A heat recovery heat pump system was deployed as the core, integrating high-efficiency centrifugal chillers, 27 modular heat pump units, and a thermal energy storage system — fully replacing the legacy steam cooling architecture. All installation and commissioning completed within 12 months. Building operations continued uninterrupted throughout.

Internal waste heat and condenser heat are captured and converted into usable energy, enabling combined cooling and heating supply. Steam consumption reduced by ~72% — the building shifted from passively consuming energy to actively recovering it.

Large-scale thermal storage enables off-peak charging and on-peak discharge, reducing electricity demand during high-cost peak hours.

• • Annual operating cost savings ~$1.5M
• • Annual Local Law 97 penalties avoided ~$1.2M
• • Government incentives and tax credits received ~$14.5M
• • Building EUI reduced ~20%

This project answers all three at once.

Compliance, cost reduction, zero disruption — results written into the contract, not promised in a sales pitch.

Containerized all-in-one design integrated pumps, controls, and auxiliaries into a single compact unit. The legacy system was replaced while the production line kept running — zero output lost.

Oil-free magnetic bearing design eliminates friction losses. Cooling efficiency rating jumped directly from 6 to 9, with measurable reduction in electricity consumption.

Oil-free operation eliminates routine lubrication system maintenance entirely. Free cooling mode further reduces energy consumption during favorable ambient conditions.

Low-GWP refrigerant R1233zd complies with European sustainability regulations. The facility now meets both production efficiency and carbon reduction targets simultaneously.

This project answers that directly. No downtime. No efficiency loss. Better cooling results from day one.

That is exactly how YCE delivers cooling outcomes.

The original gas CHP and steam network was replaced entirely with an electrically-driven heat recovery chiller system and hot/chilled water distribution network. Coverage extended to all 155 buildings via ~22 miles of new piping.

~10 million gallons of chilled water storage and ~2.3 million gallons of hot water storage installed. Enabled combined cooling and heating supply with grid peak-shaving.

CEPOM predictive optimization software dynamically dispatches every 15 minutes based on multi-variable forecasting. Campus primary electricity fully transitioned to 100% renewable sources.

• • Peak energy demand reduced ~17%
• • GHG emissions reduced 68–81%
• • Water consumption reduced ~18%
• • ~$520M projected economic recovery over 35 years

This project demonstrates one thing clearly: System-level energy restructuring can be completed without operational disruption — and the results can be quantified and guaranteed.

That is exactly how YCE delivers energy outcomes.

The steam turbine chiller replaces conventional electric motor compressors with a steam turbine drive — using steam generated by the campus CHP system to power cooling directly. Energy that was previously wasted is now producing usable cooling output.

Cooling no longer relies primarily on grid power. The facility's energy cost structure is fundamentally improved. Under conditions of adequate steam supply, electricity consumption drops significantly.

Cooling capacity range of 700–2,800 TR covers the full scale requirements of a large campus central chiller plant. OptiView control system provides real-time operational monitoring and dynamic optimization.

Steam generation → turbine-driven cooling → chilled water distribution — a complete energy recovery chain. Applicable to any facility with CHP infrastructure or large-scale steam loads.

This project makes the answer simple: The energy you already have can become the cooling capacity you need.

No large new investment required. No full system replacement. More results from resources already in place.

60MW installed capacity, stable grid-connected operation, fully compliant with North American 60Hz grid standards. [cite: 1390]

Designed to switch between Jatropha, bagasse, and other biomass feedstocks — reducing supply chain dependency and operational risk. [cite: 1391]

Full lifecycle responsibility from construction through to operational handover. The client committed no capital during the build phase and received a fully running asset at transfer. [cite: 1392]

Delivered using small F-class gas turbine technology — the first time this turbine class was deployed in a European overseas engineering project. A clear technical benchmark with replicable engineering value.

Coordinated with global gas turbine manufacturer Ansaldo across the supply chain, ensuring core equipment met international technical specifications and delivery standards.

Engineering, procurement, and construction managed under a single EPC contract.

700MW CSP provides dispatchable baseload power. 250MW PV supplements daytime generation. Together they deliver continuous, reliable electricity around the clock. [cite: 2228]

Tower-based wireless heliostat technology — one of the most advanced thermal solar approaches available. Deploying this at 700MW is an industry milestone in itself. [cite: 2229]

Delivered for DEWA — the most consequential public utility in the Middle East. Shareholders include DEWA, ACWA Power, and Silk Road Fund. Single-responsibility EPC delivery throughout. [cite: 2231]

Our team has delivered at the most demanding level this industry has seen.

The capability to be accountable for results applies to every project size. [cite: 2233]