EP2116790A1 - Furnace with a cleaning device - Google Patents

Abstract

A cleaning system for a fuel fired burner, e.g. water heating, has jets (31) positioned to loosen burn residues on the heat exchanger surfaces (16). The jets are applied a selected intervals and the loosened residues are removed by integral suction jets (30). The process can be applied to all types of fuel including fuel pellets.

Description

The invention relates to a firing device, with a burner that burns fuel and thereby generates hot combustion gases, with flue gas passages through which the combustion gases are passed from the burner, with heat exchanger surfaces in the flues, with which heat from the combustion gas is transferable to a heat transfer medium, with a cleaning device with which combustion residues from the heat exchanger surfaces can be cleaned.

Continuously operated industrial furnaces must be freed from incineration residues from time to time. This applies to solid fuel firing as well as pellet firing or wood firing. Particularly in the case of solids firing, larger quantities of ash, soot or slag or other combustion residues can form. These residues are deposited on surfaces of heat exchangers of the furnace. By this deposition, the heat transfer is hindered, which is to be done in the heat exchanger, usually called heat exchanger, from the furnace to a heat transfer medium. This heat transfer medium is usually water or a fluid composed of water.

It is therefore necessary to remove these combustion residues, especially in solid fuel boilers. This is conventionally done by manually cleaning from time to time. This cleaning is usually done by means of a mobile mechanical cleaning device. However, this cleaning device is at least partially in a hot flue gas stream and is therefore highly loaded thermally.

For example, a boiler is charged with pellets. In a combustion chamber, these pellets are burned, with a flame in one Burning post-combustion ring or other downstream elements into it. This produces flue gases. These flue gases are led into flues. Therein, the flue gases are possibly redirected several times. They run over heat exchanger surfaces, which can be quite complex depending on the concrete structure. The combustion air can be routed horizontally over entire or partial sections and the flues can be constructed very compact. In this leadership of the combustion air can also be elements for different purposes.

Such a pellet boiler is freed about once a day via a vibrator via an eccentric engine of combustion residues on the heat exchanger surfaces in the flue gas trains. The elements in the flue gas trains, such as cleaning springs, are to be considered. Due to gravity, the residues fall into a collecting container, which is significantly less thermally stressed compared to the hot combustion zone. From the collection container can then be transported via a transport device, e.g. a screw conveyor, the combustion residues are transported to a collection container.

The cleaning effect of such vibrators is sometimes unsatisfactory. Vibrating devices also have the disadvantage of occasionally transmitting vibrations very far, which is not desirable acoustically. Mechanically vibrating devices are very complex, relatively expensive and due to the required moving parts also error prone.

It would be desirable if a cleaning in firing facilities in a more convenient form would be possible.

The object of the invention is therefore to propose an improvement for the purification of combustion residues in industrial furnaces.

This object is achieved according to the invention in a generic firing device in that the cleaning device is a nozzle arrangement has, with the compressed air is periodically and / or at desired times blown over the heat exchanger surfaces, which stirs up the combustion residues, and that a suction device is provided which sucks the fluidized combustion residues.

With such a design, the heat exchanger or exchanger surfaces of technical firings are cleaned automatically at regular intervals. An additional mechanical cleaning can even be omitted, so that the associated problems no longer occur.

It is particularly advantageous that a cleaning of the firing device in the hot zone, ie in the combustion zone is possible. In previous mechanical cleaning this was difficult, since then the mechanically moving parts were exposed to these high loads, resulting in faster wear and more frequent malfunction.

By contrast, with the present invention it is possible to clean a furnace, in particular a solid-fuel firing, without wear and tear in a hot zone without mechanically moving parts.

With the invention, the Wärmeübertrager- or exchange surfaces of a furnace, for example, with a pellet boiler by means of injection of compressed air automatically and periodically cleaned. The combustion residues, which are stirred up by the compressed air, can also be extracted at a suitable point at the same time, without the combustion gases escaping into the installation space.

In a preferred embodiment, a pellet boiler is used, which is a low-temperature boiler. The pellet boiler with its combustion chamber, the combustion gases leading flues and the heat exchanger surfaces is surrounded by a large storage tank. The storage container contains the heat transfer medium. In addition, a so-called thermo ring is provided. This is a cylindrical, with a fluid, in particular a liquid, filled jacket. The heat from the combustion gases is therefore first released via the heat exchanger surfaces of the fluid in this thermo ring and then from this to the heat transfer medium in the memory.

This is used with advantage that no condensation occurs in the combustion chamber. Due to the lack of condensation and the adverse effect can be avoided that set the combustion residues on the heat exchanger fins and hinder the cleaning by means of compressed air in this way.

The cleaning device can be used in particular in a compact integrated in the memory pellet boiler, which can be compared to the prior art also reduced to a much smaller size of only one-third. The combustion chamber of the boiler can preferably be made interchangeable via a flange on the memory. The leadership of the combustion air is preferably carried out horizontally in two trains, so that it is possible that the fuel supply and the exhaust gas removal takes place from one side into the memory.

With the present system, it is possible to clean a (solid) firing in a hot zone without mechanical moving parts wear-free.

It also creates independence from the combustion chamber geometry. Even with firing systems with a compact or horizontal combustion air duct, the heat exchanger surfaces can be effectively cleaned.

It may be a boiler for hot water production, a furnace for hot air generation, or a furnace for process purposes.

Preferably, a welded-on nozzle channel is used on an exhaust gas ring channel.

In one embodiment of the invention, in addition to the combustion chamber, a Stirling engine is used for cogeneration. Especially with such a combination it can be used that hot flue gases for operation the Stirling engine can be provided with good efficiency available, which is supported by the cleaning possible with the invention of this good efficiency and also the automatic operation of the Stirling Engine is favored by the fact that a mechanical cleaning is no longer required.

It should be taken into account that flue gas temperatures of more than 800 ° C should be used for effective operation of the Stirling engine.

A cleaning is also possible for any Nachschaltheizflächen the Stirling engine with the invention.

Figur 1

Eine schematische Schnittdarstellung einer Feuerungseinrichtung mit einer Reinigungseinrichtung.

In the following, an embodiment of the invention will be described in more detail with reference to the drawing. Show it:

FIG. 1

A schematic sectional view of a firing device with a cleaning device.

The FIG. 1 shows in schematic form a firing device according to the invention. This firing device 10 serves to heat a heat transfer medium 21 in a storage tank 20.

For this purpose, the firing device 10 has a burner 11 which generates a flame 12. The burner 11 burns, for example, a solid fuel (not shown), for example pellets.

The flame 12 burns in the illustrated embodiment after leaving a horizontally oriented flame tube 13 horizontally in a combustion chamber insert 14, in the FIG. 1 to the right.

The combustion chamber insert 14 is constructed approximately cylindrical.

By the flame 12 hot combustion gases 15 arise in the combustion chamber insert 14. These hot combustion gases 15 now leave the combustion chamber insert 14 and are deflected at the end of this combustion chamber insert 14 on the opposite side of the flame 12 by 180 °.

Due to the cylindrical construction of the combustion chamber insert 14, they flow in an annular space outside the combustion chamber insert 14 and pass through heat exchanger surfaces 16, here in the form of heat exchanger fins. These heat exchanger surfaces 16 or heat exchanger fins absorb as much heat energy from the hot combustion gases 15. Around this area with the Combustor 14, the annular space with the flues and the combustion gases flowing therein 15 and the heat exchanger surfaces 16 is a cylindrical shell 18. This cylindrical defect 18 is a so-called thermo ring. He is filled with a fluid, in particular a liquid. At this thermo ring relationship, this fluid in the cylindrical shell 18, the heat exchanger surfaces 16, the absorbed heat energy from. This fluid in the thermo ring in turn then gives the heat energy to the heat transfer medium 21 in the storage container 20 from. The interposition of the thermo ring or the cylindrical shell 18 has the purpose to prevent too cold a liquid in the memory that a condensation of components from the combustion gases 15 takes place on the heat exchanger surfaces 16 and thereby possibly affect the cleaning.

From the annular space in the region of the heat exchanger surfaces 16, the hot, now somewhat cooled combustion gases 15 flow into an exhaust gas channel 17.

In addition, a cleaning device 30 is provided at the end of the annular space with the heat exchanger surfaces 16, at which the exhaust gas duct 17 branches off. This cleaning device 30 has a nozzle arrangement 31, which in the illustrated embodiment is a nozzle ring. This nozzle assembly 31 with the nozzle ring carries a series of nozzles that can deliver compressed air into the annulus.

This nozzle arrangement 31 with the nozzle ring is arranged shortly before the diversion of the exhaust gas channel 17 from the annular space with the heat exchanger surfaces 16 and the heat transfer ribs and in particular directly welded.

A control device (not shown) is provided, for example, periodically once a day in a particular situation compressed air from the Nozzle assembly 31 with the nozzle ring in the annulus with the heat exchanger surfaces 16 blows.

In addition, a suction device is provided which has a solenoid valve 32 and a suction tube 33. The suction pipe 33 is connected to a vacuum cleaner (not shown).

By blowing the compressed air into the annulus with the heat exchanger surfaces 16 residues of the hot combustion gases 15 are fluidized and released from the heat exchanger surfaces 15 and also from the other, possibly existing elements and the other walls and stirred up. An additional vibrating device as conventional does not need it.

About the solenoid valve 32 and the suction pipe 33 of the suction device are then sucked up by means of a vacuum cleaner, not shown, whirled combustion residues and other loose particles and sucked through the suction pipe 33 in a container equipped with a filter (not shown).

LIST OF REFERENCE NUMBERS

10

firing

11

burner

12

flame

13

flame tube

14

combustion liner

15

combustion gases

16

heat exchanger surfaces

17

exhaust duct

18

cylindrical jacket (thermo ring)

20

storage container

21

Heat transfer medium

30

cleaning device

31

nozzle assembly

32

Valve, in particular solenoid valve

33

suction tube

Claims (12)

firing,
a burner (11) which burns fuel and thereby produces hot combustion gases (15),
with flues through which the combustion gases (15) from the burner (11) are guided,
with heat exchanger surfaces (16) in the flues, with which heat from the combustion gas (15) can be transferred to a heat transfer medium (21),
with a cleaning device (30) with which combustion residues can be cleaned off from the heat exchanger surfaces (16),
characterized,
that the cleaning device (30) has a nozzle arrangement (31), is blown with the compressed air periodically and / or at desired times on the heat exchanger surfaces (16), which stirs up the combustion residues, and
that a suction device (32, 33) is provided which sucks the swirled combustion residues. Firing device according to claim 1,
characterized,
in that the nozzle arrangement (31) has a nozzle ring which contains a plurality of nozzles and blows the compressed air into an annular space with the heat exchanger surfaces (16). Firing device according to claim 2,
characterized,
is that the nozzle ring is welded to adjacent exhaust passages (17). Firing device according to one of the preceding claims,
characterized,
in that the burner (11) is aligned horizontally with a flame (12) and a combustion chamber (14) and has a horizontal axis. Firing device according to claim 4,
characterized,
that the flues are arranged in the form of an annular space around the combustion chamber (14) and the combustion gases (15) outside the combustion chamber (14) deflected by 180 ° horizontally in the opposite direction to the flame (12) of the burner (11). Firing device according to one of the preceding claims,
characterized,
in that the supply of the fuel to the combustion chamber (14) and the discharge of the combustion gases (15) in an exhaust gas duct (17) take place on the same side of the combustion chamber (14). Firing device according to one of the preceding claims,
characterized,
in that a control device is provided which actuates a valve, preferably a solenoid valve (32), in response to the delivery of compressed air through the nozzle arrangement (31) and thus actuates a suction device. Firing device according to one of the preceding claims,
characterized,
that the burner (11) is formed with the combustion chamber (14) as low-temperature combustion chamber. Firing device according to one of the preceding claims,
characterized,
that the combustion chamber (14) with the burner (11) and the flues is mounted replaceably on a flange. Firing device according to one of the preceding claims,
characterized,
in that a storage device for the heat transfer medium (21) is provided, which surrounds the combustion chamber (14), the flues for the combustion gases (15) and the heat exchanger surfaces (16). Firing device according to claim 10,
characterized,
that the heat exchanger surfaces (16) via a cylindrical, liquid-filled jacket (18) of the heat transfer medium (21) are separate and transfer the heat from the combustion gases (15) first to the fluid in the cylindrical jacket and from there to the heat transfer medium (21) become. Firing device according to one of the preceding claims,
characterized,
that additionally a Stirling engine is provided for a combined heat and power.

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