Weather compensation
What is weather compensation?
Weather compensation is designed to automatically adjust the temperature of the water fed to the radiators by your boiler in response to the current weather. This allows the boiler to run at a lower power when the weather is milder, but to automatically increase output when it is colder.
The advantages of weather compensation:
- Higher boiler efficiency - a modern condensing boiler can recover more energy from the flue gases with lower water return temperatures. This leads to lower fuel bills.
- Better comfort with fewer temperature overshoots.
- Less system noise, cooler water results in less thermal expansion - so less clicking and clanking of pipework and radiators.
How does it work?
At its most basic level, weather compensation needs two capabilities: a way to sense the external temperature, and a way to control the temperature of the water flowing round the radiators.
An external thermometer (usually placed high up on an north facing outside wall, away from direct sunlight), allows the system to sense the external temperature. Knowing the temperature the compensation system can increase the flow temperature on colder days, and reduce it on milder ones.
Modern boilers with electronic controls have facilities to modulate their output power to control the temperature of the water they produce. Older fixed output boilers can use external electrically controlled blending valves, to mix some cooler return water with the hot flow water to control the temperature of the flow water.
Weather compensation can also be used with thermal stores and heat bank style systems where the boiler does not directly heat the water circulated through the radiators or under floor heating. This is typically achived with controllable blending valves, or variable speed pumps.
Tuning the system
The big unaccounted for variable is of course the weather and the thermal performance of the building. Most compensation systems just work from an external temperature reading (an ideal one might also include wind speed and humidity). The temperature can then be mapped to a target flow temperature using a transfer function or lookup table that relates the external temperature to the required flow temperature.
The installer of the system will need to choose the correct mapping based on how quickly the property looses heat, and how easy it is to get back up to the desired temperature. Modern well insulated and relatively air tight properties should loose heat less quickly than older solid wall properties with little or no insulation.
A heating system designed with large radiators will likely be able to adequately heat a place at a lower flow temperature than one with smaller radiators.
So in mild weather, relatively low flow temperatures around 40°C are likely to take the chill off, and keep the place feeling comfortable. In a well insulated place with large radiators, it might be possible to adequately heat a well insulated place all year round with the flow temperature never needing to exceed 50°C. A more "difficult" property might need flow temperatures nearer 80°C in the depths of winter.