Circulating Pump settings

John.G wrote: »

As far as I can interpret the pump curves, PP1 will operate between 2M & 1M and PP2 between 4.5M and 2.25M.....I don't think that you can set PP1 or PP2 on any particular "speed". I would suggest PP2 and see how that goes. If the rads are still slow to heat then change to FP2 which will try and maintain a constant 4.5M...if all else fails you can go to constant speed iii (ii is probably a little low as it corresponds to a 3.2M pump).
I installed a Wilo Pico Yonis 1-6 a few weeks ago and settled on a PP setting of 4.0M which gives a flow rate of 12LPM @ 3M head with all rads and coil full on which gives a 20 Kw boiler a temperature rise of ~ 22/24C. I have 6 double rads & 4 singles.

John.G wrote: »

I did mine in the following manner (but I have all the time in the world to play around with the settings) I measured the boiler deltaT with everything opened up fully with the old pump in service and then just tried different PP settings until I got the same DeltaT with the Wilo. The higher you set the PP the higher the flow rate for any given condition. If I was in the trade and in a hurry I would be inclined to use the CP rather than the PP settings and if available set it at between 3.5M and 4.5M. or just go to the tried and trusted fixed speed setting of 2 or 3.

John.G wrote: »

Sorry, yes, I meant constant pressure.

John.G wrote: »

The HM 4-7 is I think a re badged DAB Evosta 4-7. It has 6 PP settings and 3 constant speed settings but no CP settings. Of the 6 PP settings, setting 5 &6 are probably the most applicable, PP5 is 3.8M to 1.9M & PP6 is 5.0M to 2.5M. The three constant speeds are (1) 4.2M, (2) 5.5M & (3) 7.0M.

I would suggest either PP6 or constant speed 2.

http://www.heatmerchants.ie/v4/581ae913-e1fb-435e-a88b-ded312da5b38/uploads/HM%20PROflyer.pdf

John.G wrote: »

You may find the attached link of interest: http://www.tasonline.co.za/toolbox/pipe/velfirc.htm

You can quickly calculate pipe velocities,dynamic head,friction loss, and orifice sizing.
rem (approx) 1/2"qual pex ID=11.3MM. 3/4"qual pex ID=16.7MM & 3/4" copper ID=19.0MM. I cant find a bit of 1/2" copper pipe just now to measure its ID.

John.G wrote: »

You may find the attached link of interest: http://www.tasonline.co.za/toolbox/pipe/velfirc.htm

You can quickly calculate pipe velocities,dynamic head,friction loss, and orifice sizing.
rem (approx) 1/2"qual pex ID=11.3MM. 3/4"qual pex ID=16.7MM & 3/4" copper ID=19.0MM. I cant find a bit of 1/2" copper pipe just now to measure its ID.

John.G wrote: »

They do but I would think that the 3 or 4; 1/2" parallel circuits would have less of a pipe friction loss than than 2 X 3/4 ins headers with 1/2" short rad tails.

John.G wrote: »

OK then if you had 12 rads, each with a total run of 20M of 1/2" pipework and each emitting 2.0 KW with a deltaT of 15C. By calc the flow rate through each one is ~ 1.9 LPM and the pipe friction loss is 0.29M but because the 12 rads have parallel circuits then the total head required is still only 0.29M so for those 12 rads you still only need a 0.29M head for a flow rate of 22.8 LPM to overcome the pipe friction losses, the flow rate is cumulative but the head is not. Now if you assume another 0.29M head loss through each rad and valve fittings then the total head loss is 0.58M, add another 20% for pipe fittings losses and you need a total of 0.7M head for a flow rate of 22.8 LPM with a total of 12 rads.

There are bigger losses in the 3/4" supply& return pipes as some of these must carry the full flow rate of 22.8 LPM. these losses are then added to the above to arrive at the final pump head required to give that flow rate. Maybe 1"
pipes are fitted or should be which would then give a reasonably low total head requirement.

John.G wrote: »

Just to be clear on the above re "Just got a call to say rads are slow to heat", what setting did you finally settle for and what are/were the watts?.

John.G wrote: »

I reckon if you were on Auto, it would have corresponded to a PP setting of 3M, using CP setting there are still reasonable savings to be had especially where zoning is used as the pump efficiency is still very high at the reduced flows/speed

I have attached some light reading for the Christmas period!!. re Auto (adapt).

John.G wrote: »

I won't pretend that I fully understand the Auto Adapt but I do get the gist of it.
No matter how clever it is it is still a compromise like the PP setting but in a properly installed heating system probably has big benefits.
Most installations that you and others will be doing will be replacing fixed speed pumps, as quite a lot of these will have been "over headed" then some customers will complain about slower warm up times with even a properly configured A rated pump so you are inclined to set them to high heads to keep the customer happy vs a completely new installation where there is no comparison to make.

Re Auto Adapt, yes it looks like its continuously bedding in/adapting.
The CP setting you choose was probably the correct one, a lower setting would probably have done but the Tucson has only two settings, 4.5M & 2M, the 2M would IMO be pretty useless in a whole house heating scene.

The Wilo has incremental 0.1M settings from 0.5 to 6M heads available in all modes except the 3 fixed speeds, here are a few readings I took over the past few weeks.

Rads+cyl coil (cold start) : PP4 (4m head) 24/27W CP4 (4M head) 26W
Rads+cyl coil (fully hot house) : PP4 (4m head) 16/18W CP4 (4M head) 20W

Rads only (cold start) : PP4 (4m head) 21/23W CP4 (4M head) 24W
Rads only(fully hot house) : PP4 (4m head) 14/18W CP4 (4M head) 19W

cyl coil only (hot or cold) : PP4 (4m head) 16W CP4 (4M head) 22W

ONE rad only i/s full open.:PP4 (4m head) 10W CP4 (4M head) 20W

Should also have said that the Tucson on Auto gave a reasonable result as at 20W it would/should have been circulating ~ 80% of the flow at 4.5M head if it was producing a 3M head (on auto)
It would be informative if any readers with these A rated pumps posted their settings.

John.G wrote: »

Didn't want to start a new thread but the following is interesting, I went to start up my Wilo Yonos Pico 6M pump yesterday around midday but found it wouldn't start, the ambient temperature was ~ 20c but the Firebird Heatpac enclosure where the pump is installed was 36/38C (sun shining directly on it) as measured with a digital thermometer.
The user's manual states -10C to 40C as the operating conditions so I presumed that this was preventing the pump from starting as it did start when the enclosure temperature fell to ~ 32C. I rang Wilo (Dublin) and they were of the opinion that it was indeed this high enclosure temperature was/is the problem. While discussing with them I did say that the pump just didn,t run but on reflection (but didn't mention this to them) I am surprised that it didn't flag a error code as one of these codes, E30 states "Fault: Excessive temperature of module" Cause: Module Interior too warm".
I will keep a good eye on it when running under normal conditions as I'm not entirely convinced of the pump's health in the absence of any fault code.

John.G wrote: »

I have just ran the burner+circ pump to the hot water cylinder coil for the past hour or so, flow/return temps 75C/62C, enclosure temp 35/40C, "plastic" module/motor temperature 45C/52C with no problem for pump stop/starting so a bit strange to say the least, even in winter and even though I've the pump installed on the boiler return I would expect that plastic module to be well in excess of 40C because of its close proximity to the pump body. I will have to keep a very good eye on this, as I stated previously, I find it hard to believe that IF temperature protection has operated that it doesn't flag a error code as this pump has error codes for all sort of faults.

John.G wrote: »

Yes, I did and even ran a separate supply to the pump, I also changed the plug top and checked that I was getting L(238V) & N at the other end of the quick connect end, the pump was certainly getting power as you would hear a click when plugging in but nothing else, you also hear this click under normal operating conditions.