Posts Tagged ‘Weather Compensation’

Weather Compensation: Experimental Tweaking

October 21, 2022

Friends, as I mentioned in my previous article, I have no real idea how to actually operate my 5 kW Vaillant Arotherm plus heat pump – or to check how well it is operating. That’s because there is no readable manual for the controller and the App does not do what it says it does.

But since I have an independent monitoring system, I have begun a series of experiments to tweak the heat pump weather compensation settings, and see what happens!

If ‘Reading the Manual is like taking a course in theoretical heat pumps, then this is more like a course in experimental heat pumps.

This is quite a technical article, and it is nearly 1500 words long. So if you are not really interested in heat pump arcana I would recommend giving this one a miss. On the plus side, it does have some nice graphs :-).

Weather Compensation

Weather Compensation is the idea that when the weather is mild, one can heat water in radiators or under-floor heating to a low temperature – perhaps just 25 °C. But when the weather is colder, and the heating demand is greater, one can increase the temperature of the hot water to perhaps 40 °C or 50 °C to meet the heating demand.

Using weather compensation to match the output of a heat pump to the heating demand contrasts with using a thermostat for the same purpose.

Click on image for larger version. The heating supplied to a dwelling can be changed to match demand in two ways. In a traditional thermostat-based system, the radiator flow temperature is fixed and switches on and off to maintain a constant indoor temperature. In contrast, using weather compensation the radiator flow temperature is adjusted.

In a thermostat-based heating system, the flow temperature to which water is heated is pre-set: in boilers it is often as high as 70 °C, and for heat pumps it might be 50 °C. And then to match heating to demand, the thermostat switches the heating source on and off intermittently to maintain the desired temperature.

Weather compensation is particularly valuable when using heat pumps because the coefficient of performance (COP) of the heat pump varies with both flow temperature and environmental temperature. But it can be tricky to adjust the settings for any heat pump, but especially one with no decent manual!

Weather Compensation in action

The graph below shows data taken every two minutes during the week from 00:01 on 11th October 2022.

  • The red curve shows the outside temperature
  • The grey dots show the instantaneous flow temperature.
  • The green curve shows the flow temperature averaged over 1 hour
  • The orange curve shows the internal temperature

Click on image for larger version. Weather compensation in action. When the outside temperature falls, the flow temperature in the radiators increases to maintain the internal temperature.

Notice that when the outside temperature falls, the flow temperature in the radiators increases to maintain the internal temperature.

But on day 4 of the period shown in the graph above, I changed the setting of the Weather Compensation from the curve labelled ‘0.6’ to the curve labelled ‘0.5’ in an attempt to lower internal temperature of the house. I’ll explain more about these labels below.

The graph below shows that average for the 4 days before the change was 21.0 °C and the average for the 3 days after was 20.76 °C: so it does seem to have had a small (0.24 °C) effect, but I will need to continue experiments – see the end of the article for an update.

Click on image for larger version. Graph shows the internal temperature of the house detail averaged over a period of 1 hour. The weather compensation parameter was changed on Day 4 and it does seem to have slightly lowered internal temperature.

It is striking to me how stable the internal temperature is given that – as I understand it – it is based entirely on measuring the temperature OUTSIDE the house – not INSIDE it!

COP

To evaluate the COP, one needs to work out the ratio of the heat delivered to the electrical energy used, over some set time period.

The hourly averaged COP is shown in the graph below. The times when the COP is greater than 4 correspond to times when the difference between the flow temperature and the outside temperature is small, and so not very much heat is being delivered with these high COP values.

Click on image for larger version. Graph shows the hourly averaged COP. Considering only use for DHW the average COP was 3.1 and considering only use for space heating the average COP was 3.9. Overall, considering both DHW and space heating across  the entire period the average COP was 3.7. These averages are shown as dotted lines on the figure.

With a little spreadsheet untangling it is possible to extract the data corresponding to periods when the heat pump is heating DHW and periods when it is heating water for space heating. For DHW the average COP for heating water to 50 °C was 3.1 and for space heating the average COP was 3.9. Overall, considering both DHW and space heating across the entire period, the average COP was 3.7.

Electrical and Thermal Power

Calculation of COP requires evaluation of both electrical power consumed and thermal energy delivered. The graphs below show both these quantities measured every 2 minutes throughout the week or so under consideration.

Click on either image for larger version. Graphs show hourly averages of electrical and thermal power. The DHW cycle runs once a night using cheap rate electricity. The separation of the two uses of the heat pump is not quite perfect: sorry.

Tweaks

So far I have just showed a week or so of data. Now I will explain what I hope to achieve with some ‘tweaks’ First let me explain, about how Vaillant implement Weather Compensation.

Their scheme is illustrated in the figure below. The flow temperature of water in the radiators is set depending the temperature outside. The sensitivity of the weather compensation is set by picking a curve labelled by a number from 0.1 to 4. For example, when the outside temperature is 5 °C,

  • the curve labelled 0.6 would result in a flow temperature of about 34 °C but
  • the curve labelled 0.5 would result in a flow temperature of about 32 °C

Click on image for larger version. The flow temperature of water in the radiators is set depending the temperature outside. The sensitivity of the weather compensation is set by picking a curve labelled by a number from 0.1 to 4. When the outside temperature is 5 °C, the curve labelled 0.6 would result in a flow temperature of about 34 °C but using the curve labelled 0.5 would result in a flow temperature of about 32 °C.

On Day 4 I adjusted the weather compensation from 0.6 to 0.5. To see if this tweak is working we can look at the second figure in this article in this article which I have reproduced below.

Click on image for larger version. On Day 4 the weather compensation setting was changed from 0.6 to 0.5. If we look at cold spells before and after the change it does look as though as the flow temperature is perhaps a degree or two than one might otherwise have expected.

If we look at cold spells before and after the change it does look as though as the flow temperature is perhaps a degree or two cooler than one might otherwise have expected. And since this article has taken a day or two to prepare, I now have a couple more days data on the internal temperature with WC curve 0.5. It does indeed seem to have maintained an internal temperature about 0.23 °C cooler than using WC curve 0.6.

Click on image for larger version. Updated version of the second graph in this article with 3 extra days data. The graph shows the internal temperature of the house in detail averaged over a period of 1 hour. The weather compensation parameter was changed on Day 4 and it does seem to have slightly lowered internal temperature.

Conclusion

My main conclusion is that the weather compensation adjustment does seem to be sort-of working. I will continue experiments and let you know how they go.

My second conclusion, is that observing these effects is really hard and it takes hours of analysis to unearth this kind of insight!

My third conclusion – which you may have already spotted – is that my 5 kW heat pump is just too big. It only needs to output 1,500 W to maintain a temperature of just over 20 °C in my home when the outside temperature is 5 °C i.e. with 15 °C of demand. This seems to indicated that a 3 kW heat pump would have been adequate to heat the home down to (say) – 5°C.

This oversizing is probably responsible (at least in part) for the rapid cycling on and off of the heat pump – exactly what weather compensation was supposed to avoid!

 


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