EBICO Non-Standard Burners are engineered for projects where “standard models” cannot meet real operating conditions. Instead of forcing your process to fit a fixed product, we design combustion solutions around your fuel characteristics, furnace structure, control requirements, and emission targets—helping you achieve stable heat output, safer operation, and long-term reliability in demanding industrial environments.
Waste incineration applications require a burner that can handle highly variable feedstock and harsh combustion environments. Fuel composition and calorific value can fluctuate, while dust, corrosive compounds, and high-temperature duty create challenging conditions for flame stability and component durability.
EBICO waste incineration burners are built to support reliable ignition, stable flame holding, and controllable heat release, with safety-oriented operation for continuous-duty systems. This makes them suitable for municipal waste, industrial waste, and specialized treatment lines where uptime and process stability are critical.
Biogas and biomass-derived gases introduce a different set of non-standard demands: low or unstable heating value, fluctuating pressure, and potential impurities.
EBICO biogas burners are designed to maintain consistent combustion even when gas quality changes, supporting cleaner energy projects and circular-economy systems. Whether the goal is process heating, boiler support, or integrated thermal systems, our biogas burner solutions focus on stable modulation, dependable flame performance, and practical adaptability for real-world fuel conditions.
For industries such as chemicals, petrochemicals, and complex retrofit projects, the “non-standard” requirement often comes from the installation itself—limited space, special interfaces, unique furnace geometry, or advanced control logic. EBICO custom burners are engineered-to-order, enabling application-matched design for capacity range, flame shape, mounting method, and automation integration (PLC/DCS). With this project-driven approach, the burner becomes a coordinated part of a larger system—supporting commissioning, stable production, and ongoing optimization.
