JohnMo

Not completely there is also the downward and upward heat transfer, how quickly the heat or cool is moved either upwards or downwards. Very good insulation below the pipes makes a difference. You would think so but, you also have to careful you stay a over condensation temperature. More cold water in floor equals a cold floor and risk of condensation. Plus your heat pump will alway manage the delta T between flow and return, get the floor too cold your heat pump permissive to start cooling again may not achieved, so your room go hot, cold,hot, cold.. it's all a balancing act. Ran my UFH on cooling today. Start temperature of the water in the floor was 20.5 degs. End of the day at 5pm when I turn off the system the water was returning at 17 degrees. Comparing the house temp today and yesterday in similar conditions, sun all day. Yesterday pumping the UFH around all day, but not cooling, living room was 27 degs, by this time, today cooling on 22, but feels cooler. Set ASHP with a 12 deg flow temp, (tried higher but delta T could not manage it) so ran once and didn't give a permission to restart. ASHP ran most of the day, switching of about a 10 times over a 9 hour period, living room 22 degrees, but felt cooler. That's with floor U value of 0.09 and 300mm spacing and circa 100mm concrete screed.

Work surface which is 3.5m long and the shelf are made from a tree we took down (Scottish larch) and we had it cut into planks. Work surface is made from 4 pieces cut, biscuit jointed and glued. Both the bench and shelf were then lime waxed. The units are Howden kitchen cupboards, instead of using the plastic feet and kickboard, I just made a 20mm plinth for the units to sit on.

Inside showing walls finished and the top finishing detail. The wooden parts are only attached to the ceiling and not the wall. They allow the roof/ceiling to move independently of the walls.

Update on summer house, photos to follow, once I complete the external paint. Walls are airtight and fully taped. Sliding doors are far from airtight, with gaps at top and bottom of each sliding panel. So would have been a bad candidate for MVHR. Instead have a single dMEV fan which runs while someone is in the room and for 30 mins after. UFH is all operating, and currently running in cooling mode, with the rest of the house. First day with cooling. Last night at 6pm it was circa 29 degs in the building with the internal blinds closed. Similar weather today so will see how it goes.

I did that with mine about 3 months ago, we have CO2 monitors for Scottish building regs, nothing undue has happened to CO2 levels, boost never or very rarely comes on. All is good so it stays in away mode all the time, the setting is mid way between minimum flow allowable and current set point.

A new build down the road is having 2 panels installed so they pass SAP. Roof is on and has been for quite a while. Next tiles are being removed for hangers to be installed and wires run. Just daft.

If you are installing MVHR just keep it simple. Push buttons for boost in wet rooms. Set the flow rates per building regs, until sign off, then reduce based on number of people in house. 90mm semi rigid, to easy to install, minimum number of runs and quite. Titon HRV, are good, made in UK with good technical and spares support. I had an issue and they were great. No call centres or people who have never seen a unit, trying to talk through a problem, like most companies these days.

Bit of a downer. I also looked at the gutter while I was there, so 10.mins cleaning panels, 30 mins cleaning gutter.

Noticed my DHW temperature was not very high temperature and we have a couple days of clear skies, so should have been plenty of excess solar electricity. So checked the PV output. Just over 1kW. Panels and roof covered a green film of pollen. Out with soapy water and hose pipe and 10 mins later over 2.5kW.

First question is they have just used building regs to size. Are you better than that, do you have good airtightness? By the way the price is bonkers, same answer even if an installed price. The ASHP unit is made by Midea.

But you can to a great degree just manipulate the flow rate through individual loop to correct for this. Increase or decrease the flow changes the delta T and therefore the mean flow temp. Anything below 20W/m2 heating requirement a 1 or 2 degree change in mean flow tamp has a big impact on heat output. Irrespective of pipe centres.

Sorry cannot answer your radon question, but your insulation looks rubbish, does even meet building regs? Not sure my choice would be Actis Hybris, you would be better using something like Frametherm 32. You also need an insulation layer inside the studs to get rid of the repeat thermal bridge, so a layer of 25mm or better 50-75mm PIR insulation or insulated plasterboard. Sorry not really the answer you were looking for. Pay once for insulation or every year on heating bills.

Not really a little water, there will be multiple loops, even with my 300mm centres I still have 28 litres just in the lounge, and there are another 7 loops..

Yes.

Plenty of people take a slice of the cake to get from manufacturer costs, to the consumer cost. Import duty, vat, wholesaler profit, retailer profit, transportation etc.

There is always a bleed through from the return to the supply, tried two different types of mixer, a Reliance and Ivar, both have the same outcome. Was wanting to flow 26 degrees into the UFH loops, but had to operate the weather compensation curve higher to achieve it, about 3 to 4 to degrees hotter. Which is rubbish. If you are on the same floor, no need for mixers at all, in my opinion, others will not agree. Not sure where any benefit comes from a buffer with thermostat, as it cancels out running weather compensation. Just let it float on return temperature. Loop spacing, extremely small difference in flow temp if your W/m2 is below about 20. At 20W/m2 your mean flow temp at 100mm spacing is 26 deg, while at 300mm centers it has jumped up to 28 deg. The further below 20 you go the smaller the difference.

Why go abroad city plumbing. Plus currently you get 10% off that price.

It's not that cheap to run making DHW, with an ASHP, its cheaper than direct electric heating, by a margin of two and bit. But preheating a single big cylinder to 50 or so via ASHP and topping up to 60+ via an immersion isn't much worse than a heat pump. Plus a big single cylinder of x capacity had a daily heat loss that is way less than 2x smaller cylinders of half the capacity each due to the extra surface area. Plus you also have parasitic losses of the piping x 2.

It sounds like the the cylinder set point is too high. So the heat pump runs to max temperature stops and restarts and keeps doing this. Your set point should be say around 48. What temp are you trying to achieve in the cylinder and from the cylinder nameplate it should state the coil size. So can you confirm cylinder set point, and coil size?

Novel solution...

No buffer equals big zones only, so possibly only one zone per floor, but you need to calculate the water volume for each zone to ensure it meets your specific heat pump requirements. I have a small zone (2x50m loops) the thermostat can switch the zone off but not on, as the volume is way to small to run on its own, without a buffer. 1. temp probe, when temp hits a defined limit, the ASHP drives a 3 port valve to DHW and ramps up flow temperature. 2. My ASHP gets a trigger from the single house thermostat, call for heat ASHP starts, no call ASHP goes into standby mode 3. Not sure your assumption is correct. The WC curve does not take anything from the thermostat or room temps. It's a basic, when external temp is X, flow temp will be Y, straight line curve. Even if it did UFH is way to slow to react to take room temp in to account. It just chases its own tail (been there, done it) 5. If you want a stat on each loop you need a buffer sized for the smallest loop. 6. You could do away with the wiring centre and control the pump directly by the thermostat. I dumped the manifold pump and mixer, as they incurred a temperature drop across the mixer of 3 to 4 degs, cooler but with two floors and different flow temps you maybe need one or both.

So what do you mean when you say runs like a boiler. From what I can see you seem to run at 2t degrees or on DHW.

Or just running everything too hot, for too short a period, therefore getting a rubbish CoP. Basically trying to run like a gas boiler.

You would cheaper to just top up temperature with your immersion, if you needed too. A constant standing loss for each cylinder would be 1.5 to 2kWh per day. So not sure why you would want that. Or just add an inline electric heater, use your single cylinder as the main source of hot water, heated by ashp, then if the temperature drops below a set level, the inline heater kicks in.

If your UFH is running at 45 your CoP will not be much better than 3, if your running the UFH for short periods then CoP will drop from that. Running at 35 your CoP jumps to 4, so you use 33% less electric. UFH runs better if you run for a long periods at the lowest possible temperature. You need to drop the temperature on the heat pump controller, not the mixer on the UFH manifold as such.