In practice, it quickly becomes clear that the real challenge lies not in the stable, continuous operation of a cold storage facility, but in the transitional phases. It is precisely during these moments that conditions arise that overwhelm traditional humidity sensors.
A typical everyday scenario:
A warehouse door is opened > warm, humid outside air flows into the room > the cold air already in the warehouse is physically unable to absorb this Humidity
The result: Relative humidity rises locally to nearly 100% within a very short time. When the air exceeds the dew point, Humidity begins to condense, primarily on cold surfaces.
And this is exactly where the critical issue comes into play: The sensor itself is one of those cold surfaces.
You can think of it like a cold beverage bottle in the summer. The surrounding air “sees” the cold surface and releases Humidity in the form of condensation. For the sensor, however, this is not just a physical phenomenon—it’s a real measurement problem.
Impact on Measurement Technology
As soon as condensation forms on the sensor element, the measurement conditions change fundamentally:
- The sensor surface is no longer surrounded by air, but by a film of water
- The measured relative humidity no longer corresponds to the actual indoor air
- The signal waveforms become sluggish or erratic
In building automation, this manifests itself quite specifically:
- Measurements "stick" at 100% relative humidity.
- Control loops respond with a delay or incorrectly
- Dehumidification or ventilation is inefficient
Even more critical are the long-term effects:
- Repeated condensation places mechanical and chemical stress on the sensor element
- Deposits and residues from the air stick to the sensor
- This results in drifting and premature failure
Particularly in applications such as fruit and vegetable storage, where stable climatic conditions directly affect product quality, this is not only a metrological problem but also an economic factor.
Why Standard Sensors Reach Their Limits Here
Conventional humidity sensors are generally designed for “normal” HVAC applications—that is, for stable conditions without persistent humidity spikes or condensation events. What they lack:
- No active measures against condensation
- The sensor element is located directly in the airflow
- No distinction between sensor temperature and ambient temperature
This means that they function correctly as long as no condensation occurs. However, as soon as real-world operating conditions—with rapid changes in temperature and humidity—come into play, they operate outside their optimal range.
From a product manager's perspective, this can be clearly summarized as follows: The problem is not the maximum humidity—it is the dynamics and the phase changes between air and condensate.
It is precisely for these situations that specialized sensor technology is needed—technology that not only measures but also actively takes physical constraints into account.