EP0718555A1 - Method and device for waste combustion - Google Patents

Abstract

The waste burning method involves feeding the waste (20) for burning on a burner (4) via a feed shaft (2) and delivery slider. Air is fed to the burner to maintain combustion. The water content of the waste to be burnt is determined using microwave signals and the measurement values stored in a process control unit (18) which controls the combustion of the waste depending on the magnitude of the water content. The water content is determined at a defined time before combustion and the process control unit controls the quantity of air fed to the burner during waste combustion depending on the magnitude of the water content. The water content can be measured in the delivery shaft about 30 minutes before combustion.

Description

The invention relates to a method and a device for incinerating waste according to the preamble of claims 1 and 9.

Waste as fuel is very inhomogeneous in its composition. Their properties such as calorific value, ignitability and burning rate fluctuate in a very wide range. Waste is incinerated, which consists, for example, of organic residual waste, industrial waste, wood, stones, plastics, glass, ceramics, paper and cardboard. The waste is provided for incineration in such a combination that it always contains a certain amount of combustible components. The waste intended for incineration is available in different sizes. In addition, they have different proportions of water, which must be taken into account when burning. In contrast, the compositions and chemical-physical properties of fuels such as coal, gas and oil are known. In contrast to the waste mentioned above, it is easily possible to optimize an incineration plant for these fuels.

Incineration plants for waste have so far mostly been operated with a low degree of automation. In most previously known systems of this type, a control room is provided, which is looked after by at least one surgeon. The operator is responsible for adapting the combustion control to the fuel that is produced. He is dependent on his personal observation of the combustion process. In most incineration plants, at least one video camera is provided, which is arranged above the combustion chamber. Corrective interventions in the combustion process can, however, only be made retrospectively, ie when a change in the composition of the waste to be incinerated has become noticeable through a change in the quality of the incineration. Then it is usually too late for corrective interventions. Such a combustion process will always fluctuate more or less strongly around its optimal operating point. In order to minimize these fluctuations, attempts are underway to increase the degree of automation of waste incineration. For this purpose, for example, special measuring sensors were installed in the combustion chamber, which monitor the combustion process. The information obtained in this way, which the surgeon has so far recorded visually, is recorded automatically and is immediately made available to a system controlling the combustion as a correction factor.

In EP-A-0 317 731 it is proposed to observe the area of the waste application on the combustion grate with optical radiation receivers, which are preceded by optical filters which selectively detect the electromagnetic radiation emitted by H ₂ O or CO ₂ molecules. The indicator for the water content of the waste obtained in this way is fed to the control device as a disturbance variable for controlling the combustion. With the method described here, a signal is obtained which provides information about the water content of the waste before the waste is incinerated, so that the combustion parameters can be adapted directly to the incinerating waste. A disadvantage of this process, however, is that the time from the drop in the waste in the drop zone to the incineration on the grate is too short for changes in the combustion parameters to have a positive effect. The dead times in this process are of the order of 30 to 60 minutes. The transport time from the waste disposal area to the main incineration zone, on the other hand, is in the range of 10 minutes. In the method described here, the water content of the waste is only determined from the water evaporating on the surface. The water contained in the waste is not recorded and can therefore not be taken into account when controlling the combustion.

EP-A-0 352 620 describes a method in which the grate on which the waste is incinerated is observed with the aid of a video camera. The video image obtained is automatically processed by means of a computer. Information about the course of the combustion, such as, for example, the temperature distribution and the location of the main fire zone, is derived from the signals obtained from this and is then fed to the process control system as a control variable. With this method, a proactive way of incinerating waste is not possible, since only the surface temperature on the grate is recorded. Embers or smoldering nests under the surface of the garbage to be burned, which influence the combustion process, are not taken into account.

The invention is therefore based on the object of demonstrating a method which enables a forward-looking manner of incinerating waste of all kinds, so that it is known even before the incidental waste is incinerated which parameters the furnace is to be set to. The invention is also based on the object of demonstrating a device with which this method can be carried out.

A method with which this object is achieved is disclosed in claim 1.

A corresponding device for incinerating waste is disclosed in claim 9.

The best way to incinerate waste is to determine the composition or nature of the waste before incineration, and to ensure that its incineration is fully tailored to this information. One of the most important factors for optimal combustion is knowledge of the water content of the waste. If the water content of waste due for incineration is known both on its surface and in its interior, the incineration can be controlled in advance without major problems.

According to the invention, the water content of the waste to be incinerated is determined a few minutes before incineration with the aid of microwave signals. The determination of the water content of the waste takes place in the allocation shaft, in such a timely manner that the information obtained is completely available during incineration.

For this purpose, microwave signals are emitted perpendicular to the direction of conveyance of the allocation shaft, in which the waste is transported to a grate provided for incineration. The water content of the waste causes signal weakening and / or phase changes in these microwave signals. These are evaluated to determine the water content in the waste. For this purpose, microwave signals are transmitted from a first inner wall of the allocation shaft to the opposite wall and received there. The microwaves sent through the waste experience a signal weakening and / or phase change. The water content of the waste just examined is then determined from this by comparing the transmitted and received microwave signals. The information signals obtained are forwarded to a process control unit. This is intended to control the supply of air for the incineration of the waste taking place on the grate and the allocation control of the waste. According to the invention, microwave signals can also be transmitted perpendicular to the conveying direction of the allocation shaft and the microwave signals reflected on the waste can be evaluated for the determination of the water content. The information signals determined from this are also fed to the process control unit. Furthermore, to determine the water content in waste, a standing microwave can be formed between two opposite walls of the allocation shaft and the water content of the waste can be evaluated in a corresponding manner from the signal weakening and / or phase change of this standing microwave. To determine the water content, the microwave signals that are required for the upgrading are forwarded to evaluation units. The measured values determined by these evaluation units are stored in the process control unit.

The device for incinerating waste is equipped with an allocation shaft, which is followed by a feed slide. It is used to convey the amount of waste to be incinerated to a grate provided for this purpose, to which air is fed to maintain the incineration. At least one, preferably a plurality of microwave transmitters and microwave receivers, which are connected to at least one evaluation unit, are installed in the allocation shaft. The signal outputs of the evaluation units are connected to a process control unit. This is intended for controlling the air supply to the grate. According to the invention, four combined microwave transmission / reception modules are provided in at least two planes α and β that are perpendicular to one another and perpendicular to the conveying direction of the allocation shaft. Two combined microwave transmission / reception modules are installed at a defined distance from each other on a first inner wall of the allocation shaft. The two other combined microwave transmitter / receiver modules belonging to the same level are installed on the opposite wall in such a way that two combined microwave transmitter / receiver modules are arranged opposite each other on a straight line perpendicular to the conveying direction of the distribution shaft.

Further features essential to the invention are disclosed in the subclaims.

The invention is explained in more detail below with the aid of schematic drawings.

Fig. 1

eine Vorrichtung zur Verbrennung von Abfällen im Vertikalschnitt,

Fig. 2

den mit einer speziellen Meßvorrichtung versehenen Zuteilungsschacht der Vorrichtung gemäß Fig.1,

Fig. 3

den Signalverlauf einer senkrecht zur Förderrichtung des Abfalls gesendeten und durch den Abfall hindurch geleiteten Mikrowelle,

Fig. 4

den Signalverlauf einer am Abfall reflektierten Mikrowelle,

Fig. 5 und 6

durch metallische Abfälle geleitete sowie daran reflektierte Mikrowellensignale,

Fig. 7 und 8

durch nicht metallische Abfälle geleitete sowie daran reflektierte Mikrowellensignale.

Show it:

Fig. 1

a device for incinerating waste in vertical section,

Fig. 2

the allocation shaft of the device according to FIG. 1 provided with a special measuring device,

Fig. 3

the signal curve of a microwave transmitted perpendicular to the direction of conveyance of the waste and guided through the waste,

Fig. 4

the signal curve of a microwave reflected on the waste,

5 and 6

microwave signals conducted through and reflected by metallic waste,

7 and 8

microwave signals conducted through and reflected by non-metallic waste.

The device 1 shown in FIG. 1 for the combustion of all types of waste comprises an allocation shaft 2, a feed slide 3 and a grate 4, a measuring device 5, three evaluation units for microwave signals 15, 16 and 17, and a process control unit 18. The in a dimensioning section 30 of the distribution shaft 2 waste 20 are provided for incineration on the grate 4 in about 20 to 30 minutes. To determine the water content in these wastes 20, the measuring device 5 is provided in the dimensioning section 30 of the distribution shaft 2, which in the exemplary embodiment shown here is equipped with five microwave transmitters or receivers 6S, 6E, 7S, 7E and 8.

The amount of waste 20 that is loaded onto the grate 4 for incineration corresponds to the amount of waste that can be filled into the dimensioning section 30 of the allocation shaft 2. At the upper end 30A of the dimensioning section 30, a microwave transmitter 6S is installed on the first inner wall 2A of the allocation shaft 2 and a microwave receiver 6E is installed on the opposite inner wall 2B at the same height as the microwave transmitter 6S. A standing microwave is formed between these two microwave devices 6S and 6E. From the signal weakening and / or phase changes of this standing microwave, the water content of the wastes 20 transported into the dimensioning section 30 can be determined with the aid of the evaluation unit 15. A signal with the information about the water content is forwarded from the evaluation unit 15 to the process control unit 18. At a defined distance from the first microwave device 6S and 6E, a microwave transmitter 7S is installed on the inside of the wall 2a, as seen in the conveying direction of the allocation shaft 2, from which the vertical through the in the Dimensioning section 30 of the allocation shaft 2 to be transported waste 20 microwaves. The microwave signals passing through the wastes 20 are received by the microwave receiver 7E installed on the inside of the wall 2B at the same level as the microwave transmitter 7S. In the evaluation unit 16, to which the microwave transmitter 7S and the microwave receiver 7E are connected, the water content in the waste 20 is determined from the signal weakening and / or phase change of the received microwave signals compared to the transmitted microwave signals. The measured values are transmitted from the evaluation unit 16 to the process control unit 18. A combined microwave transmitter / receiver module 8 is also installed at a defined distance below the microwave transmitter 7S on the inner wall 2A of the allocation shaft 2. This sends out microwave signals. The microwave signals reflected at the waste 20 are received again by the module 8. The microwave signals sent and received by the module 8 are fed to the evaluation unit 17. This determines measured values from the signal weakening and / or phase change between the transmitted and the reflected microwave signals, which are passed on to the process control unit 18. All measurement signals transmitted from the evaluation units to the process control unit 18 are stored there. They are available for the combustion of the waste 20 for controlling the air supply to the grate 4. The waste 20 contained in the allocation shaft 2 is conveyed onto the grate 4 for incineration with the aid of the feed slide 3. The amount of waste 20 that is loaded onto the grate 4 corresponds to the amount of waste that is currently in the dimensioning section 30 of the allocation shaft 2. The dimensioning section 30 comprises only that part of the allocation shaft 2 in which the microwave transmitters and receivers 6S, 7S, 7E, and 8 are arranged.

With the help of the feed slide 3, exactly the amount of waste 20 can be transported onto the grate, the water content of which was determined about 30 minutes before the incineration when filling into the dimensioning section 30. To ensure an error-free assignment between the measured values stored in the process control unit and to ensure the waste 20 that has just been transported to the grate for incineration, the feed slide 3 is also controlled by the process control unit 18. An air damper 19L, which is installed in a pipeline 19, is also controlled by the process control unit 18. This opens into channels 19K on the underside of the grate 4, from where the amount of air required for optimal combustion is supplied from the grate 4.

The density of the waste 20 is determined using separate methods. The information is also stored in the process control unit and taken into account when controlling the combustion.

2 shows the dimensioning section 30 of the allocation shaft 2 in an enlarged view with a special embodiment of the measuring device 5. The measuring device 5 here has eight combined microwave transmitter / receiver modules 7, 8, 9, 10, 11, 12, 13, 14 . In this case, four combined microwave transmission / reception modules 7, 8, 9, 10, 11, 12, 13 and 14 are arranged in two planes α and β, which are perpendicular to one another and perpendicular to the conveying direction of the distribution shaft 2. As shown in FIG. 3, two of these microwave transmission / reception modules 7 and 9 are at a defined distance from one another on the inside of the wall 2A of the allocation shaft 2 and the two other microwave transmission / reception modules 8 and 10 also belonging to the plane α opposite inside of the wall 2B installed so that two microwave transmitter / receiver modules 7 and 8 are arranged on a straight line perpendicular to the conveying direction of the allocation shaft 2 opposite each other. In the same way, the microwave transmission / reception modules 11, 12, 13 and 14 belonging to the plane β are arranged.

3 shows the change in a microwave signal over the course of a minute. The microwave signal D is transmitted by the microwave transmission / reception module 7 and received by the microwave transmission / reception module 8. During this one minute there will be waste 20 bypassed the microwave transmission / reception modules 7 and 8 and the dimensioning section 30 is filled with them. From the decrease in the intensity of the microwave D, it can be clearly seen that the waste 20 which is being guided past is initially dry, but the water content of the subsequent waste 20 is constantly increasing. FIG. 4 shows the course over time of a microwave R, which was emitted by the microwave transmission / reception module 7 in a manner reflected by the waste 20 that was passed. The reflected microwave is again received by the microwave transmission / reception module 7. The reflected microwave signal R also shows that the first bypassed wastes 20 initially dry and the subsequent wastes 20 have a considerable water content, which also leads to a weakening of the reflected microwave signal.

As FIGS. 5, 6, 7 and 8 show, several measurements carried out with the microwave transmission / reception modules 7, 8, 9, 10, 11, 12, 13, 14 can be used to clearly determine whether the wastes are loaded with water, or whether the change in the microwaves is caused by metallic wastes which are directed past the measuring device 5. In order to show this, it is assumed that during the time t1 to t2 a larger metallic piece of waste 21 is passed between the microwave transmitter / receiver modules 7 and 8. FIG. 5 shows the microwave signal 7R reflected on the metallic waste 21 during the time t1 to t2, which is received by the microwave transmitter / receiver module 7 and was also transmitted by the latter. The reflected microwave 7R show a clear amplification, which it experienced when reflecting on the metallic waste 21. The microwave signals 7T emitted by the microwave transmission / reception module 7 are weakened by the metallic waste and are received in this form by the microwave transmission / reception module 8. During the time t3 to t4, the metallic piece of waste 21 passes the microwave transmission / reception modules 11 and 12. As can be seen from FIG. 6, here too the transmission and reception module 11 emitted by the microwave transmission / reception module Transceiver module 12 received microwave signal 11T through the metallic piece of waste 21 weakened, while the microwave signal 11R emitted by the microwave transmission / reception module 11 and reflected by the metallic waste 21 was amplified.

In a departure from this, the microwave signals 9T and 9R or 13T and 13R transmitted, transmitted, received or reflected by the microwave transmission / reception modules 9 and 10 or 13 and 14 have no changes, as can be seen from FIGS. 7 and 8 is. This means that non-metallic wastes 22 were transported past the microwave transmitter / receiver modules 9, 10, 13 and 14. On the one hand, the evaluation units (not shown here), which are connected to the microwave transmitter / receiver modules 7, 8, 9, 10, 11, 12, 13 and 14, are subject to greatly modified transmitted or reflected microwave signals 7T and 7R and 11T and 11R and on the other hand unchanged transmitted or reflected microwave signals 9T, 9R and 13T and 13R, the evaluation units which are connected to the microwave transmitter / receiver modules 7, 8, 11, 12 can recognize that a large metallic piece of waste 21 is conveyed into the design section 30. This means that the measurement of the water content must be suspended in the time t1 to t4. They therefore do not give any information signals to the process control unit (not shown here). This receives only the information signals from the evaluation units, which are connected to the microwave transmission / reception modules 9, 10, 13, 14. The process control unit is designed such that in this case it stores the water content of the waste 22, or if the water content of the waste 22 is too low, it does not store the information. This means that the control of the supply of air for the combustion of these wastes 21 and 22 is tracked according to a value permanently stored in the process control unit.

Claims (12)

Process for the incineration of waste (20, 21, 22) which are conveyed via an allocation shaft (2) and a feed slide (3) for incineration onto a grate (4) to which air is supplied in order to maintain the incineration, characterized in that the water content of the waste to be incinerated (20, 21, 22) is determined with the aid of microwave signals and the measured values are stored in a process control unit (18) which shows the incineration of the waste (20, 21, 22) as a function of the size of the water content controls. Method according to Claim 1, that the water content of the waste (20, 21, 22) to be incinerated is determined at a predetermined time before the incineration, and that the process control unit (18) is dependent on the size of the water content during the incineration of the waste ( 20, 21, 22) controls the amount of air to be supplied to the grate (4). Method according to one of claims 1 or 2, characterized in that the water content of the waste (20, 21, 22) is determined about 30 minutes before the incineration within a dimensioning section (30) of the allocation shaft (2). Method according to one of Claims 1 to 3, characterized in that microwave signals are emitted within the dimensioning section (30) perpendicular to the conveying direction of the allocation shaft (2) and signal weakenings and / or phase changes of these microwave signals for determining the water content in the waste (20, 21, 22) are evaluated. Method according to one of claims 1 to 4, characterized in that from the inside of a first wall (2A) of the dimensioning section (30), microwave signals are transmitted perpendicularly to the conveying direction of the allocation shaft (2) to the opposite wall (2B) and received there, and from the signal weakening and / or phase change of the received microwave signals a measured value is determined in relation to the transmitted microwave signals when passing through the waste (20, 21, 22) and is stored in the process control unit (18). Method according to one of Claims 1 to 5, characterized in that microwave signals are emitted from the inside of a first wall (2A) of the dimensioning section (30) perpendicular to the conveying direction of the allocation shaft (2) and the signal weakenings and / or phase changes of the waste (20 , 21, 22) reflected microwave signals compared to the transmitted microwave signals for the determination of the water content in these wastes (20, 21, 22) are evaluated and the measured values determined are stored in the process control unit (18). Method according to one of Claims 1 to 6, characterized in that, in order to determine the water content in waste (20, 21, 22) in the interior of the dimensioning section (30), at least one standing microwave is formed between two opposite walls (2A, 2B) the signal weakening and / or phase change of this standing microwave determines the water content of the waste (20, 21, 22) to be incinerated and the measured values are stored in the process control unit (18). Method according to one of Claims 1 to 7, characterized in that, in order to determine the water content in the waste (20, 21, 22) to be incinerated, the transmitted and received microwave signals are fed to an evaluation unit (15, 16, 17) which are fed from the Signal weakening and / or phase changes of the received microwave signals compared to the transmitted microwave signals determines the water content of the checked waste (20, 21, 22) and forwards the measured values to the process control unit (18) in which they are stored. Device for incinerating waste with an allocation shaft (2), which is followed by a feed slide (3) is, which conveys the waste to be incinerated (20, 21, 22) on a grate (4) provided for this purpose, to which air can be supplied to maintain the combustion, characterized in that at least one measuring device (5) for the Determination of the water content of waste (20, 21, 22) installed and connected to at least one evaluation unit (15, 16, 17)), the signal outputs of which are connected to a process control unit (18) which is used to control the air supply to the grate (4th ) is provided. Device according to claim 9, characterized in that the measuring device (5) is installed within a dimensioning section (30) of a defined size of the allocation shaft (2) and microwave transmitters (6S, 7S), microwave receivers (6E, 7E) and combined microwave transmitter / receiver modules ( 7, 8, 9, 10, 11, 12, 13, 14), which are connected to three evaluation units (15, 16, 17), the signal outputs of which are connected to the process control unit (18) which is used for controlling the air supply to Grate (4) is provided. Device according to one of claims 9 or 10, characterized in that in two or more planes (α and β) which are perpendicular to one another and perpendicular to the conveying direction of the distribution shaft (2), at least four combined microwave transmitter / receiver modules (7, 8, 9, 10 and 11, 12, 13, 14) are provided. Device according to one of claims 9 or 10, characterized in that in each case two combined microwave transmission / reception modules (7, 9 or 8, 10) at a defined distance from one another on the inside of a first wall (2A) of the allocation shaft (2) and the two other combined microwave transmission / reception modules (8, 10 and 12, 14) belonging to the same level (α and β) are installed on the opposite wall (2B) such that two combined microwave transmission / reception modules ( 7, 8 or 9, 10) are arranged on a straight line perpendicular to the conveying direction of the allocation shaft (2) opposite one another.

Images