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WOOD, PAPER & PULPS

Recover The Heat Your Dryers Throw Away

Drying, steam and CHP engineering for mills where heat is the product cost. We audit, design and verify the measures that cut energy per tonne without touching sheet quality.

Sector reality

Where The Energy Actually Goes

Four verified numbers that frame every energy conversation in this sector.

70%of pulp and paper energy use goes to drying
50 MW+recoverable heat in a modern machine's exhaust air
~50%of European paper sector electricity from on-site CHP
4thlargest industrial energy consumer worldwide

Sources: IEA, Valmet, Cepi, Global Efficiency Intelligence

The challenges

The Pressures Squeezing Every Mill

Six problems we hear from mill engineering managers, energy managers and operations directors.

  1. Dryer hoods heating the sky

    Warm, humid exhaust leaves the hood around the clock, and most of its heat goes straight to atmosphere. It is typically the largest recoverable energy stream in the building, yet it rarely has a project owner or a budget line.

  2. Steam systems degraded over decades

    Trap populations nobody has surveyed in years, bare pipework and valves, condensate dumped to drain and flash steam vented. Each loss looks small on its own. Added up across the distribution system, they quietly inflate every tonne you make.

  3. CHP dispatch built for yesterday's prices

    The turbine was sized and the dispatch logic written for a fuel and power market that no longer exists. The spark spread has moved through several cycles since commissioning, and what was once obviously profitable running may now be marginal.

  4. Moisture control trading off against energy

    Machine crews run the dryers hot and safe because a moisture excursion costs more than steam does. Without hood balance data and pocket ventilation control, the energy bill silently pays for that insurance every shift.

  5. Fibre and energy costs squeezing margin together

    Both of your largest input costs have risen at once, and you control neither price. Energy per tonne is the variable you can actually engineer, which makes specific energy consumption the most useful number in the monthly review.

  6. Biomass strategy unclear

    Bark, residues, gas and grid power all compete in the fuel mix, and carbon prices keep moving the answer. Without a current techno-economic model, boiler and fuel decisions stall, and so does the decarbonisation roadmap behind them.

What we engineer

What We Engineer In Your Plant

The sub-systems that set a mill's energy per tonne, and what we do with each of them.

  • Drying sections and hood heat recovery

    We measure the hood balance, raise exhaust dew point towards 60 to 65 degrees C and design multi-stage recovery to supply air, white water and fresh water.

  • Press section dewatering

    We assess shoe press performance, felt condition and nip management, because each percentage point of post-press dryness typically cuts dryer steam demand by roughly 4%.

  • Steam and condensate systems

    We survey traps, thermocompressors and cascade condensate loops, then specify the repairs, insulation and flash steam recovery that stop the losses.

  • CHP and biomass boiler optimisation

    We model turbine dispatch against current spark spreads and fuel mix so the plant runs for today's prices, not the ones it was commissioned for.

  • Vacuum systems

    We drop unneeded vacuum levels, add variable speed drives and evaluate liquid ring to turbo blower conversions, measures that commonly save 20 to 50% of vacuum power.

  • Refining loads

    We benchmark refiner specific energy, where TMP lines typically draw 2 to 3 MWh per tonne, and verify that refiner heat recovery to process steam is actually delivering.

  • Compressed air

    We fix leaks, lower pressure setpoints and right-size compressors, with 10 to 30% savings on the affected systems being a credible audited range.

  • Heat upgrading with MVR and heat pumps

    We evaluate mechanical vapour recompression and high temperature heat pumps for lifting hood exhaust and effluent heat back to low pressure steam.

EM3 engineering work at a paper mill dryer section
How we engage

How The Work Gets Done

Every engagement follows the same engineering discipline, whatever the sector.

  1. Audit

    Instrumented, engineering-led, and baselined against your production data.

  2. Roadmap

    A costed, sequenced register of measures your board can fund in steps.

  3. Delivery

    Designed and delivered around production, never in spite of it.

  4. Verify

    Savings measured against the baseline and verified to IPMVP.

Start With An Audit
Compliance

Regulation As A Roadmap

Regulation in this sector arrives with deadlines and carbon prices attached. Treated properly, it is a funded roadmap for the projects you already wanted to build.

  • EU ETS

    Every tonne of fossil CO2 from boilers and CHP now carries a market price, which changes project paybacks year on year. We quantify the carbon value of each measure and build it into a ranked abatement plan.

  • ISO 50001

    The standard demands an energy management system with real baselines and performance indicators, not a binder on a shelf. We build EnPIs such as specific steam consumption per tonne into daily operations and support certification.

  • CSRD

    Corporate sustainability reporting requires energy and emissions data that survives an auditor. Our sub-metering and monitoring and targeting infrastructure produces the numbers behind the disclosure, traceable from meter to report.

  • ESOS

    The UK scheme mandates recurring energy audits for large undertakings. We turn the compliance exercise into an investment-grade register for your mills, so the audit pays for itself in identified projects.

  • National audit schemes

    EU Energy Efficiency Directive obligations and national equivalents require periodic audits across member states. We deliver them to one consistent methodology across multi-country mill portfolios, with one point of accountability.

Your team

Engineers Who Live In The Mill

Your first conversation is with our commercial team. Delivery is by engineers who spend their weeks in dryer sections, boiler houses and turbine halls.

  • Daniele Dominguez

    Commercial Director

  • Senior Energy Engineer, Drying & Heat Recovery

    Owns hood balances, dew point control and the design of multi-stage heat recovery systems.

  • Steam & Utilities Engineer

    Owns trap surveys, condensate return, insulation programmes and boiler and CHP performance.

  • Energy Manager, Monitoring & Targeting

    Owns specific energy per tonne baselines, sub-metering design and IPMVP savings verification.

Go deeper

Field Notes For Mill Engineers

Articles and case studies on drying, steam and heat recovery, written by the engineers who deliver the work.

Common questions from wood, paper & pulps teams

How much heat can a dryer hood recovery system capture?

On a large modern paper or board machine, the exhaust can carry more than 50 MW of recoverable heat, equivalent to roughly 86 tonnes of steam per hour. What you actually capture depends on the sinks available: supply air, white water, fresh water and ventilation. Documented rebuilds have delivered around 14% site energy savings with payback inside one to two heating seasons. A hood balance and dew point survey tells you your machine's number before any capital is committed.

Does heat recovery affect sheet moisture control?

Not when it is engineered properly. Recovery sits on the exhaust side of the hood, downstream of the sheet. The work that raises recovery potential, balancing supply and exhaust air, controlling pocket ventilation and lifting exhaust dew point towards 60 to 65 degrees C, is the same work that stabilises the drying environment. We design around the machine's moisture profile and verify it before and after commissioning.

When does CHP still make sense?

Around half of the electricity consumed by the European pulp and paper sector is already produced on site through cogeneration, so the question is rarely whether to have CHP but how to run it. The economics swing with the spark spread, the gap between power price and fuel cost. We model dispatch against current fuel, power and carbon prices, and revisit it through each price cycle rather than leaving the plant on commissioning-era logic.