe diameter.
Load sequencing: Program building controls to start HVAC units in stages rather than all at once. Battery storage: Install batteries that charge during low-demand periods and discharge during peaks to "shave" the demand spike. Demand response: Enroll in utility demand response programs to receive credits for reducing load during grid peaks.
A commercial building paying $15/kW/month can save $180/year for each kW of peak reduction. A 100 kW battery that reliably shaves 30 kW saves $5,400/year in demand charges alone. Combined with energy arbitrage on TOU rates, the payback period for battery storage is often 5–7 years for commercial facilities.
A demand charge is a fee based on your highest power draw (kW) during a billing period, measured in 15-minute intervals. It reflects the capacity the utility must maintain for your peak usage, regardless of how briefly that peak occurs.
Your smart meter records average kW demand in 15-minute intervals. The highest 15-minute average during the billing period becomes your peak demand. Some utilities use a 30-minute or 60-minute interval instead.
Stagger equipment startup, use building automation for load sequencing, install battery storage for peak shaving, shift non-critical loads to off-peak hours, and upgrade to energy-efficient equipment that draws less power. Documenting the assumptions behind your calculation makes it easier to update the analysis when input conditions change in the future.
A demand ratchet sets your minimum billing demand at a percentage (often 80%) of the highest peak in the past 12 months. This means a single month of high demand raises your minimum charge for an entire year.
Most residential customers don't pay explicit demand charges. However, some utilities are introducing residential demand charges, and time-of-use rates serve a similar purpose by pricing peak-period energy higher.
Solar alone reduces demand charges only if production coincides with your peak demand period. Since peak demand can occur any time (e.g., a cloudy afternoon), solar + battery storage is more reliable for demand charge reduction.