[0001] The present invention relates to an apparatus for purification of gases, comprising
a combustion device, through which a gas is intended be to conducted for combustion
and/or conversion of the contaminants of the gas.
[0002] In Swedish laid-open specification No. 8403330-7, a method and an apparatus are described
for combustion or decomposition of contaminations in gases, the contaminated gas being
conducted into a combustion device having a bed of sand, stones or another heat accumulating
substance and a heating device for heating the bed to the required temperature. In
such a device it is desirable that the maximum temperature and consequently the most
efficient combustion and decomposition are attained in the central region of the bed.
However, during the operation of the device the temperature gradient in the bed will
drift in the direction of the gas flow. In order to solve this problem the direction
of the gas flow through the combustion device is changed periodically such that the
maximum temperature will be maintained essentially in the central region of the bed.
However, this solution requires a complicated gas flow direction changing device.
[0003] The purpose of the present invention is to solve, in a much simpler way, the problem
related to the drifting temperature gradient in this type of purification apparatus,
and to provide in a simpler way an apparatus, which can be operated continuously while
maintaining the desired temperature conditions in the combustion device without the
need for reversal of the gas flow direction through the combustion device.
[0004] This purpose is obtained by an apparatus of the type stated in the introduction with
the characteristics set forth in claims 1 or 2.
[0005] By constructing the apparatus such that the contaminated gas is conducted in one
direction through one part of the combustion device and the contaminated gas or another
medium in opposite direction through a second part of the combustion device, each
of the two oppositely directed flows being successively passed through different parts
of the combustion device, the tendency of the temperature gradient to drift, which
is caused by the one flow in a certain part of the combustion device, will be brought
back, when subsequently the oppositely directed flow will flow through this part of
the combustion device. Thus, by continously reversing the flow direction in the different
parts of the combustion device the drift of the temperature gradient is avoided in
a simple way.
[0006] It appears to be an advantage to utilize the contaminated gas as a sole medium in
the two oppositely directed flows. However, it is also possible to utilize a second
(clean) medium in the oppositely directed flow. However, this second medium will have
a cooling effect on the combustion device and consequently this embodiment is less
attractive from the point of view of energy consumption.
[0007] According to an advantageous embodiment the combustion device is mounted in a rotor,
stationary supply means being provided to conduct the flows mainly parallel to the
axis of the rotor in opposite directions through different parts of the rotor. Due
to the rotation of the rotor the oppositely directed flows will then successively
pass through different parts of the combustion device.
[0008] According to another advantageous embodiment said supply means comprise a system
of movable ducts for the oppositely directed flows, which are passed through the different
parts of the combustion device due to the motion of the ducts, the combustion device
being stationary.
[0009] The combustion device comprises a bed of sand, a ceramic material or another heat
resistant material and a source of heat for heating the bed. The source of heat can
be formed of electric heating coils or burners for a suitable fuel, such as a gas,
oil or a solid fuel, the embodiment with stationary bed being particulary advantageous,
since feeding of electric current or gas, oil or another fuel to the bed is possible
by simple solutions, from electric sources or fuel containers situated outside the
combustion device.
[0010] Exemplary embodiments of the apparatus according to the invention will be described
in more detail with reference to the accompanying drawings, on which
Fig. 1 shows a first embodiment of the apparatus according to the invention with the
bed positioned in a rotor;
Fig. 2 a second embodiment having a system of movable ducts for supply of oppositely
directed flows to the bed;
Fig. 3 a third embodiment having a rotating bed positioned in a combustion chamber;
and
Fig. 4 a fourth embodiment having a stationary bed in a combustion chamber.
[0011] In fig. 1 an embodiment having a slowly rotating rotor 2 is shown. A combustion device
for combustion and/or conversion of the contaminations of the gas is disposed in the
rotor. The combustion device comprises a bed 4 of sand, a ceramic material or another
heat resistant material and a source of heat, not shown in detail, for heating the
bed to the required temperature.
[0012] The gas, which is to be purified, is passed through one half 5 of the bed 4 in one
direction 3 and in the opposite direction 7 through the other half 9 of the rotor
2. The tub flows 3 and 7 are preferably both constituted of contaminated gas, to be
purified, but it is also possible that one of the two flows is constituted of another
(pure) medium, e.g. exterior air, supplied or recirculated air to a process. The gas
flows, which are schematically illustrated by the arrows 3 and 7, are supplied to
the combustion device in a known manner through supply ducts (not shown).
[0013] As the rotor 2 is slowly rotating in the direction of the arrow 16, the flows of
contaminated gas will continuously pass through different parts of the combustion
bed and those parts of combustion bed 4, through which the gas has passed in a certain
direction during a certain period of time will successively reach that part of the
device, where an oppositely directed flow passes through the bed, the tendency of
the temperature gradient to drift, arisen during the passage of the contaminated gas
in the one direction 3, being corrected by the flow 7 in the opposite direction. Thus,
in this way only a very limited temperature gradient drift will be possible, such
that the maximum temperature will be maintained substantially in the center of bed
4, where it is desirable that the combustion or the conversion mainly is to take place.
[0014] The heating of the bed 4 is preferably realized in this embodiment by electric heating
coils in the bed (not shown in detail), which coils are fed in known manner by means
of slip rings, because the bed is rotating.
[0015] However, it is also possible to provide the heating by burning gas, oil or another
suitable fuel, fuel containers then being suitably mounted inside the rotor. This
is quite possible, since in practice the dimentions of the rotor are substantial.
Since the apparatus according to the invention is particularly adapted for purification
of large gas volumes having a comparatively low concentration of contaminants the
diameter of the rotor is typically of the order of 10 m.
[0016] In fig. 2 a second embodiment is shown, in which the combustion device with its bed
6 is stationary, while a system of movable ducts 8,10 is arranged for supply of the
contaminated gas in oppositely directed flows through different parts of bed 6.
[0017] Thus, a flow of the contaminated gas is introduced at 12 and passes through the bed
6 from the top downwards to the bottom in fig. 2, an oppositely directed flow passing
through the bed 6 and the duct 10.
[0018] The duct 10 is rotatable around a vertical axis in fig. 2 inside the duct 8, such
that the flow 14 through the duct 10 successively passes through different parts of
the bed 6, while the flow 12 simultaneously passes in the opposite direction through
other parts of the bed 6, which are positioned outside the duct 10, the temperature
gradient drift thus being continuously corrected or counteracted so that the maximum
temperature will all the time remain within a comparatively narrow region in the center
of the bed 6.
[0019] In fig. 3 an embodiment having a rotating bed 16 is shown, disposed in a combustion
chamber 18, in the upper part of which a burner 20 is mounted. The flow 22 of contaminated
gas is first conducted through a first part of the bed 16, through the space 24 and
in the opposite direction, at 26, through another part of the bed 16. Because of the
rotation of the bed 16 the flows 22 and 26 will successively be moved to different
parts of the bed.
[0020] As mentioned above, the embodiments according to fig. 1 and 2 are designed such that
the temperature is maximum in the central region of the bed. In the embodiment according
to fig. 3 on the contrary the maximum temperature of the bed 16 will be in its upper
part due to the position of the source of heat 20. The gas flow 22 will then be heated
when passing through the bed 16. In the space 24 the gas can be further heated due
to the combustion of fuel supplied from outside and due to possible combustion of
e.g. solvents present in the gas. When passing in the opposite direction through the
bed 16 the gas 26 will be cooled again, the temperature at the outlet from the bed
16, however, being somewhat higher than at the inlet into the bed 16.
[0021] In fig. 4 an embodiment is shown having a stationary bed 28 in a combustion chamber
30, in the upper part of which a burner 32 is disposed. The temperature conditions
in the apparatus are in this embodiment mainly the same as in the embodiment according
to fig. 3.
[0022] The contaminated gas is supplied under pressure to the bed 28 through a rotating
duct 34 and due to the rotation of duct 34 the flow 36 of contaminated gas will be
moved successively to different parts of the bed 28, the gas flow 38 passing through
the bed in the opposite direction outside the area of supply duct 34 also being displaced
to different parts of the bed due to the rotation of the duct 34 in a way analogous
to that of the embodiment according to fig. 2.
[0023] It is possible in the embodiments according to fig. 3 and 4 that it is not necessary
to operate the burners continuously with fuel from exterior. It can e.g. be sufficient
to operate the burners only during an initial period of time until the temperature
in the combustion chamber is sufficiently high, after which the combustion of contaminants,
e.g. solvents, in the gas may be sufficient in order to maintain the required temperature
for a continued operation.
[0024] The embodiments with a stationary bed have certain practical advantages, because
the feeding of the sources of heat of the apparatus may be carried out in a simple
way from electric sources or fuel containers situated outside the apparatus.
[0025] In the apparatus according to the invention the gas to be purified can of course
be supplied to the combustion device in more than two flows, every second flow passing
the combustion device in one direction and every second flow in the opposite direction.
[0026] The apparatus according to the invention can be generally used for purification of
gases. As examples can be mentioned destructions of solvents from paint industry,
printing trade and car manufacturing plants. The apparatus is particularly suitable
for purification of large gas volumes having a low concentration of contaminants.
1. An apparatus for purification of gases, comprising a combustion device, through
which a gas is intended to be conducted for combustion and/or conversion of contaminants
of the gas, characterized in that means are provided to conduct the contaminated gas in one direction through
one part of said combustion device and in opposite direction through a second part
of the combustion device, said means and/or said combustion device being designed
such that each of the oppositely directed gas flows will successively pass through
different parts of said combustion device.
2. An apparatus for purification of gases, comprising a combustion device, through
which a gas is intended to be conducted for combustion and/or conversion of contaminants
of the gas characterized in that means are provided to conduct the contaminated gas in one direction through
one part of said combustion device and a second medium in opposite direction through
a second part of the combustion device, said means and/or said combustion device being
designed such that each of the oppositely directed flows of the gas and said second
medium will successively pass through different parts of said combustion device.
3. The apparatus according to any of claims 1 and 2, characterized in that said combustion device comprises a bed of sand, a ceramic material or another
heat resistant material and a source of heat for heating said bed.
4. The apparatus according to claim 3, characterized in that said bed is disposed in a rotor and in that said means are arranged to conduct
the flows substantially parallel to the axis of the rotor in opposite directions through
different parts of the rotor, said flows being moved to different parts of said bed
by rotation of the rotor.
5. The apparatus according to claim 3, characterized in that said bed is mounted stationary and in that said means comprise a system of
movable ducts, which are disposed to successively move each of said oppositely directed
flows so that they will pass through different parts of said bed.
6. The apparatus according to any of claims 3-5, characterized in that said source of heat comprises an electric heating coil embedded in said bed
or a burner for gas, oil or another fuel.
7. The apparatus according to claims 4 and 6, said source of heat comprising a burner
for gas, oil or another fuel, characterized in that a fuel container is disposed in said rotor.
8. The apparatus according to any of claims 1-5, characterized in that said combustion device comprises a combustion chamber with said source of
heat positioned outside said bed.
9. The apparatus according to any of claims 1-8, characterized in that said means are disposed to conduct more than two flows having alternately
opposite directions through different parts of said combustion device.