EP0611919B1 - Method for supplying combustion gas containing oxygen to an incinerator with a grate furnace and apparatus for carrying out the method - Google Patents

Description

The invention relates to a method for supplying an O ₂ -containing combustion gas for the combustion of lumpy combustible material, in particular waste, into a combustion chamber with an associated grate of an incinerator, in which part of the combustion gas is supplied as a primary gas through the grate and the other part of the Combustion gas is supplied at least as a secondary gas in a quantity-controlled manner in at least one jet, the speed of the secondary gas jet being additionally regulated when the amount of combustion gas changes.

Such a method is known from DE-PS 632 881, in which the speed of the secondary gas jets entering the combustion chamber is kept constant in order to consume smoke when the total amount of combustion gas changes. In order to achieve constant secondary gas jet speeds, nozzles with a variable outlet opening are provided, as shown in FIG. 2 of DE-PS.

In the generic method, it is to be regarded as disadvantageous that when the combustion air supply changes, the impulse that characterizes the depth of penetration of the secondary gas jet into the combustion chamber and / or the mixing of the rising flue gases with the injected secondary gas determining pulse flow ratio of the pulse of the rising flue gas to the pulse of the secondary gas jet is changed such that the combustion is disrupted with changing amounts of combustion gas and compliance with the operating requirements for good combustion with minimal pollutant emissions of the system is no longer guaranteed.

The momentum of a gas jet is understood as the relationship between mass and speed - see DE book "Applied Fluid Dynamics" by Dr.-lng. Werner Albring, Verlag Theodor Steinkopff, Dresden (1970) (pp. 24, 25 and 385)

Due to the construction of the nozzle, when it is operated in a dusty combustion chamber atmosphere, the adjustment mechanism that changes the outlet opening is contaminated by recirculating dusts, which impairs the function.

From DE-PS 39 04 272 a method for supplying combustion air in the combustion chamber of a waste incineration plant is known in which primary air is supplied in a quantity-controlled manner in a plurality of quantity-controlled partial flows to the grate divided into a plurality of sectors. For intensive mixing of the rising smoke gases and enrichment of the smoke gases with oxygen for post-combustion, secondary air is supplied in a quantity-controlled manner in the transition area of the combustion chamber to the radiation draft using nozzles directed towards the grate. A thermographic camera records the radiation values emanating from the individual grate sectors and describing the progress of the combustion, which are evaluated in an electronic control and regulating unit, whereupon the regulating flaps of the primary and secondary air ducts are adjusted independently of one another with regard to a predetermined combustion air throughput.

Such combustion air routing secures the O ₂ load required for combustion, but this is also associated with a change in the pulse of the secondary air flow, which means that the pulse flow ratio of the pulse into the transition area of the combustion chamber ascending smoke gas flow to the impulse of the secondary air flow is essentially impaired certain mixing quality, which leads to increased pollutant emissions.

The object of the present invention is to provide a generic method in which good combustion with low pollutant emissions from the system is achieved even when the amount of combustion gas changes.

The object is achieved in that the pulse of the secondary gas jet is determined and the speed of the secondary gas jet is adjusted to a predetermined pulse of the secondary gas jet when the amount of combustion gas changes.

This makes it possible to use the amount of secondary gas containing O ₂ to burn the combustion material and the unburned constituents in the flue gas that rise with the flue gas, regardless of the impulse that determines the quality of the inhomogeneous flue gases, the mixing of the secondary gas jet into the flue gases and the range of the secondary gas jet Adjust secondary gas jet. By adjusting the velocity of the secondary gas jet to a given pulse, it is possible to set each pulse without changing the amount of secondary gas.

The impulse is determined, on the one hand, by the geometry of the gas space, such as that of the combustion space, into which the beam flows with an intensity matched to it. Furthermore, the impulse is determined by the flow conditions in the gas space, which depending on the mode of operation of the furnace more or less intensely counteracts the achievement of the predetermined range of the jet or the associated homogenization of the rising smoke gases and their enrichment with oxygen with good mixing. As parameters for the O ₂ requirement The combustion on the part of the secondary gas supply, the mixing quality and the range of the secondary gas jet reveal the values determined by a customary flue gas analysis, such as O ₂ , CO, CO ₂ , SO _x , NO _x , dioxins and / or by thermographical observation of the combustion progress of the combustion material values determined based on the rust.

Since the pulse of the secondary gas jet is kept essentially constant when the amount of combustion gas changes, it is achieved that the range of the secondary gas jet, the mixing quality of the flue gases and the mixing of the secondary gas jet into the flue gas lead to the operating requirements even under low-load operation.

An advantageous method is that the pulse of the primary gas flow is determined and the speed of the secondary gas jet is adjusted to a predetermined pulse flow ratio of the pulse of the primary gas flow to the pulse of the secondary gas jet when the amount of combustion gas changes.

This methodology takes into account, in particular, the change in the primary gas quantity in a simple manner. When converting the amount of primary gas released by the fire grate to flue gas, there is a change in the impulse flow of the flue gas stream rising from the fire grate and exiting the combustion chamber and thus also a change in the penetration or mixing behavior of the secondary gas jet into the flue gas stream. The amount of primary gas given is essentially proportional to the amount of flue gas, so that the pulse flow ratio of the pulse of the primary gas flow to the pulse of the secondary gas jet allows a qualitative statement about the mixing quality or the penetration of the secondary gas jet into the rising flue gas stream. The penetration or mixing ability of the secondary gas jet is inversely proportional to the pulse current ratio. The The pulse flow ratio to be regulated thus characterizes a predetermined penetration or mixing behavior of the secondary gas jet, which is essentially retained even when the primary gas quantity and / or the secondary gas quantity changes, in that the speed of the secondary gas jet is adjusted to the predetermined pulse current ratio.

It is also advantageous that the pulse of the primary gas flow is determined and the pulse flow ratio of the pulse of the primary gas flow to the pulse of the secondary gas jet is kept constant with a change in the amount of combustion gas, whereby an essentially constant mixing quality or penetration depth of the secondary gas jet is achieved even with load changes.

A further improvement in the mixing in the area near the nozzle orifice can be achieved by swirling the secondary gas jet. Particularly in the case of waste incineration plants with direct current furnaces, a relatively large area of colder combustion chamber atmosphere can be seen at the beginning of the grate, in which there is a risk of dioxin formation. This area can be intensively mixed and enriched with oxygen due to the further improved mixing behavior of the swirled secondary gas jet.

It is also advantageous that the speed of the secondary gas jets is controlled in groups when the secondary gas is supplied by means of a plurality of parallel jets.

It is also advantageous that an additive is added to the secondary gas jet. This enables a precise partial introduction of the additive into the flue gas stream, even under changing operating conditions. Due to the swirling of the secondary gas jet and the recirculation generated thereby, premixing with the secondary gas already occurs in the area near the nozzle.

In addition to the injection of the secondary gas, it is also provided to inject O ₂ -containing tertiary gas in order to smooth the flow profile in the radiation train in accordance with the inventive method.

The invention is also directed to a device for supplying an O ₂ -containing combustion gas for the combustion of lumpy combustible material, in particular garbage, into a combustion chamber with an associated grate grate of an incineration plant, with a primary gas supply device below the grate, control devices associated with the primary gas supply device and a gas delivery device for quantity-controlled supply of primary gas and with at least one gas nozzle above the fire grate, control devices assigned to the gas nozzle and gas delivery device for quantity-controlled supply of secondary gas, in which in the gas nozzle a control body that at least partially blocks the nozzle cross-section with an adjustment device that can be removed from the nozzle for speed-controlled supply of the Secondary gas is arranged and for the speed-controlled secondary gas supply at least one pressure determining the nozzle admission pressure is provided.

According to the invention it is provided that the pressure transducer is provided for determining the differential pressure between the nozzle pressure and the pressure above the fire grate and at least the pressure transducer and the control devices are connected to an evaluation and control unit, the differential pressure determination serving to act on the adjusting device such that the speed of the secondary jet is adjusted to a predetermined pulse of the secondary beam.

It is also advantageous that at least one sensor connected to the evaluation and control unit for characterizing the combustion is arranged in the combustion system.

An advantageous embodiment of the device can be seen in the fact that the regulating body has an essentially longitudinally extending and axially symmetrical shape adapted to the cross-sectional shape of the nozzle and is arranged so as to be axially displaceable relative to the longitudinal direction of the nozzle while maintaining a flowable nozzle cross section.

It is also advantageous that the nozzle and the regulating body have a circular cross-sectional shape.

It may also be advantageous for the nozzle and the regulating body to have a rectangular cross-sectional shape.

A further advantageous embodiment of the device according to the invention is that the control body can be guided on the nozzle wall via spacer elements connected to the control body.

It is advantageous that the spacer elements are designed as swirl bodies.

If the nozzle is advantageously narrowed in the area of its mouth and the control body is tapered in the flow direction at least on a section facing the mouth, a stepless regulation of the jet outlet speed is possible, which can be fine-tuned the more acute the angle of the tapered section is.

Advantageously, the adjustment device can be led out of the nozzle in the extension of its longitudinal axis with respect to the nozzle mouth. Thus, the nozzle can be sealed off from the environment at the point provided for removal, if necessary, in a simple manner by means of a shaft sealing ring.

An advantageous embodiment of the device can also be seen in the fact that the adjusting device is a tube, whose clear width continues symmetrically to the longitudinal axis of the control body in such a way that the adjustment device and the control body can be flowed through. This means that the nozzle can also be used to add an additive to bind pollutants in the flue gas.

In the event that the combustion chamber wall is constructed from refractory rock, at least the mouth region of the nozzle can be molded into the combustion chamber wall when the combustion chamber wall is being built up, so that the nozzle is part of the combustion chamber wall.

If, in the case of nozzles arranged in groups, a combination of the nozzle jets is to be largely avoided, it is advantageous that the swirl bodies of adjacent nozzles are designed in opposite directions.

The method according to the invention and a device operated according to this method will now be described in more detail with reference to the attached figures.

FIG. 1

eine Sekundärluftdüse mit integrierter Additivzuführung im Längsschnitt und Regeleinrichtungen,

FIG. 2

einen Verstellmechanismus für die Verschiebung der Verstelleinrichtungen mehrerer parallel geschalteter Düsen, und

FIG. 3

eine Müllverbrennungsanlage im Längsschnitt mit Primär- und Sekundärluftzuführung und Regeleinrichtungen.

Show it:

FIG. 1

a secondary air nozzle with integrated additive feed in longitudinal section and control devices,

FIG. 2nd

an adjusting mechanism for the displacement of the adjusting devices of several nozzles connected in parallel, and

FIG. 3rd

a waste incineration plant in longitudinal section with primary and secondary air supply and control devices.

One in FIG. 1 illustrated nozzle 1 is embedded in a ceiling 3 closing a combustion chamber 2 and serves the Supply of secondary air 4 as a combustion gas containing O ₂ in a waste incineration plant.

The nozzle 1 consists of a two-part base body 5a, 5b with a circular cross-section, the front part 5a of which, as seen in the flow direction, is molded into the ceiling 3 made of refractory rock. The rear part 5b is a tube which is flanged onto the front part 5a via a flange connection 6 and angled at its other end.

If the combustion chamber ceiling 3 is made up of fin tubes and refractory ramming compound, it is provided that the base body 5a, 5b is made in one piece as a tube.

The secondary air 4 is fed to the nozzle 1 via a blower 7a and an adjoining air delivery line 8a with control devices 9a, 9b, 10a, 10b consisting of a throttle valve 9a with a servomotor 9b and a flow meter 10a with a measurement signal converter 10b.

Provided in the interior of the nozzle 1 is a longitudinally extending, axially symmetrical control body 11 which is adapted to the cross-sectional shape of the nozzle 1 and which is arranged displaceably on the longitudinal axis of the nozzle while keeping an annular gap 12 through which it can flow.

The front part 13 of the control body 11 seen in the flow direction is continuously tapered in the flow direction, the cross section of the front part 5a of the nozzle 1 in the mouth region 14a to the nozzle mouth 14 continuously narrowing, so that when the control body 11 is displaced into the nozzle mouth 14b Mouth cross section 14 of the nozzle 1 is continuously reduced.

The regulating body 11 is connected to the regulating body 11 by spacer elements 15, which act as a swirl body in the Form of curved guide vanes are formed, guided on the inner wall 16 of the nozzle 1.

The control body 11 is displaced by means of an adjusting device 17 which is arranged on the control body 11 in the extension of the longitudinal axis of the control body 11 and which is brought out opposite the nozzle mouth 14a and driven by a motor 18.

The adjusting device 17 is designed as a tube, the clear width of which continues symmetrically to the longitudinal axis of the control body 11 in such a way that the tube 17 and the control body 11 can be flowed through, so that, if necessary, an additive 19 which binds undesirable flue gas components in gaseous, dusty or liquid form Air jet flowing out of the nozzle mouth 14a can be added.

A well-known slide bearing 20 with a final shaft sealing ring 20 is provided for sealing the passage of the pipe through the nozzle 1 from the environment and for mounting the pipe 17.

In addition to the illustrated circular cross-sectional shape of the nozzle 1 and its regulating body 11, it is also provided that the nozzle 1 and the regulating body 11 have a rectangular cross-sectional shape.

The difference between the nozzle admission pressure PD and the combustion chamber pressure PF is measured by means of a differential pressure sensor 21. The measurement signal is fed to a programmable evaluation and control device 22, in which, using previously programmed characteristics characterizing the nozzle 1 at different positions of the control body 6, the mass flow and the jet velocity in the mouth cross section 14b of the nozzle 1 or the jet pulse essentially characterizing the jet are calculated becomes.

In the event of changes in the load change or as a result of smoke gas analytical measurements 23, which are also recorded, evaluated and converted into control variables by the evaluation and control unit 22, the control body 11 is replaced by the motor 18 controlled by the evaluation and control unit 22 into the position at which the speed and the mass flow of the jet result in a pulse specified by the evaluation and control unit 22. If necessary, the throttle valve 9a of the secondary air supply is tracked by control signals coming from the evaluation and control unit 22.

FIG. 2 shows an adjustment mechanism for a plurality of nozzles 1 connected in parallel. The adjustment devices 17 led out of the nozzles 1 are each gripped at their rear end by a cam 25 arranged on a shaft 24 and by axially displacing the shaft 24 driven by the motor 18 into the nozzles 1 shifted so that the mouth cross section 14b decreases equally in all nozzles 1. When the shaft 24 is displaced in the opposite direction, the adjusting devices 17 are displaced in the opposite direction by return springs 26 arranged on them, so that the orifice cross section 14b increases equally in all the nozzles 1. But it is also provided that the cams 25 of the shaft 24 are provided with different pitches, so that the beams have a number of different pulses.

FIG. 3 shows a waste incineration plant 27 in which a plurality of the previously described nozzles 1a, 1b, 1c are arranged for supplying secondary air 4 into the ceiling 3 of the combustion chamber 2.

However, it is also provided to arrange nozzles 1d in the wall of the combustion chamber 2 and / or nozzles 1f as tertiary air nozzles for supplying tertiary air to one to assign radiation train 28 adjoining the combustion chamber 2.

The waste incineration plant 27 has a waste task 29, through which waste 30 as fuel is placed at one end of a longitudinally extending fire grate 31 in the form of a traveling grate for combustion. At the end of the grate 31, combustion residue 32 is fed to a disposal, not shown.

The combustion takes place primarily by supplying primary air 33 as an O ₂ -containing combustion gas through so-called underwind zones, which subdivide the fire grate 31 in the longitudinal and transverse directions, below the firing grate 31, of which the underwind zones 34a, 34b, 34c, 34d dividing in the longitudinal direction are shown. The underwind zones 34a, 34b, 34c, 34d are each connected via an air supply line 8b with control devices (not shown) and an adjoining common air supply line 8c with control devices 9a, 9b, 10a, 10b to a further blower 7b for supplying primary air 33. The total amount of combustion air 4.33 is predetermined by the vander waste incineration plant. The proportion of secondary air 4 is determined by the evaluation and control unit 22.

As the flow arrows show, from the grate 31 to rising flue gas 35, when leaving the firebox 2 in a narrowed transition zone 36 connecting the firebox 31 with the radiation train 28, which is schematically highlighted with a dash-dot line, it is accelerated and after flowing through the radiation train 28 for further treatment supplied flue gas cleaning.

The nozzles 1a, 1b, 1c, 1d, 1f each represent a row of nozzles. Each row of nozzles forms a group, the nozzles of which, as shown in FIG. 2 described about a Camshaft 24, 25 can be adjusted with an associated motor 18.

An infrared camera 23a directed towards the combustion grate 31 is provided for the sectoral detection of the combustion progress on the combustion grate 31. Further sensors 23b and 23c are provided for detecting the state of the flue gas at the end of the waste incineration plant 27, such as the flue gas temperature and the O ₂ , CO, CO ₂ , NO _x , SO _x and dioxin content. The detected measurement signals are also fed to the evaluation and control unit 22 and, in addition to the sectorial exposure to primary air 33 adapted to the progress of combustion of the garbage 30 distributed on the combustion grate 31, also require a pulse-adapted supply of the secondary air 4 by appropriate control of the regulating body 11 which varies the mouth cross section 14b. the speeds of the secondary air jets being regulated independently of the required amount of secondary air to the pulse of the secondary air jet specified by the evaluation and control unit 22.

The pairings of Roman numerals in FIG. 3 designate connections from the measuring and control circuit and the secondary air supply.

Criteria for the speed-controlled pulse adjustment of the jet are: adjustment of the penetration depth of the jet to the gas space to be penetrated, achieving a good mixing of the O ₂ load intended for the combustion of combustible flue gas components and achieving a good mixing of the inhomogeneous smoke gas when leaving the combustion chamber and making the flow profile more even in the radiation train.

Claims (19)

1. Method for supplying a O₂-containing combustion gas for the combustion of particulate combustible material, especially waste, in a combustion chamber with assocciated combustion grate of a combustion plant, with which part of the combustion gas is supplied as primariy gas through the combustion grate in a flow controlled manner and with which the other part of the combustion gas is supplied at least as secondary gas in at least one jet, while with varying combustion gas flow the velocity of the secondary gas jet is additionally controlled, characterized in that the impulse of the secondary gas jet is determined and with varying combustion gas flow the velocity of the secondary gas jet is adjusted to a predetermined impulse of the secondary gas jet.
2. The process according to claim 1, characterized in that with varying combustion gas flow the impulse of the secondary gas jet is kept substantially constant.
3. The process accoding to claim 1, characterized in that the impulse of the primary gas flow is determined and with varying combustion gas flow the velocity of the secondary gas jet is adjusted to a predetermined impulse stream ratio of the impulse of the primary gas stream to the impulse of the secondary gas jet.
4. The proesss according to at least one of the claims 1 - 3, characterized in that the impulse of the primary gas stream is determined and with varying combustion gas flow the impulse stream ratio of the impulse of the primary gas to the impulse of secondary gas jet is kept substantially constant.
5. Method according to at least one of the claims 1-4, characterized in that the secondary gas jet is provided with a swirl.
6. Method according to at least one of the claims 1-5, characterized in that in case of supplying the secondary gas by means of a plurality of parallel jets the velocity of the secondary gas jets is controlled in a groupwise manner.
7. Method according to anyone of the claims 1-6, characterized in that an additive is added to the secondary gas jet.
8. Device for supplying of a O₂-containing combustion gas for the combustion of particulate combustible material, especially waste, in a combustion chamber with assocciated combustion grate (31) of a combustion plant, with means for supplying primary gas below the combustion grate, control means assocciated to the primary gas supply means and gas conveying means for the flow controlled supply of primary gas and with at least one secondary gas nozzle (1) above the combustion grate, with control means assocciated to the gas nozzle (1) and gas conveying means for the flow controlled supply of secondary gas, with which in the gas nozzle a control element obstructing the nozzle cross section and having adjusting means (17) leading to the outside of the nozzle for the velocity controlled supply of the secondary gas is arranged and with which for the velocity controlled secondary gas supply at leat a pressure transducer (21) determining the nozzle admission pressure is provided, characterized in that the pressure transducer (21) is provided for the determination of the differential pressure between the nozzle admission pressure (PD) and the pressure (PF) above the combustion grate (31) and in that at least the pressure transducer (21) and the control means (9a, 9b, 10a, 10b, FIG.1) are connected to an evaluation and control unit (22), whereby the determination of the differential pressure is served for the biasing of the adjustment device (17) in such a manner that the velocity of the secondary jet is adjusted to a predetermined impulse of the secondary jet.
9. The device according to claim 8, characterized in that at least one sensor (23) is connected to the evaluation and control unit (22) for the characterization of the combustion in the combustion plant (27).
10. The device according to claim 8 or 9, characterized in that the control element (11) has a substantially longitudinally extending axis symmetrical form adapted to the cross section form of the nozzle (1) and is arranged to be displacable axially to the longitudinal axis of the nozzle, while none-obstructing a cross-flowable nozzle cross section (12).
11. The device according to at least one of the claims 8-10, characterized in that the nozzle (1) and the control element (11) have a circular cross section form.
12. The device according to at least one of the claims 8-10, characterized in that the nozzle (1) and the control element (11) have a rectangular cross section.
13. The device according to at least one of the claims 8-12, characterized in that the control element (11) is guidable along the nozzle wall (16) by means of spacer elements (15) connected to the control element (11).
14. The device according to claim 13, characterized in that the spacer elements (15) are formed as swirl elements.
15. The device according to at least one of the claims 8-14, characterized in that the nozzle (1) is narrowed in the range of its mouth (14a) and in that the control element (11) is tapered in flow direction at least a section (13) facing towards the mouth (14b).
16. The device according to at least one of the claims 8-15, characterized in that the adjustment means (17) is led from the nozzle to the outside opposite of the nozzle mouth (14a) in extension of its longitudinal axis.
17. The device according to at least one of the claims 8-16, characterized in that the adjustment means (17) is comprised by a tube, the clear width of which is continuing symmetrically to the longitudinal axis of the control element (11) in such a manner that the adjustment means (17) and the control element (11) are cross-flowable.
18. The device according to at least one of the claims 8-17, characterized in that the nozzle (1) is part of the combustion chamber wall (3).
19. The device according to at least one of the claims 14-18, characterized in that in case of groupwise arranged nozzles (1) the swirl elements (11) of adjacent nozzles are of opposite design.

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