All CH Experts...

Background

Conventional Ideal FF380 80,000btu Boiler
13 Rads (No TRV's) and Programmable Thermostat
System just balanced - temp drop of 11/12 degree C
across all rads and boiler. Pump speed on minimum.

Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

It only tends to happen in the morning when warming
the system up from cold. When demand is triggered
during the day/evening to top up the temp it seems
to fire continuously until the room stat is satisfied.

Obviously this is the boiler stat turning the boiler
off but I wouldn't of thought this would happen as the
flow temp from the boiler is 74 degree C and the return
about 62 degree C.

Is the problem the amount of time it takes to heat the
house up in the morning?

Is it a problem or am I concerning myself about something
that isn't a problem

If it's a problem is there a solution?

Cheers

Nige

If it's a problem is there a solution?

The solution is to use a boiler that has a modulating burner. Then, it just
turns down the heat when the flow temperatures get too high. I suspect the
difference between morning and evening is that the house gets up to
temperature before the flow temperature goes too high. This is because it is
warmer in the evening than the morning. Deeper into winter, you'll probably
find it does it in the evening too.

I wouldn't worry about it. It is slightly inefficient, that's all. It is why
they developed modulating burners.

Christian.

"Nigel Percy" wrote in message
om...
All CH Experts...

Background

Conventional Ideal FF380 80,000btu Boiler
13 Rads (No TRV's) and Programmable Thermostat
System just balanced - temp drop of 11/12 degree C
across all rads and boiler. Pump speed on minimum.

Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

It only tends to happen in the morning when warming
the system up from cold. When demand is triggered
during the day/evening to top up the temp it seems
to fire continuously until the room stat is satisfied.

Obviously this is the boiler stat turning the boiler
off but I wouldn't of thought this would happen as the
flow temp from the boiler is 74 degree C and the return
about 62 degree C.

Is the problem the amount of time it takes to heat the
house up in the morning?

Is it a problem or am I concerning myself about something
that isn't a problem

If it's a problem is there a solution?

Cheers

Nige

I suspect that the boiler is a bit too powerful for the job it's doing - and
is simply cycling on its own stat to maintain the set flow temperature. If
this is a problem, you could try de-rating it a bit by reducing the gas
pressure. [If you look at the installation handbook it will probably have a
table showing heat output vs gas pressure].

If you do this, of course, it will be a bit slower to heat up on really cold
days.

As others have said, a modulating boiler would vary its output
automatically - but it's a bit drastic to throw away an otherwise perfectly
good boiler!

Roger

"Nigel Percy" wrote in message
om...
All CH Experts...

Background

Conventional Ideal FF380 80,000btu Boiler
13 Rads (No TRV's) and Programmable Thermostat
System just balanced - temp drop of 11/12 degree C
across all rads and boiler. Pump speed on minimum.

Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

It only tends to happen in the morning when warming
the system up from cold.

This may be the boiler stat faulty or a slow running pump. I assume the
house is still cold and the thermostat is calling for heat.

- The heat appears not to be getting out of the boiler fast enough
- the boiler stat is faulty,
- the boiler is way too large.

When demand is triggered
during the day/evening to top up the temp it seems
to fire continuously until the room stat is satisfied.

So all is right when the room stat is in control. It may have a boiler
anti-cycle function so all is fine when it is mainly in charge.

Obviously this is the boiler stat turning the boiler
off but I wouldn't of thought this would happen as the
flow temp from the boiler is 74 degree C and the return
about 62 degree C.

Is the problem the amount of time it takes to heat the
house up in the morning?

Is it a problem or am I concerning myself about something
that isn't a problem

If it's a problem is there a solution?

Needs a little more observation and seeing if the boiler is too big.
Cheers

Nige


---
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Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

Could the boiler stat be set too low?

Sparks...

On 26 Nov 2003 01:42:27 -0800, (Nigel Percy) wrote:

All CH Experts...

Background

Conventional Ideal FF380 80,000btu Boiler
13 Rads (No TRV's) and Programmable Thermostat
System just balanced - temp drop of 11/12 degree C
across all rads and boiler. Pump speed on minimum.

Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

It only tends to happen in the morning when warming
the system up from cold. When demand is triggered
during the day/evening to top up the temp it seems
to fire continuously until the room stat is satisfied.

During the morning warm-up, the flow temperature will probably be at its
highest after the longest "burn" - I assume from what you say about later
demand that the periods are much shorter ? 2 mins on/2 mins off is not
really a great problem in terms of lost efficiency.

However, I note you say you have a fairly powerful boiler and a lot of
radiators. I have a similar configuration, but my boiler pump is set on
max. Anything less and the boiler will "trip" more often. The rads on my
system vary from about 1/2 turn open to almost fully open to achieve an
acceptable balance. (They all have TRVs too, however, although I did the
balancing when they were all demanding heat.) Anyone care to comment on
whether boosting the pump a little might help the OP ?

--
Insanity is hereditary - you get it from your children.

Mail john rather than nospam...

"Sparks" wrote in message
.. .
Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

Could the boiler stat be set too low?

Good point. the stat should always be near to or at the top of the range.


---
--

Checked by AVG anti-virus system (http://www.grisoft.com).
Version: 6.0.542 / Virus Database: 336 - Release Date: 18/11/2003

"John Laird" wrote in message
...
On 26 Nov 2003 01:42:27 -0800, (Nigel Percy) wrote:

All CH Experts...

Background

Conventional Ideal FF380 80,000btu Boiler
13 Rads (No TRV's) and Programmable Thermostat
System just balanced - temp drop of 11/12 degree C
across all rads and boiler. Pump speed on minimum.

Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

It only tends to happen in the morning when warming
the system up from cold. When demand is triggered
during the day/evening to top up the temp it seems
to fire continuously until the room stat is satisfied.

During the morning warm-up, the flow temperature will probably be at its
highest after the longest "burn" - I assume from what you say about later
demand that the periods are much shorter ? 2 mins on/2 mins off is not
really a great problem in terms of lost efficiency.

However, I note you say you have a fairly powerful boiler and a lot of
radiators. I have a similar configuration, but my boiler pump is set on
max. Anything less and the boiler will "trip" more often. The rads on my
system vary from about 1/2 turn open to almost fully open to achieve an
acceptable balance. (They all have TRVs too, however, although I did the
balancing when they were all demanding heat.) Anyone care to comment on
whether boosting the pump a little might help the OP ?

I mentioned that. I would first turn the stat right up and see how that
works. No joy, then increase the pumps speed, assuming it is not at full
speed anyhow. Ensuring that the boiler is matched to the house is another
point. If too large then see if the burner can be turned down via the
governor.


---
--

Checked by AVG anti-virus system (http://www.grisoft.com).
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Simple trick would be to turn up the boiler stat slightly, and turn down
the pump speed. But don't use this method as a permanent fix!

"IMM" wrote in message
...

"Sparks" wrote in message
.. .
Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

Could the boiler stat be set too low?

Good point. the stat should always be near to or at the top of the range.


Does this apply to (back boiler) gravity fed systems too?

"manoman" wrote in message
...
"IMM" wrote in message
...

"Sparks" wrote in message
.. .
Problem:-
The boiler will fire continously while the house is
warming up from cold in the morning but for a short
period just before the room stat is satisfied the
boiler will short cycle, Fire for 2 mins off for about
the same duration. This will happen until the room
stat switches the boiler off.

Could the boiler stat be set too low?

Good point. the stat should always be near to or at the top of the
range.

Does this apply to (back boiler) gravity fed systems too?

All non condensing boiler should be on high temperatures to avoid
condensation occurring in the burner box.


---
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All non condensing boiler should be on high temperatures to avoid
condensation occurring in the burner box.


How do I know if I have a condensing boiler? It was in the house when I
moved in, and there are no instructions for it.

Bob

How do I know if I have a condensing boiler? It was in the house
when I moved in, and there are no instructions for it.

It probably isn't. Does it have a make or model? What does the flue exit
look like and what route does it take? If it is short (i.e. straight through
the wall), it will plume noticeably if condensing.

Christian.

On Thu, 27 Nov 2003 09:17:22 -0000, "Christian McArdle"
wrote:

How do I know if I have a condensing boiler? It was in the house
when I moved in, and there are no instructions for it.

It probably isn't. Does it have a make or model? What does the flue exit
look like and what route does it take? If it is short (i.e. straight through
the wall), it will plume noticeably if condensing.

I would have thought the whole point of a condensing boiler is that the
exhaust contains little or no water vapour. A condenser will have a
permanent drain, although this could of course be coupled to the pressure
relief plumbing and not be immediately obvious.

--
Some drink from the fountain of knowledge, others gargle.

Mail john rather than nospam...

I would have thought the whole point of a condensing boiler is that the
exhaust contains little or no water vapour.

This would only happen if the flue is long enough for all the water to be
removed, or the return temperature is very low. If the return temperature is
around 60C, then the boiler fundamentally can't cool the flue gases any
lower that this. Those gases would then still contain water that will only
condense out when the temperature drops further, either within the colder
flue (if it is long enough) or upon exposure to colder air (at the
terminal).

Any condensing on the flue or outside air is wasted energy. That is one
reason why greater efficiency occurs at lower return temperatures. More
condensing can then occur upon the heat exchanger itself, where the energy
can be usefully recovered. (There are also thermodynamic reasons for greater
efficiency at low temperatures that apply to all boilers, not just
condensing types).

Christian.

On Thu, 27 Nov 2003 11:32:18 +0000, John Laird
wrote:

On Thu, 27 Nov 2003 09:17:22 -0000, "Christian McArdle"
wrote:

How do I know if I have a condensing boiler? It was in the house
when I moved in, and there are no instructions for it.

It probably isn't. Does it have a make or model? What does the flue exit
look like and what route does it take? If it is short (i.e. straight through
the wall), it will plume noticeably if condensing.

I would have thought the whole point of a condensing boiler is that the
exhaust contains little or no water vapour. A condenser will have a
permanent drain, although this could of course be coupled to the pressure
relief plumbing and not be immediately obvious.

It very much depends on the design and operational conditions of the
boiler.

The important thing to realise is that the extra energy recovered when
condensing is due to the latent heat of condensation. This is the
change of state of water from the gaseous phase (steam) to the liquid
phase (water). Heat is given up as a result of this change, just as
extra heat is required at boiling point to turn water to steam.

It's important to note that water vapour (that you see) is *not* steam
- it is fine droplets of liquid water. By the time that you see the
plume, the energy release has already occurred.
Thus from the perspective of efficiency, it doesn't matter whether the
water vapour is collected inside the boiler or goes out through the
flue.

Some designs of boiler and heat exchanger appear to be better than
others in terms of how much pluming happens, but it does not appear to
significantly affect the efficiency. If you look at the SEDBUK
tables, most recent boilers are in the 90-91.3% range and the
variation is fractions of a percent between them and not statistically
significant. There are still a few older models that are in the mid
to high 80s range, but are older designs.

It is possible that in some of the older designs that the heat
exchanger(s) has/have not condensed so much of the steam to water
vapour and that some is escaping in gaseous phase through the flue,
and condensing to water vapour as soon as it hits the outside air.
Since there are so many models bunched together in efficiency terms at
the top 90-91% range, it suggests that they are reaching the limits on
design and physics for the technology.

There are certainly different burner designs. Most of the good
quality products have a downward facing burner and stainless steel
heat exchanger, to improve performance and deal with the acidic
condensate. The older ones tended to have more conventional burners
and heat exchangers and a second heat exchanger after the main one.

There are also implications in the burner design with the amount of
pollutant emission, especially of NOx gases.

I have a German made boiler from a company called MAN Heiztechnik
(division of the same company that makes trucks and diesel engines).
This is towards the top end on efficiency and one of the lowest NOx
emitters in the industry. The burner and heat exchanger design is
cylindrical with the burner being a wire mesh arrangement sitting at
the centre of a stainless steel chamber with pipes around the
periphery. The condensate falls to the bottom at the back and passes
to a trap system for disposal. Very little water vapour leaves the
boiler flue, even under quite high firing conditions.

There are photos at
http://www.man-heiztechnik.de/index.php

Click on the second thumbnail picture with the flashing red "test"
logo and then at the resulting Micromat EC product page, the link
under the photo marked "Mehr fotos und details". There is a gallery
of pictures and the heat exchanger is shown as the third and the
burner as the fourth.
The manufacturer won a best on test award in August for this product
even though it was originally introduced in 1995.


..andy

To email, substitute .nospam with .gl

On Thu, 27 Nov 2003 11:45:48 -0000, "Christian McArdle"
wrote:

I would have thought the whole point of a condensing boiler is that the
exhaust contains little or no water vapour.

This would only happen if the flue is long enough for all the water to be
removed, or the return temperature is very low. If the return temperature is
around 60C, then the boiler fundamentally can't cool the flue gases any
lower that this. Those gases would then still contain water that will only
condense out when the temperature drops further, either within the colder
flue (if it is long enough) or upon exposure to colder air (at the
terminal).

Any condensing on the flue or outside air is wasted energy. That is one
reason why greater efficiency occurs at lower return temperatures. More
condensing can then occur upon the heat exchanger itself, where the energy
can be usefully recovered. (There are also thermodynamic reasons for greater
efficiency at low temperatures that apply to all boilers, not just
condensing types).

Christian.


I don't think that that is completely it, Christian.

The major heat recovery in terms of delivering heat to the heat
exchanger water is from the change of phase of water from gas to
liquid - latent heat of condensation.

The lower flue gas temperatures result in less loss of heat outside in
the form of hot air, CO2, water vapour etc., and anything that can
help with that is a bonus as well in that the heat will dissipate
inside the property. For example, having a longer flue inside the
house on a condensing boiler will result in the flue gases being
cooler as they leave the building and more water will have been
collected. However, that will be heat transferred other than into
the water.

Obviously the heat exchanger temperature has an impact on that as
well.

I just took a look at the display on the front of my boiler. It's
currently showing 6 degrees outside, the flow temperature is 61
degrees, the return 45 degrees. It also gives me the fan rpm from
which I can look up the heat input - approx. 7.5kW - and the pump is
running at 35% of max. There is very little plume at all.

I can press a test button and deliberately force it to run at a 50% of
full power rate (approx. 14kW). There is still very little plume.

I only have a very short flue - literally the elbow above the boiler
and straight through the wall.

..andy

To email, substitute .nospam with .gl

"Andy Hall" wrote in message
...

Since there are so many models bunched together in efficiency terms at
the top 90-91% range, it suggests that they are reaching the limits on
design and physics for the technology.

Soon, it looks as if 86% efficiency will be the minimum. This precludes all
non-condensing boilers. This creates problems with the plume in flats and
the likes, so advanced research is under ways with prototypes using Zeolithe
heat pumps which run on natural gas for the provision of domestic heating
and hot water. These units are currently floor mounted and resemble a
typical boiler in appearance. Zeolithe heating appliance's use less energy
and more environment-friendly than electric heat pumps and gas boilers. It
provides considerably higher output levels than the current conventional and
condensing boilers. Carbon-dioxide emissions are reduced by approximately
20 to 30%.

Zeolithe heat pumps can be toned down to eliminate a plume and still beat
current condensing boilers in efficiency. Have the gas powering them
condense and efficiency rises again.

I have a German made boiler from a company called MAN Heiztechnik
(division of the same company that makes trucks and diesel engines).
This is towards the top end on efficiency and one of the lowest NOx
emitters in the industry. The burner and heat exchanger design is
cylindrical with the burner being a wire mesh arrangement sitting at
the centre of a stainless steel chamber with pipes around the
periphery.

The burner is a "radiant" burner. designed to primarily give off radiant
heat. In normal bottom mounted rail burners the heat transfer is mainly via
the products of combustion passing through the heat exchanger, the reverse.


---
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The major heat recovery in terms of delivering heat to the heat
exchanger water is from the change of phase of water from gas to
liquid - latent heat of condensation.

Maybe I didn't explain very well.

The water condenses out of the gases because the gas temperature has reduced
to the extent that the air is fully saturated. As the gas temperature
reduces, it can contain less water, so the water condenses out onto the heat
exchanger, raising the temperature of the heat exchanger as it does so.

If the coldest part of the heat exchanger (which is the same as the return
temp) is 60C, the gas is capable of containing far more water than if it was
30C. Therefore, less water comes out for condensing, and the heat exchanger
benefits from less boost.

This is completely different from simply the energy lost by expelling higher
temperature air. You would even gain this energy advantage even if you
subsequently reheated the air to the same temperature. The difference would
then be that the exhaust gas would have lower humidity, water would go down
the drain and the system would be more efficient, but obviously less
efficient that had you not reheated the exhaust.

Although the plume starts happening when the boiler gets cool enough to
condense, if the return temp is very low, then the pluming may reduce again,
simply because the heat exchanger becomes efficient enough to remove most of
the water from the gases, which then don't have much further in temperature
to fall.

Christian.

On Thu, 27 Nov 2003 13:45:51 -0000, "Christian McArdle"
wrote:

The major heat recovery in terms of delivering heat to the heat
exchanger water is from the change of phase of water from gas to
liquid - latent heat of condensation.

Maybe I didn't explain very well.

The water condenses out of the gases because the gas temperature has reduced
to the extent that the air is fully saturated. As the gas temperature
reduces, it can contain less water, so the water condenses out onto the heat
exchanger, raising the temperature of the heat exchanger as it does so.

If the coldest part of the heat exchanger (which is the same as the return
temp) is 60C, the gas is capable of containing far more water than if it was
30C. Therefore, less water comes out for condensing, and the heat exchanger
benefits from less boost.

This is completely different from simply the energy lost by expelling higher
temperature air. You would even gain this energy advantage even if you
subsequently reheated the air to the same temperature. The difference would
then be that the exhaust gas would have lower humidity, water would go down
the drain and the system would be more efficient, but obviously less
efficient that had you not reheated the exhaust.

Although the plume starts happening when the boiler gets cool enough to
condense, if the return temp is very low, then the pluming may reduce again,
simply because the heat exchanger becomes efficient enough to remove most of
the water from the gases, which then don't have much further in temperature
to fall.

Christian.


Agreed. I rather suspect that the contact time and area for the
gases with the heat exchanger has an impact as well.....




..andy

To email, substitute .nospam with .gl

Agreed. I rather suspect that the contact time and area for the
gases with the heat exchanger has an impact as well.....

There's a law of diminishing returns, though. Once the gas temperature is
within a few degrees of the return temperature, there's little point in
hanging around.

Christian.