ap-3-12.dvi


Acta Polytechnica Vol. 52 No. 3/2012

Optimal Combustion Conditions for a Small-scale Biomass Boiler

Viktor Plaček1, Cyril Oswald1, Jan Hrdlička2

1
Czech Technical University in Prague, Faculty of Mechanical Engineering, Department of Instrumentation and Control
Engineering, Technická 4, 166 07 Prague 6, Czech Republic

2
Czech Technical University in Prague, Faculty of Mechanical Engineering, Department of Power Engineering,
Technická 4, 166 07 Prague 6, Czech Republic

Correspondence to: viktor.placek@fs.cvut.cz

Abstract

This paper reports on an attempt to achieve maximum efficiency and lowest possible emissions for a small-scale biomass

boiler. This aim can be attained only by changing the control algorithm of the boiler, and in this way not raising the

acquisition costs for the boiler. This paper describes the experimental facility, the problems that arose while establishing

the facility, and how we have dealt with them. The focus is on discontinuities arising after periodic grate sweeping,

and on finding the parameters of the PID control loops. Alongside these methods, which need a lambda probe signal

for proper functionality, we inroduce another method, which is able to intercept the optimal combustion working point

without the need to use a lambda sensor.

Keywords: biomass, combustion, control.

1 Introduction

Small-scale boilers used for residential heating have
undergone considerable development in the last
decade. The developments have focused on reduc-
ing manual user handling. This has led to the re-
quirement for a low-volume fuel that can be deliv-
ered to the boiler by automatic feeding. Automatic
feeding enables the fuel to be fed in smaller batches,
so that the combustion process is disurbed much less
than when the fuel is stoked in the form of whole
logs. Feeding small batches also allows combustion
in much smaller combustion chambers, so that the
size of the boiler can also be reduced [5].

However, a smaller combustion chamber leads to
issues with combustion process control. The small
mass of the burning fuel leads to much faster dynam-
ics of the combustion process response, requiring the
controller parameters to be more carefully adjusted
for faster reactions. Other differences between small-
scale boilers and larger boilers are:
• not only faster but also more sensitive to exter-
nal influences,

• are more resistant to lack of maintenance of the
boiler,

• sensors are not periodically tested.
We are developing a new original algorithm to

control the combustion process in a way that will
maintain the combustion process in optimal condi-
tions. The algorithm meets the requirements of low
acquisition costs and takes advantage of the sensitiv-

ity of the combustion process to external sources of
excitation. It is also resistant to qualitative changes
in the combustion process due to lack of maintenance.
The combustion process is often controlled by main-
taining an optimal air-to-fuel ratio using feedback
from a lambda probe (more on this topic in [5]). Al-
though a lambda probe is not expensive equipment
nowadays, it still has significant impact on the cost
of automating a boiler. The proposed algorithm is
able to find the optimal air-to-fuel ratio without the
need to use a lambda probe.

2 Experimental arrangement

and deployment

The basic arrangement used for combustion control of
small-scale biomass boilers is depicted in Figure 1. It
is based on a biomass boiler for residential and small
enterprise heating that is widely available on the mar-
ket. Its warmed water heat output is 25 kW when
combusting wood pellets. The original control elec-
tronics for the boiler was purpose-made, and could
not be used for experimental control. We therefore
developed and installed a control unit in addition to
the original control electronics. The control unit is
based on the RexWinLab-8000 data acquisition and
control station, which had earlier been developed at
the department where the authors work. Further in-
formation on the control unit can be found in [3].

89



Acta Polytechnica Vol. 52 No. 3/2012

Figure 1: Process schematic of adapted boiler used for small-scale experiments

The boiler instrumentation was further extended by
thermal measurements, a flue gas analyzing unit, a
frequency changer for combustion air speed control,
etc.

The first issue that emerged when we completed
the experimental arrangement was that we observed
quite strong peaks in CO emissions in instants just af-
ter grate sweeping. According to [1], these peaks are
probably caused by the formation of air channels in
the burning layer of the biomass which are destroyed
by movement of the whole layer during grate sweep-
ing. Until new channels are established, the combus-
tion is temporarily short of oxygen. We shortened
the length of the grate-sweeper run and shortened the
grate sweeping period accordingly. The tuned grate
sweeping algorithm led to almost complete elimina-
tion of the CO peaks. More on this topic can be
found in [3].

The original control electronics of the boiler uses
some proprietary modulation of the heat output that
is unknown to us. The modulation is based on burn
out and start up of the fire in the combustion cham-
ber, leading to quite long transitions. During the
transitions, the boiler has considerably high emis-
sions of flue gases, and as in the case of the grate

sweeping peaks mentioned above, unpleasant fluctu-
ations make any automatic evaluation of the steady
state of the combustion process difficult.

3 Optimizing the operation

conditions for a small-scale
biomass-fired hot-water
boiler

The optimal operation conditions for a biomass-fired
boiler can be viewed from two main perspectives:
economic, and ecological. From the economic point
of view, we want to maintain the desired performance
of the boiler while using as little fuel as possible. In
other words, we want to achieve maximum boiler ef-
ficiency. From the ecological point of view, we want
to have the lowest content of monitored components
in the flue gases throughout the process.

Both the economic aspects and the ecological as-
pects of optimal combustion can be affected by con-
trolling the current excess air ratio. If the only eco-
logical consideration is to monitor carbon monoxide

90



Acta Polytechnica Vol. 52 No. 3/2012

emissions, both of the combustion optimality require-
ments can be fulfilled at very similar excess air ratio
values (Figure 2). Then the optimal operation con-
ditions for a biomass-fired boiler can be achieved by
monitoring only a single factor.

Figure 2: Efficiency and CO dependency on excess
air ratio for a biomass combustion process — a typ-
ical trend scheme demonstrating that the minimum
of CO emissions and the efficiency maximum occur
for approximately the same excess air ratio value

A typical approach to controlling the optimal op-
eration conditions for a biomass-fired boiler involves
monitoring the current carbon monoxide content in
the flue gases and controlling the excess air ratio by
changing the primary and/or secondary combustion
air supply. This approach is effective and relatively
fast. On the other hand, optimizing the boiler op-
eration conditions by analyzing the composition of
the flue gases requires special, relatively expensive
instrumentation such as a lambda probe. The addi-
tional expenses are problem for producers of small-
scale biomass-fired boilers for residential heating, and
for their customers.

The control algorithm for optimizing small-scale
biomass-fired boiler operation conditions by monitor-
ing current fuel consumption has been developed for
this reason. The new optimization algorithm is based
on the following assumption: if the controller con-
tinuously controls the current boiler heat output by
changing the fuel supply, and there are no changes
in the desired boiler heat output, then the maximum
boiler efficiency is achieved when the fuel consump-
tion is lowest.

The proposed algorithm continuously analyzes
current fuel consumption and adjusts the combus-
tion air supply to achieve the minimum required fuel
consumption by changing the excess air ratio. This
approach is more time consuming than the approach
using an analysis of the fuel gases. On the other
hand, the proposed optimization algorithm does not

need special additional instrumentation, and does not
introduce any additional costs for the boiler pro-
ducer. The proposed optimization algorithm was
tested on the small-scale biomass-fired boiler intro-
duced above. The results of the test are depicted
in Figure 3. It shows that, although this approach is
very time-consuming, it is an effective and cheap way
to find and maintain small-scale biomass-fired boiler
combustion in its optimal operating conditions.

Figure 3: Results of a air-fuel ratio optimization al-
gorithm experiment

We are currently developing the optimization ap-
proach for mid-scale boilers, which will use a com-
bination of the two approaches mentioned here to
achieve a better compromise between the two aspects
of optimal operating conditions. In addition, this
new approach should be able to observe the current
combustion process parameters.

4 Conclusion

Although there are no emission regulations for small-
scale boilers in most countries, recent developments
in national legislation show that this situation will
probably change in the near future. One probably in-
evitable way to reduce emissions will be by improving
boiler control algorithms. This paper has pointed out
some of the issues that can arise when building an ex-
perimental small-scale biomass combustion platform.
It has also introduced a method for finding optimal
combustion conditions without the need for a lambda
probe.

Future work will involve testing the proposed al-
gorithm on a boiler with a much greater heat out-
put. The Verner 600 experimental boiler is located
in Turňa nad Bodvou in Slovakia, and experiments

91



Acta Polytechnica Vol. 52 No. 3/2012

on it are controlled remotely, using the Internet, in
cooperation with Technical University in Košice.

Acknowledgement

This work has been supported by the Ministry of
Education of the Czech Republic, under project No.
MSM68400770035 “Development of environmentally
friendly decentralized power systems”, which is grate-
fully acknowledged.

The work of PhD students has been supported
by Doctoral Grant Support of the Czech Techni-
cal University in Prague, grant No. SGS10/252/
OHK2/3T/12.

References

[1] Korpela, T., Bjorkovist, T., Lautala, P.: Durable
feedback control system for small scale wood chip
combustion. In Proceedings of World Bioenergy
2008, Jönköping, Sweden : May 2008, p. 224–230.

[2] Mižák, J., Pitel’, J. On the problem of use
of Lamda sensors for combustion control. In
Zborńık pŕıspevkov ARTEP 2011, Stará Lesná,

16. 2.–18. 2. 2011. [CD-ROM]. Košice : TU
v Košiciach, 2011. ISBN 978-80-553-0606-3.

[3] Plaček, V., Šulc, B., Vrána, S., Hrdlička, J.,
Pitel’, J.: Investigation in Control of Small-
scale Biomass Boilers. In Proceedings of the 2011
12th International Carpathian Control Confer-
ence (ICCC), Velké Karlovice : IEEE – Systems,
Man, and Cybernetics Society, 2011, p. 312–315.

[4] Oswald, C., Šulc, B.: Achieving Optimal Oper-
ating Conditions in PI Controlled Biomass-fired
Boilers: Undemanding way for improvement of
small-scale boiler effectiveness. In Proceedings of
the 2011 12th International Carpathian Control
Conference. Velke Karlovice : 25.–28. May 2011,
p. 280–285. ISBN 978-1-61284-359-9.

[5] Pitel’, J., Mižák, J.: Approximation of CO/
lambda biomass combustion dependence by artifi-
cial intelligence techniques. In Annals of DAAAM
for 2011 & Proceedings of the 22nd International
DAAAM Symposium, Vienna : DAAAM Interna-
tional, p. 0143–0144.

[6] van Loo, S., Koppejan, J.: The Handbook of
Biomass Combustion and Co-firing. London :
Earthscan, 2008.

92