Streetlight Energy Savings Calculator

Project name

Used in exports and summary.

Number of fixtures *

Hours per night *

Days per year *

Existing wattage (W) *

Include driver/ballast losses if known.

New wattage (W) *

Use actual luminaire input power.

Electricity rate ($/kWh)

Demand charge ($/kW-month)

Set to 0 if not applicable.

Coincident factor (0–1)

Share of fixtures on peak billing interval.

Existing maintenance ($/fixture-yr)

New maintenance ($/fixture-yr)

Installed cost ($/fixture)

Rebate/incentive ($/fixture)

Analysis years

Used for NPV only.

Discount rate (%)

Emission factor (kg CO₂/kWh)

Use a local grid factor if available.

Reset

Example data table

Scenario	Fixtures	Existing (W)	New (W)	Hours/night	Rate	Annual kWh saved	Annual $ saved
Collector road upgrade	80	150	70	11	$0.12	28,864	$3,464
Residential corridor	120	100	45	10	$0.10	24,090	$2,409
Highway interchange	60	250	120	12	$0.15	34,164	$5,125

Example outputs assume 365 days/year and exclude demand and maintenance savings.

Formula used

Core energy math uses wattage, quantity, and operating hours.

Annual hours = Hours per night × Days per year
Annual energy (kWh) = (Wattage ÷ 1000) × Fixtures × Annual hours
Energy savings (kWh) = kWh_existing − kWh_new
Energy cost savings = Energy savings × Electricity rate
Peak kW saved = ((W_existing − W_new) ÷ 1000) × Fixtures × Coincident factor
Demand savings = Peak kW saved × Demand charge × 12
Maintenance savings = (Maint_existing − Maint_new) × Fixtures
Total annual savings = Energy cost savings + Demand savings + Maintenance savings
Net cost = (Installed cost × Fixtures) − (Rebate × Fixtures)
Simple payback = Net cost ÷ Total annual savings
CO₂ avoided = Energy savings × Emission factor ÷ 1000 (tCO₂/yr)
NPV = PV(annual savings over years) − Net cost

How to use this calculator

Enter fixture count and typical nightly run hours.
Add existing and proposed luminaire wattages.
Type your electricity rate and any demand charge.
Set a coincident factor if peaks apply to billing.
Include maintenance, installed cost, and rebate values.
Choose analysis years and discount rate for NPV.
Press Calculate to view results above the form.
Use Download CSV or Download PDF for reporting.

Baseline energy profile and operating assumptions

Streetlight energy use is driven by fixture wattage, quantity, and operating hours. In most municipal corridors, lights run 10–12 hours nightly, producing 3,650–4,380 annual hours. A 150 W legacy fixture operating 4,015 hours uses about 602 kWh per year. Scaling by 100 fixtures yields roughly 60,200 kWh annually, before demand or maintenance costs.

Retrofit impact on kWh and utility billing

Replacing legacy luminaires with efficient units reduces input power while maintaining illumination targets. If wattage drops from 150 W to 60 W, annual energy per fixture declines to about 241 kWh, saving roughly 361 kWh each year. Multiply by fixture count to quantify portfolio savings. When tariffs include demand charges, the coincident factor estimates how much kW reduction aligns with the billing peak interval.

Maintenance and lifecycle cost drivers

Ongoing maintenance often rivals energy savings in older systems. Lamp replacements, ballast failures, bucket-truck mobilization, traffic control, and callout labor add recurring costs. LED retrofits typically reduce relamping frequency and troubleshooting visits. Enter per‑fixture annual maintenance for existing and new systems to convert reliability differences into yearly savings that improve payback and net present value.

Budgeting, incentives, and financial performance

Installed cost per fixture should reflect materials, removal, disposal, controls integration, and commissioning. Incentives and rebates reduce net project cost; apply them per fixture to keep calculations transparent. Simple payback divides net cost by total annual savings. For capital planning, NPV discounts the annual savings stream over the analysis horizon, allowing consistent comparison across competing infrastructure upgrades.

Carbon accounting and reporting deliverables

Emissions avoidance depends on the grid’s kg CO₂ per kWh factor. Multiply annual kWh savings by the factor to estimate avoided kilograms, then convert to tonnes for reporting. Use local factors where available, especially for project financing or sustainability disclosures. Export results to CSV for spreadsheets, or PDF for submittals, audits, and stakeholder briefings. These estimates support grant applications, public dashboards, and transparent performance tracking over time.

FAQs

1) What wattage value should I enter for existing fixtures?

Use the measured input wattage when possible. If you only have lamp ratings, add typical ballast or driver losses so the baseline reflects real power draw.

2) How do I choose hours per night and days per year?

Use photo‑cell logs, control schedules, or seasonal averages. Many systems run 365 days, with 10–12 hours nightly depending on latitude and dimming strategy.

3) When should I include demand charges?

Include them if your bill has a $/kW line item tied to peak demand. If streetlighting is separately metered without demand billing, set demand charge to zero.

4) What is the coincident factor used for?

It estimates what share of the lighting load reduction occurs during the billing peak window. Use 0.6–1.0 if lighting is on during typical peaks.

5) How should I estimate maintenance savings?

Convert your work history into annual cost per fixture, including lamps, parts, labor, traffic management, and dispatch. Use a conservative LED value if warranties apply.

6) Why might my payback look unusually long or short?

Payback is sensitive to tariffs, run hours, net cost after incentives, and maintenance assumptions. Recheck units, fixture counts, and whether the new wattage is realistic.