Staging · hold for filing — publish only after provisional is on file & §2870 clearance confirmed
CRYONIL Patent pending
Cryonil

Energy-recovery ventilation · cold-climate frost control

Frost forms in one corner. So we warm only that corner.

Cryonil predicts where an energy-recovery core will frost and steers recovered exhaust heat to that spot — holding it above freezing while the rest of the core keeps recovering. No whole-core defrost. No added heat.

See how it works IP & licensing
Core face · live thermal modelinteractive
−14°
+18° ● 0°C frost line

Push the outdoor temperature down and watch frost take the cold corner.

Coldest surface
Frost coverage
Recovery retained
— biased exhaust heat (when on)illustrative simulation

The problem

An energy-recovery core saves heat in winter — until it freezes.

Frost starts in one geometry-determined corner of the core face — where the coldest incoming supply air opposes the most-cooled exhaust — and spreads from there. Existing controllers sense a single threshold and respond by treating the entire core, wasting energy and interrupting recovery across all the passages that aren't frosting.

15–35%
Recovery efficiency lost during a conventional whole-core defrost cycle — while both air streams are interrupted
4–8×
Typical defrost cycles per hour at extreme cold — each one stopping ventilation and wasting the energy just recovered
<10%
Fraction of the core face where frost actually nucleates first — the rest of the core is defrosted for nothing
Conventional whole-core defrostproblem
Frost detected at threshold → entire core bypassed / recirculated → recovery stops for all passages → repeat every cycle.
Cryonil predictive responsesolution
Frost-prone region predicted → exhaust heat steered to that corner only → recovery preserved elsewhere → ventilation never interrupted.

The approach

Three ideas, working together.

Each is simple on its own. The combination — applied to a passive recovery core with no refrigerant circuit — is what makes the difference. Order matters: localize before you actuate, and actuate with recovered heat before adding any.

01 · Localize

Know where, not just whether

Spatially-resolved sensing across the core face — a temperature array, per-region differential pressure, a distributed fiber sensor, or a thermal model driven by inlet conditions — pinpoints the region approaching the freeze-and-dew-point threshold before frost accumulates.

02 · Bias recovered heat

Steer the warmth already there

Modulators — vanes, a segmented exhaust manifold, or variable inlet guide vanes — redirect a portion of the warm exhaust stream toward that region, lifting its surface above the threshold using heat the air is already carrying. No added energy source.

03 · Prevent

Hold the line, don't melt it

Acting before frost forms — with the minimum bias needed to hold the region above the criterion — keeps the corner safe while the rest of the core recovers normally, both air streams keep flowing, and ventilation is never interrupted.

Sensing & actuation

See it before it happens. Act where it matters.

The core insight is that a passive counterflow or crossflow ERV has a deterministic cold corner — geometry and inlet conditions tell you where frost will nucleate. Cryonil puts eyes there and the means to warm it without interrupting the rest.

ERV core cross-section · schematic

Zone sensing drives zone actuation.

Because a counterflow or crossflow ERV has a geometry-determined cold corner, sensing only needs to cover that region and its advance. The modulator deflects a calibrated share of the warm exhaust stream into exactly that zone — nothing more.

  • Sense Temperature array across the core face, per-zone differential pressure, or a distributed fiber-optic sensor reading the face in continuous segments.
  • Predict A thermal model driven by inlet temperature and humidity identifies the locus where surface temperature is predicted to cross the frost-formation criterion ahead of time.
  • Bias Modulating vanes, a segmented exhaust manifold with independent zone dampers, or variable inlet guide vanes deflect a portion of warm exhaust toward the cold corner using recovered heat already in the airstream.
  • Fallback A localized resistive heater at the cold zone is engaged only if frost indication persists after biasing. The whole core is never the target.

How it works

A continuous loop, not a defrost cycle.

Cryonil runs as background control while the ventilator operates normally. The order of operations is fixed: the energy-light move is always tried first, supplemental heat is the last resort, and the whole core is never the target.

01 · sense

Read the face

Spatially-resolved temperature and pressure across the core, plus inlet temperature and humidity at both supply and exhaust inlets.

02 · localize

Find the corner

Estimate — by measurement, model, or both — the region approaching the freeze-and-dew-point threshold. Track how a frost front would advance.

03 · bias

Steer exhaust heat

Redirect warm exhaust toward that region — the minimum needed to hold its surface above the criterion using heat the exhaust already carries.

04 · verify

Confirm margin

Watch the region recover its thermal margin above the criterion. Ease the bias back as conditions allow; apply hysteresis to prevent chatter.

05 · fallback

Only if needed

If frost indication persists despite biasing, engage a localized heater or zoned bypass — for that corner alone, never the whole core.

Core types

Three core geometries, one control framework.

Cryonil's frost-front localization and warm-exhaust-flow biasing apply across the three principal passive core types. The sensing array and modulator configuration adapt to each geometry; the control logic is the same.

Fixed-plate

Counterflow plate core

The most common ERV type. Supply and exhaust flow in opposing directions through alternating channels separated by flat heat-exchange plates. The cold corner is geometrically fixed at the supply-in / exhaust-out edge.

Primary application
Enthalpy membrane

Membrane ERV core

A semi-permeable membrane transfers both heat and moisture, improving winter humidification. Frost management must account for the additional latent-heat flux at the frost-prone zone — Cryonil's biasing addresses both sensible and latent conditions at the cold corner.

ERV-specific
Rotary wheel

Rotary heat / energy wheel

A slowly rotating desiccant or sensible wheel alternates between the supply and exhaust streams. The frost-prone zone is an angular sector rather than a fixed corner. Cryonil's framework targets that sector, biasing exhaust dwell in the frost-prone arc.

Sector-zoned control

How it compares

Point-by-point against conventional approaches.

The contrast with whole-core defrost is not just about efficiency — it's structural. Once you localize the frost zone and use recovered heat to hold it, the entire response architecture changes.

Attribute No defrost Whole-core defrost Cryonil
Frost prevention None — frost accumulates until blockage ~ Reactive after accumulation Predictive — acts before frost forms
Recovery during frost event Degraded as frost blocks passages Stopped across whole core during cycle Maintained across remainder of core
Ventilation continuity Reduced by blockage Interrupted each defrost cycle Both streams flow continuously
Energy for frost control Zero spent; damage accumulates External heat or recirculation energy Primarily recovered exhaust heat
Spatial sensing None Single threshold sensor Zone-resolved across core face
Targeted actuation None Whole core Frost-prone region only
Core type compatibility All (passively) All Fixed-plate, membrane, rotary

Why it holds up

Built to be different where it counts.

The distinctions below are not marketing language — they are the specific technical deltas that differentiate Cryonil from adjacent frost-control art in the heat-pump and refrigeration fields, where defrost is better developed but operates on fundamentally different hardware.

Passive core

Designed for plate, membrane, and rotary recovery cores with no refrigerant circuit — a structurally different world from heat-pump and refrigeration frost control, where the defrost mechanism is tied to the vapor-compression cycle.

Recovered heat first

The primary intervention reuses heat the exhaust stream already carries, rather than adding a heater as the primary actuator. The localized resistive heater is an explicitly sequenced fallback, not the lead mechanism.

Spatially localized

Recovery is preserved across the remainder of the face. The whole core is never bypassed or stopped. This is the outcome that no existing ERV defrost art achieves.

Predictive

Frost is prevented before it accumulates — no recovery loss from melting, no energy wasted defrosting passages that weren't frosted. The model identifies the locus before the criterion is crossed.

Adaptive

Model parameters adapt to the specific installation over time, forming a building-specific frost signature. Fleet data from networked units can further refine predictions without user intervention.

Minimum-bias control

The controller targets the minimum bias sufficient to hold the critical region above the criterion, then backs off as margin is restored — minimizing any distortion to recovery while keeping the corner safe.

FAQ

Common questions.

Marginally and controllably. Redirecting a fraction of the exhaust stream toward one corner does reduce the temperature differential in the unbiased regions slightly — but far less than stopping recovery altogether during a conventional defrost cycle. The controller minimizes the bias needed and backs it off as the margin is restored, so the net effect on seasonal energy recovery is strongly positive compared to whole-core defrost.
At extreme outdoor temperatures, the thermal lift available from the exhaust stream may be insufficient to hold the cold corner above the frost-formation criterion by biasing alone. In those cases the controller escalates: first engaging the localized resistive heater at the cold zone, and if frost still persists, triggering a conventional defrost cycle as a last resort. The point is to push that threshold deeper into extreme cold and reduce cycle frequency — not to eliminate defrost at all conditions.
That depends on the unit design. The sensing layer (a zone temperature array or differential pressure taps) can often be added to an existing core without redesign. The modulator — vanes or a segmented manifold — generally requires access to the exhaust inlet, which varies by unit. The cleanest integration path is as an OEM design-in rather than a retrofit, but the sensing-and-control layer is disclosed as independently licensable for both new designs and qualified retrofit opportunities.
Three structural differences. First, refrigeration cores have a vapor-compression refrigerant circuit — the core is cold because refrigerant is actively evaporating. An ERV passive core has no refrigerant; it is cold because supply air is cold. The physics and accessible actuators are different. Second, refrigeration heater placement is a static design choice at a known accumulation zone; Cryonil's approach dynamically estimates the frost-front location and actuates relative to a moving target. Third, and most importantly, the primary actuator in Cryonil is the redistribution of already-recovered exhaust heat, not an electric heater — heater engagement is the fallback.
Three tracks are under consideration: an OEM design-in license (the sensing and control layer embedded in a manufacturer's product line under a per-unit royalty), a technology assignment (full IP transfer for a qualified acquirer), and a research and development partnership for manufacturers who want co-development access before a non-provisional filing. All discussions begin with an NDA; substantive technical disclosure follows. Contact details are below.

Where it fits

For the climates that punish recovery cores.

Any building system that depends on a passive recovery ventilator in a cold climate is exposed to the frost problem Cryonil solves. The control framework adapts to the core type and the unit architecture.

🏠
Residential ERV / HRV

Whole-home recovery ventilators in cold-climate housing. These units frost early, cycle often, and have no occupant-visible warning that ventilation has stopped.

🏢
Commercial DOAS

Dedicated outdoor-air systems where recovery downtime carries real HVAC cost and potential code compliance issues. High duty-cycle units benefit most.

🔧
OEM integration

A sensing and control layer for core and unit manufacturers to license and embed at the design level, with per-unit royalty or design-in fee structures.

💧
Membrane & rotary

Enthalpy membranes and rotary wheels, where local moisture transfer interacts with frost onset. Cryonil's predictive model accounts for latent as well as sensible heat at the critical zone.

Intellectual property & status

Patent-anchored, disciplined, and gated.

Status
Provisional patent application
Coverage
Apparatus · method · system
Claims drafted
50 (independent + dependent)
Entity
Micro entity (USPTO)
Assignee
Cryonil Inc. (Michigan)
Portfolio
HeOntotita Corporation
Apparatus
24

Core claims on the ERV hardware assembly: sensing array, modulator, controller, supplemental actuators.

Method
19

Process claims on the localize-bias-verify-fallback control loop, including model-based prediction and adaptive learning.

System + CRM
7

Networked multi-core system claims and a computer-readable-medium claim anchoring the software layer.

Pre-disclosure note

Technical content on this page is intentionally high-level. Claim scope, sensing and actuation specifics, model detail, and test data are shared under NDA with qualified manufacturers and licensing partners after a provisional is on file and employment-IP clearance is confirmed.

Licensing tracks

OEM design-in

Embedded license

Sensing and control layer integrated into a manufacturer's product line. Per-unit royalty or upfront design-in fee. Includes field exclusivity options for primary product categories.

R&D partnership

Co-development access

Pre-non-provisional co-development for qualified manufacturers seeking to shape the specification. Early access in exchange for testing and validation collaboration.

Assignment

Full IP transfer

Complete patent assignment to a qualified acquirer. Available for a defined portfolio scope on negotiated terms.