WOOD-FIRING EXPERIMENTS: TESTING THE EFFICIENCY
OF AN UPDRAFT KILN
In this paper we present and compare two separate wood-firings of predominantly
plain, handmade burnished ceramics in an updraft kiln. Our main aim was to gain a
better understanding of the function of the kiln and a greater knowledge of ancient
firing processes. Both firings took place in the same kiln, but the pottery installation
underwent a series of modifications and the fuel type was partially changed for the
second firing [1]. The objectives of the experiments were to: a) evaluate the
effectiveness of the kiln based on the heat rate, the maximum temperature achieved,
and heat loss, b) investigate the effect of the fuel type on heat efficiency, c) assess
the impact of the temperature and prevalent atmosphere on the colour and texture of
the pottery, and d) check the quality of the fired vessels and, if necessary, provide
more sophisticated adaptations to improve the heat efficiency of the installation.
1. The kiln
We used a rectangular, wood-fired kiln for our experiments (Fig. 1a). The entire
structure was placed on wheels to make it movable. The kiln walls were built from a
layer of firebricks (0.11m in thickness), while the stoking channel and its door, as well
as the cover and the chimney, were all made of iron. Slight deformations on one of
the two long sides were observed after the first firing, so the corners of the
installation were supported with additional elongated metal sheets for the second
firing.
The updraft kiln type is a two-chamber, vertical installation where the fuel is
separated from the pots and the hot air flows from the lower to the upper chamber
(Conway 1976, 92; Dawson and Kent 1984; Prillwitz and Hein 2015; Thér 2004, 39–
40; Zakin 2020, 5–6). During the experiments, the pottery was placed in the upper
chamber (0.85 x 0.60 x 0.48m), while the lower combustion chamber or ‘fire box’
(0.85 x 0.60 x 0.29m) was used to stoke the fire. Between the two chambers, three
adjacent fire plates (0.25 x 0.50 x 0.04m) constituted the floor upon which the pots
were stacked. For the second firing the original compact fire plates were replaced by
thinner ones (0.03m thick) that were perforated with evenly distributed vents, each
with a diameter of 0.012m (Fig. 1b). Along the long sides of the walls, between them
and the pottery chamber floor, a gap (0.06m in width) allowed the hot gases and
flames to pass directly from the fire box into the upper chamber (Fig. 1b). This gap
was 0.03m wide at the transverse sides. For an overview of the main modifications to
the kiln, as well as the changes in atmospheric conditions and the fuel types used in
the two firings, see Tab. 1.
First firing
Second firing
Chimney height
0.30m
2.30m
Top of chimney
Closed (after reaching the maximum
temperature)
Open (constantly)
Pottery chamber
floor
Compact fire plates, 0.04m in
thickness
Perforated fire plates, 0.03m in thickness
Firing atmosphere
Smoky (in the final stage of firing)
Mixed (in the final stage of firing)
Kind of fuel
Chopped pine wood; small olive logs,
0.08-0.10m in diameter; fresh grass
after the maximum temperature was
achieved
Chopped pine wood; twigs from olive
and orange trees, complementary
brushes of vine; brushwood and dried
leaves in the advanced stage of firing;
fresh grass after the maximum
temperature was achieved
Tab. 1. Overview of the main changes between the two firings.
The fuel was added through a short stoking channel (0.25 x 0.35 x 0.42m), which
faced north during both firings. The top of the channel extended 0.03m above the top
of the combustion chamber. The stoking hole had a door for stopping sudden
airflows, thus preventing the fire from rapid, unwanted temperature rise. This also
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worked as a means to regulate the air supply and draft, and helped to raise or reduce
the temperature when desired. A central, cylindrical chimney (0.15m in diameter and
0.30m in height) was attached to the cover that closed the upper part of the kiln (Fig.
1a). The chimney was extended by two metres for the second firing. During firing, the
temperature was determined by a thermocouple that was placed in the middle of the
back wall of the pottery chamber.
2. The pottery load
The shape, surface treatment and forming techniques for the majority of the pots
used in the experiments were inspired by extant examples of prehistoric pottery,
mainly found in Greece and the surrounding region, including Cyprus (see
facebook.com/JasperHandmadeCeramics).
A number of different handmade manufacturing techniques were applied for building
the pots. It should be stressed that the vessels used in both firings comprised of a
range of shapes, sizes, and wall thicknesses, although the vast majority were thinwalled and medium-walled. All vessels were burnished and had a highly glossy
appearance. A few pottery sherds were also fired during the second firing. These
constitute part of a reference collection produced by G. Kordatzaki, and are
representative of a wide spectrum of manufacturing techniques. Besides being
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burnished, the reference sherds were also polished and smoothed [2]. The bulk of
the ceramics in both firings were made from similar clay pastes, whereas very few
pots were prepared from other types of commercial clay. Specifically, two different,
semi-fine types of clay from Greece were used, including a commercial one from
Chalkis, pale brown when unfired, and a non-commercial clay from central Crete that
is dark grey in its raw state [3].
The pottery chamber in both firings was less than half-full (Figs. 2 and 3), with more
available space between the vessels in the first firing compared to the second. The
larger vessels were put directly on the floor of the chamber. Occasionally, mediumor large-sized pots with convex bases were placed upside down. It is noteworthy, that
several pots near the side walls were resting partly or directly on the gap. For the first
firing, the pots were stacked in columns, one upon the other in a vertical arrangement
(Fig. 2) [4]. The drinking cups and the miniature vessels were often put inside the
larger pots. In the second firing, the pots in the front part of the chamber were piled in
a lattice-style arrangement (Abu-Ziyan 2004) (Fig. 3). However, the vessels in the
middle and the back parts of the chamber were stacked one above the other in
columns. The columns were close to each other, leaving narrow passages for the hot
air and gases to circulate [5]. In contrast to the first firing, the bulk of the drinking
cups were put in the upper parts of the load and not in the interior of the larger
vessels.
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3. The firing process
In order to avoid a rapid temperature rise in the early stages of the firing process, the
fire was kept at the mouth of the combustion chamber during both firings. The slow
increase in temperature up to 200–250°C prevented potential damage to the pots
due to water evaporation during the water smoking stage (Fig. 4) (Rye 1981, 105) [6].
3.1. The first firing
At the start of the first experiment, the fire was slowly fed with small chopped pine
wood up to 220°C. Beyond this temperature, we supplemented the pine wood with
small olive tree logs (0.08–0.10m in diameter). When the temperature reached
approximately 450°C, we only used olive tree logs. It was noted that up to 550°C the
pots appeared black. After reaching this temperature the first sparkles became visible
above the chimney, and at about 600/625°C flames extended out of the flue.
Unfortunately, it was impossible to increase the temperature as high and as fast as
we wanted, despite feeding the fire with a large number of logs. Several times we
were forced to empty the fire box of all combustion materials. When the maximum
temperature of 625°C was achieved, fresh grass was added to ‘smoke’ the vessels
(for this process and a general discussion on reduction, see Dawson and Kent 1999;
Shepard 1956, 88). The flue and the door of the stoking channel were sealed, and
the pots were left in the smoky atmosphere of the kiln to slowly cool down. Within 2
hours and 45 minutes the temperature dropped to 250°C. Early the next morning,
when the temperature had reached 100°C, the vessels were discharged.
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3.2. The second firing
At the beginning of the second firing, single pieces of chopped, dried pine wood were
used up to approximately 100°C. Above this temperature, up to about 450°C, dried
twigs from olive trees were occasionally added to the fire. Gradually, the fire feeding
became faster. Up to 540°C, the small pieces of pine wood were replaced by larger
pieces, and the initial intermittent refuelling switched into an almost continuous one.
Above 540°C the fire was stoked mostly with twigs from olive and orange trees,
complemented with brushes of vine. In addition, the fire was supplied with pine wood.
It was noted that the original pale brown/orange colour of the fire plates in the
combustion chamber progressively turned black during the first stage of the firing. At
about 400°C they changed to a whitish colour, and above 550°C to red.
Above 600°C the fire was stoked continuously with twigs. The charcoal and ashes,
which had accumulated in the middle and back parts of the combustion chamber,
were removed twice (at about 525°C and then at 650°C) in order to maintain the fire.
Dried leaves and large amounts of brushwood (mostly from olive trees and vine)
were also added. This quickly raised the temperature above 675°C. Feeding the fire
with this type of fuel required fast and continuous stoking, otherwise the temperature
promptly dropped. In order to create surfaces of variable colour, fresh grass was put
into the combustion chamber after reaching 750°C. The door of the fire box was
sealed, but the chimney remained open. The vessels were left in the kiln to gradually
cool down. Within 2 hours and 15 minutes, the temperature dropped to 250°C
showing a more or less similar cooling rate as the first firing. Early the next morning,
when discharging took place, the temperature had dropped to 60°C. It was noted that
the fresh grass in the front part of the kiln remained unburned, but was combusted in
the middle and back parts. This implies (given that the chimney was kept open during
the cooling stage) the occurrence of an air draft in the middle and back parts of the
installation throughout the final cooling stage.
3.3. Comparing the two firings: the pottery outcome
In general terms, the heating rate was faster during the second firing, the maximum
temperature achieved was higher (750°C), and the duration of the firing shorter
(about 7.5 hours). In contrast, the first firing reached a maximum temperature of
625°C within 8 hours, and the total duration of the firing was 9 hours (Fig. 4). The
soaking time was about 45 minutes for the first firing (with a slight drop of about
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30°C), and approximately 5 minutes for the second. It should be noted that the
temperature was kept above 700°C for half an hour during the second firing.
It was further noted that the higher maximum temperature during the second firing
was attained in shorter duration with less investment of labour. The olive wood logs
that formed the main combustion agent for the first firing proved to be an ineffective
type of fuel since it exhibited low combustibility. It produced a lot of charcoal that
overfilled the combustion chamber several times, thus preventing the circulation of
oxygen. The replacement of the olive wood logs with dried twigs from olive and
orange trees during the second firing not only contributed to an increase in
temperature and an acceleration in the heating rate, but also a greater economy of
fuel, and the stoking of the fire was more easily manipulated. The windy weather
during the second firing also provided increased airflows (well regulated by the
manipulation of the door of the stoking hole), which produced long flames towards
the middle and back parts of the kiln. This was especially desirable above 500–
550°C. Due to that, and partly the higher chimney, the draft was stronger, making it
easier to raise the temperature. Moreover, the perforated floor used for the second
firing facilitated increased circulation of the hot air.
Nevertheless, it is worth noting that there were difficulties in spreading the fuel and
the charcoal into the front corners of the kiln close to the stoking channel. This was
the case in both firings. In general, the hot air and gases did not circulate evenly and
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sufficiently throughout the pottery chamber. It was found that the interiors of the
vessels that had been placed upside down were fully oxidised in both firings. The
surface colour of the majority of the vessels in the first firing was uniform, although
there were exceptions. The deliberately induced smoky atmosphere created surfaces
that were black or black with a dark brown shade on those vessels manufactured
from the Chalkis clay, and dark grey or greyish/black surfaces on those made from
the Cretan clay (Fig. 5). The fresh cross sections of the vessels of both types of clay
usually appeared fully oxidised brown (Fig. 6a), but the sections of the thicker-walled
vessels made from the Cretan clay occasionally displayed a grey or black core (Fig.
6b).
In the second firing, the vessels situated in the middle and back parts of the chamber
were either homogeneous in colour or displayed patchy discolorations (Figs. 3 and
7). It would appear that mixed conditions (oxidising and reducing/under-oxidising)
prevailed in these parts of the upper chamber. Generally, those vessels made from
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the Chalkis clay, which were situated in the middle and back of the kiln, were orange,
orange brown or, occasionally, dark orange, and often exhibited black shades (Fig.
7). In the same parts of the kiln the small number of vases made from the Cretan clay
became brown. Those parts of the pots that rested just above the side gap
consistently appeared pale greyish brown, implying under-oxidising conditions during
firing. On the other hand, those vessels loaded in the front part of the kiln consistently
displayed dark, almost black surface colours due to the prevailing smoky atmosphere
throughout the cooling stage (Fig. 3). The fresh cross sections appeared uniform –
either brown for pots placed in the front part of the kiln, or orange brown and orange
for those in middle and rear parts (Fig. 6c). However, some examples also showed
light greyish-brown external margins, which were usually associated with vessels
located next to the side gap (Fig. 6d).
For further investigation of the firing atmosphere and a basic estimation of the
temperature reached in the second firing, comparisons were made with a set of test
sherds. These sherds were prepared from the same types of clay as the vessels that
were fired in the updraft kiln. The test sherds were fired in an electrical furnace under
controlled oxidising conditions at different temperatures (600°C/1h, 700°C/1h,
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800°C/1h, 900°C/1h, and 1050°C/1h) so that the full colour development could be
documented [7]. The comparison of the vessels with the test sherds confirmed that
the orange colour or the orange shades of several of the vessels were indicative of
higher temperatures at the back and central parts of the kiln. Furthermore, the dark
orange colour suggests that the achieved temperature was often higher at the bases
of those vessels situated directly on the perforated floor [8]. The same applies to the
adjoining parts of the neighbouring vessels. Three reference sherds situated at the
uppermost back part of the kiln above the side gap in an inclined position exhibited
fireclouding and sooting (Rice 1987, 235).
An interesting observation concerned the state of preservation of the burnishing of
the vases. The intensity of the burnishing was partially affected in certain parts of the
vessels that had been placed in the central and rear parts of the kiln in the second
firing. In addition, extensive damage to the burnishing was observed on those parts
of the vessels that were in the middle and back parts of the kiln immediately above
the side gap, thus directly exposed to the flames and hot gases (von Dassow 2009,
7). Nevertheless, all the vases in the first firing and the vessels situated in the front
part of the kiln of the second firing kept the original burnishing and were highly
lustrous.
In order to test the strength of the fired vessels, they were each filled with water,
causing some of them to break after a few minutes. This test showed that those pots
set in the front part of the kiln of both firings were underfired. However, those vessels
from the middle and back parts of the kiln were durable. This also implies
considerable temperature variation between the front part of the installation and the
middle and back parts.
4. Future modifications of the kiln
Further modifications are required to achieve a more uniform temperature distribution
in the pottery chamber. To improve the overall heat efficiency of the kiln and produce
durable vessels throughout the chamber, we intend to make the following
modifications:
1. Replace the metal cover. The metal cover is a bad insulator that absorbs the heat
and transfers it to the surrounding environment, thus causing significant heat loss.
Hence, it has to be replaced with fire plates and covered with a mixture of clay and
straw, materials that display low thermal conductivity (Prillwitz and Hein 2015, 354).
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2. Change the position and size of the chimney. The long chimney used in the
second firing caused a considerably strong draft in the central part of the kiln, and,
due to the short length of the installation, in its rear part. This, in relation to the
position of the chimney at the centre of the installation, amplified the significant
temperature variation we observed (see also Dawson and Kent 1985, 75–76; Thér
2004, 69). Moreover, its central position enhanced the fast flow and quick escape of
the hot air from the interior of the kiln to the outside environment (for more on this,
see Cuomo di Caprio 2017, 357; Norsker 1987). A better positioning of the flue is
also necessary, which would allow a more even distribution of the hot air in the upper
chamber and improved circulation of the hot gases over a longer period of time
before the heat leaves the kiln. A repositioning of the chimney at the back part of the
installation would also be more functional.
3. Increase the size of the combustion chamber by moving the perforated fire plates
upwards. The extra space in the lower chamber would permit a faster, uninterrupted
refuelling, which is necessary above 600°C for reaching higher maximum
temperatures.
4. Partially modify the stoking strategy through a proper spread of the fuel and
charcoal across the combustion chamber. After the second firing it was clear that the
fuel and the combustion products were gathered mostly in the middle and back parts
of the structure. For this reason, the pots inserted in the front part of the kiln were
underfired or lower fired.
5. Closing remarks
Considerable variations in temperature were recorded in the pottery chamber. It
seems that these variations were more significant between the front part of the kiln
compared to its middle and back spaces. This was partly due to improper fire
feeding. Those parts of the vessels that were in contact with or close to the
perforated floor were exposed to higher temperatures, as the comparison with the
test sherds confirmed. The same applied to the neighbouring parts of pots, signifying
that the temperature here was higher as the heat was being transmitted between
adjacent pots. This most likely indicates that an appropriate lattice setting of the
vessels may play a key role in raising the temperature. However, this kind of setting
presupposes sufficient skill in order to avoid fireclouding and sooting, as the
reference sherds testified, and to permit the free passage of hot gases.
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The type of fuel also proved to be a significant factor in the firing process. During the
main phase of the firing, the twigs from the olive and orange trees and the brushes
from olives and vine constituted a better type of fuel than the logs of olive wood,
obtaining higher maximum temperatures and a desirable heating rate. The perforated
floor that replaced the former compact one likely contributed to the higher maximum
temperature achieved in the second firing as well. The capacity of the combustion
chamber was apparently too small in comparison to that of the pottery chamber. The
long chimney in the second firing, combined with its central position, produced a
strong draft in the middle and back parts of the kiln, leading to an undesirable, rapid
escape of hot air from the front part.
The production of durable vessels and higher temperatures are primary objectives for
potters. Nevertheless, the partial disturbance of the intensity of the burnishing, or
even its loss due to the higher temperatures in association to the firing duration
and/or the direct exposure to the combustion gases, has to be taken into consideration when evaluating kiln efficiency. The experiment with the test sherds demonstrated that the precise temperature at which the burnishing is affected or damaged is also directly related to the type of clay. On this basis, there are no absolute
criteria for a ‘proper firing’, as this depends on the ware and the type of clay being
fired, and on the desired properties of the fired vessels. Equally important is the
extent to which the craftsperson knows how her/his kiln functions. With these
experiments in mind, the exploration of the efficiency of the kiln constitutes an
ongoing journey for us.
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[1] The authors warmly thank Stavros Kordatzakis, who undertook the construction of the kiln,
modified the installation for the second firing, and provided the fuel. For the additional experimental
firing, we owe special thanks to Evangelia Kiriatzi for giving Georgia Kordatzaki the opportunity to use
the furnace at the Fitch laboratory, British School at Athens (BSA). Duncan Howitt-Marshall is
gratefully acknowledged for the proofreading.
[2] Burnishing was usually performed with a pebble or, less often, a wooden tool, providing a lustrous,
though not uniformly shiny, surface. It was noted that the uneven glossy appearance resulted from the
marks left behind by the use of the pebble. Polishing produces uniformly shiny ceramics after rubbing
with a piece of leather, while smoothing provides a more even, though lustreless, surface. For more on
finishing techniques, see Rice 1987, 138; Rye 1981, 89; Shepard 1956, 67, 123–124, 186–193.
[3] We are grateful to Georgios Dalamvelas for providing the Cretan clay (keramion.gr).
[4] More specifically, a total of 53 pots were charged in the first firing, including 20 medium- and largesized vases, 18 small pots, mostly cups, and 15 miniature vessels. For the second firing, 60 vessels
were loaded with considerably less miniature vases (30 medium- and large-sized pots, 27 small pots,
mostly cups, and 3 miniature vases).
[5] The setting pattern substantially affects the circulation of hot air and gases throughout the pottery
chamber, thus influences the distribution of heat (see Abu-Ziyan 2004, 190; Hein, Müller and
Kilikoglou 2017, 102–104). Narrow passages between the pots increase the velocity of the hot air,
thus providing higher temperatures (Norsker 1987).
[6] Generally, dehydration is completed at approximately 600°C, when the water of the crystal lattice
has been driven off and further shrinkage takes place (Shepard 1956, 19–20).
[7] A Nabertherm furnace at the Fitch laboratory, BSA, was used for the experiments. The full colour
development for each type of clay is as follows: Chalkis clay – 600°C/1h / brown, 700°C/1h / brown,
800°C/1h / orange brown, 900°C/1h / dark orange, and 1050°C/1h / dark brown to orange brown;
Cretan clay – 600°C/1h / brown, 700°C/1h / brown, 800°C/1h / brown orange, 900°C/1h / dark orange,
and 1050°C/1h / very dark brown to dark orange. For the general transformations of the iron
compounds during firing and their impact on the full colour development of the fired clays, see
Maniatis 1981.
[8] A similar argument regarding higher temperatures for the vessels placed in the lower part of the
pottery chamber and on the chamber floor itself was made by Rhodes (1968, 118–121) and Rice
(1987, 160). For considerations of the temperature distribution in updraft kilns, see Hein, Müller and
Kilikoglou 2017, 102.
© Georgia Kordatzaki, Michaela Zavadil
e-mail: gkordat@gmail.com, Michaela.Zavadil@oeaw.ac.at
This article should be cited like this: G. Kordatzaki – M. Zavadil, Wood-firing experiments: testing the
efficiency of an updraft kiln, Forum Archaeologiae 96/IX/2020 (http://farch.net).
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