EP1008806A2 - High temperature resistant grate bar - Google Patents

Abstract

A high temperature grate bar has a layer (3) of ceramic elements (5) embedded in the interspaces (6) of a metallic mesh frame structure (4). Preferred Features: The ceramic elements (5) comprise hydraulically or chemically bonded aluminum oxide, chromium oxide, silicon carbide, silicon nitride, silicon dioxide or their mixtures.

Description

Technical field

The invention relates to the field of combustion technology. It affects a high temperature resistant grate bar with a ceramic protective layer, which is particularly suitable for a grate in a combustion furnace for the combustion of Garbage can be used.

State of the art

It is known prior art to burn garbage on a combustion grate, whose air or water-cooled grate bars by defined movement Transport garbage through the firebox.

• Die deutliche Schwankung der Müllqualität hinsichtlich Brennwert, Dichte, Strömungswiderstand, Feuchte usw. führt zu enormen Temperaturschwankungen, häufig zu nicht tolerierbaren Übertemperatur luftgekühlter gegossener Roststäbe.
• Die Bewegung der Stäbe relativ zueinander und relativ zum Müll führt zu hohem Abrasionsverschleiss, der bei hohen Temperaturen beschleunigt stattfindet.
• Der häufige Temperaturwechsel mit grossen Temperaturgradienten und Temperaturtransienten führt zu thermomechanischem Versagen einzelner Roststäbe. Die daraus resultierenden geänderten Strömungsbedingungen für die Primärluft schädigen letztendlich weite Bereiche des Rostes.

In the air-cooled grates, primary air flows through the grate and is only used to cool the grate bars and then as a necessary reaction partner for combustion. The following disadvantages are associated with this system:

• The significant fluctuation in waste quality with regard to calorific value, density, flow resistance, humidity, etc. leads to enormous temperature fluctuations, often to the intolerable excess temperature of air-cooled cast grate bars.
• The movement of the bars relative to one another and relative to the waste leads to high abrasion wear, which takes place accelerated at high temperatures.
• The frequent temperature change with large temperature gradients and temperature transients leads to thermomechanical failure of individual grate bars. The resulting changed flow conditions for the primary air ultimately damage large areas of the grate.

These disadvantages are attempted by using water-cooled grate bars remove. Although the expensive cast alloys used for air-cooled grids need to be cheaper with water-cooled grates by using cheaper Sheet metal structures can be saved, have water-cooled gratings a number of disadvantages. On the one hand, they are opposed to air-cooled grates technically much more complex because they have a separate cooling water circuit exhibit and are very sensitive to damage. In the event of leaks, they must be switched off become. On the other hand, a lot of thermal energy is disadvantageously applied to the system deprived of low levels, reducing the thermal efficiency of the waste incineration plant reduced.

Therefore, one tries to use the material in accordance with the stress To improve the properties of the air-cooled grate bars. So is from EP 0 382 045 A2 a grate bar is known which consists of a supporting lower element Steel or cast iron and an upper element made of ceramic material, the ceramic element forming the bed for the garbage to be incinerated. Because of the ceramic material used, the top element a high temperature resistance and wear resistance, so that the Rust can be air-cooled. The upper ceramic element and the lower element each grate bar are form-fitting and by means of bolts and elastic Elements, e.g. B. connected springs. A disadvantage of this state of the Technique is that in the event of an impact load, the upper plate is formed ceramic element easily shatters because the ceramic is very brittle and one has high impact sensitivity and low elongation at break. Also is it is not possible the big temperature differences and the different to adequately compensate for the thermal expansion behavior of the two elements, so that there is undesirable tension and distortion shorten the operating time of the grate. In addition, there is a high manufacturing tolerance The connections are required so as not to go through the assembly to cause pre-damage. This leads to high manufacturing costs.

A similar solution is known from DE 33 14 098 C2, in which the grate block or grate bar as part of a grate covering for a waste incinerator is designed so that the grate block exposed to combustion or grate bar part made of fine ceramic material and the block or Rod holder with bearing part is made of steel or cast steel. Also be here both parts held together by screw connections. This execution In addition to the disadvantages listed above, it also has the disadvantage that it is very expensive because almost the entire grate block or grate bar is made of expensive ceramic Material exists.

Presentation of the invention

The invention tries to avoid all of these disadvantages. You have the task based on an air-cooled, high-temperature-resistant grate bar for one To show combustion grate, its directly exposed to combustion Parts are made of ceramic material, the grate bar being relatively inexpensive absorbs impact stresses well and is easy to wear distinguished so that it has a long service life.

According to the invention, this is the case with a grate bar according to the preamble of the claim 1 achieved in that the ceramic layer from a variety ceramic elements that exist in spaces between a lattice-like metallic Frame structure are embedded.

The advantages of the invention are that on the one hand only those at high Temperatures in parts exposed to corrosive and oxidizing atmospheres of the grate bar with a high temperature resistant ceramic layer are, so that the grate bar is relatively inexpensive, on the other hand with a Impact stress does not shatter the ceramic, as it is in the ductile metallic Frame structure is embedded, which absorb this stress and can easily cope. Because the frame structure a variety of ceramic Enclosing elements also has the added advantage that at a possible failure of a ceramic element, the grate bar anyway still has sufficient operational reliability and will continue to be used can. Finally, the temperature differences within the grate bar are significant smaller than, for example, a grate bar with a surface a single ceramic plate is covered, consequently are less thermal Tensions exist, so the grate bar has a longer life having.

It is expedient if the metallic frame structure is due to the manufacturing process Is part of the grate bar. Then there is no need to attach the frame structure to the Grate bar surface. The ceramic elements can later in the spaces the frame structure will be filled or they will be right in the making the metallic components of the grate bar pressed into the frame structure or poured.

It is also advantageous if the metallic frame structure is a separate component which is connected to the grate bar and before or after the connection is filled with the ceramic elements because this enables prefabrication and old bars can be easily repaired on site. From functional or cost reasons, it is also advantageous if the basic carrier and the the ceramic-containing frames are made of different materials

It is also an advantage if the gaps accommodate the ceramic Elements are designed such that they are parallel to the grate bar surface aligned cross section of the gaps or ceramic elements is polygonal or round or elliptical and has a degree of elongation in the longitudinal direction of the grate bar between 1 and 20, preferably 1 to 3, and a depth ratio relative to the transverse direction between 0.1 and 20, preferably 1 to 3, exhibit. Due to the longitudinal stretching of the ceramic elements, there are only a few Edges present in the transverse direction so that when the grate bar moves in Longitudinal only a small amount of friction is caused, which is beneficial in Regarding the material transport, but also in terms of the wear of the Rust rod affects.

Furthermore, it is expedient if the spaces between the metallic frame structure or the ceramic elements perpendicular to the grate bar surface have variable cross sections. This can, for. B. be achieved that ceramic material during the stress not from the metallic Frame structure torn out, but is held there.

The ceramic material consists of at least one component of oxidic, carbidic or nitridic phases, preferably aluminum oxide, chromium oxide, Silicon carbide, silicon nitride, silicon dioxide or mixtures of these compounds and is hydraulically or chemically bound. It can be fiber reinforced material (Metal or ceramic fibers), porous structures or monolithic structural ceramics his. By using variable thicknesses, materials and shapes for different Places of the grate bar are advantageous the heat flow and erosion customizable according to requirements.

Brief description of the drawing

Fig.1

eine schematische Darstellung eines Teiles eines Müllverbrennungsrostes in der Draufsicht (oberer Teil von Fig. 1 ) und in der Seitenansicht (unterer Teil von Fig.1) nach dem bekannten Stand der Technik;

Fig. 2

eine Draufsicht auf die metallische Rahmenstruktur eines Roststabes, welche mit keramischen Elementen gefüllt ist, in einer ersten Ausführungsvariante der Erfindung;

Fig. 3

eine Draufsicht auf die metallische Rahmenstruktur eines Roststabes, welche mit keramischen Elementen gefüllt ist, in einer zweiten Ausführungsvariante der Erfindung;

Fig. 4

eine Draufsicht auf die metallische Rahmenstruktur eines Roststabes, welche mit keramischen Elementen gefüllt ist, in einer dritten Ausführungsvariante der Erfindung;

Fig. 5

einen Längsschnitt durch einen erfindungsgemässen Roststab gemäss Fig. 3;

Fig. 6

einen Längsschnitt durch einen weiteren erfindungsgemässen Roststab.

Several exemplary embodiments of the invention are shown in the drawing. Show it:

Fig. 1

a schematic representation of a part of a waste incineration grate in plan view (upper part of Figure 1) and in side view (lower part of Figure 1) according to the known prior art;

Fig. 2

a plan view of the metallic frame structure of a grate bar, which is filled with ceramic elements, in a first embodiment of the invention;

Fig. 3

a plan view of the metallic frame structure of a grate bar, which is filled with ceramic elements, in a second embodiment of the invention;

Fig. 4

a plan view of the metallic frame structure of a grate bar, which is filled with ceramic elements, in a third embodiment of the invention;

Fig. 5

a longitudinal section through an inventive grate bar according to FIG. 3;

Fig. 6

a longitudinal section through a further grate bar according to the invention.

Only the elements essential for understanding the invention are shown.

Way of carrying out the invention

The invention is explained below using exemplary embodiments and the figures 1 to 7 explained in more detail.

1 schematically shows part of an air-cooled grate of a waste incineration plant, with a top view in the upper drawing, and a view in the lower drawing Side view can be seen. The grate consists of 4 rows of grate bars 1, in which 3 grate bars 2 are arranged side by side. The rust is not in one shown incinerator arranged in which waste is burned. The garbage is passed through by a defined movement of the individual grate bars 2 transported the firebox. Primary air flows through the grate Grate bars 2 cools and is then used to incinerate the waste. This is known in the art. Because the surface of the grate bar Temperatures> 700 ° C and also oxidizing and corrosive atmospheres exposed, the surface facing the garbage bed becomes at least provided with a ceramic layer 3 (see lower part of Fig. 1). This is also known prior art.

According to the present invention, however, this ceramic layer 3 is special educated. Fig. 2 shows a first embodiment of the invention Top view of the metallic frame structure 4 of a grate bar 2, which with ceramic elements 5 is filled. The metallic frame structure 4 forms in Longitudinal direction of the grate bar 2 extended spaces 6 (see right part of Fig. 2), which are filled with ceramic elements 5.

The use of ceramic elements 5 ensures high temperature resistance of the grate bar 2 reached. In addition, shatters in the inventive Do not release the ceramic in the event of an impact stress, as it is in the ductile metallic frame structure 4 is pressed in, so that the grate bar relative is inexpensive, on the other hand, the ceramic does not with impact stress shatters because it is embedded in the ductile metallic frame structure 4, the can absorb this strain and can easily cope with it. Because the frame structure 4 encloses a large number of ceramic elements 5 furthermore as an advantage that in the event of a possible failure of a ceramic Element 5 of the grate bar 2 still sufficient operational reliability has and can be used further. Finally, there are the temperature differences within the grate bar 2 much smaller than, for example for a grate bar, the surface of which is covered with a single ceramic plate is covered, consequently there are fewer thermal stresses, so that the grate bar 2 has a longer service life.

The metallic frame structure 4 can be very different in terms of its shape be trained. 2 shows, for example, a hexagonal contour of the spaces 6. The ceramic elements to be inserted into the spaces 6 5 thus have an easy to manufacture honeycomb structure.

3 finally shows an embodiment in which the ceramic elements 5 are brick-shaped and in rectangular spaces 6 of the metallic Frame structure 4 are pressed. This shape is also quite simple too realize.

4, elliptical cross sections of the spaces 6 are also parallel to the grate bar surface and accordingly elliptical cross sections of the associated ceramic elements 5 conceivable.

A longitudinal stretching of the ceramic elements 5 in the longitudinal direction of the grate bars 2 has the advantage that there are only a few edges in the transverse direction, so that at the movement of the grate bar 2, which takes place in the longitudinal direction, is only slight Friction is caused, which is convenient in relation to the transport of the Burning material, but also in relation to the wear of the grate bar 2. Degree of stretching is conceivable in the range from 0.1 to 20. Below the degree of stretching the quotient from longitudinal expansion to transverse expansion (in relation to to the longitudinal direction of the grate bar) of a ceramic element 5 or a space 6 can be understood. So they are also square Cross sections or circular cross sections of the spaces possible. Prefers an aspect ratio of about 1 to 3 should be used. The depth ratio relative to the transverse direction should also be between 0.1 and 20, preferably 1 to 3.

5 shows a longitudinal section through a grate bar 2 according to the invention Fig. 3. The ceramic elements 5, which are embedded in the spaces 6 are in the form of a brick, i.e. H. they are cuboid. The gaps 6 of the metallic frame structure 4 or the ceramic elements 5 thus point in this embodiment perpendicular to the grate bar surface a constant cross section.

6 shows another possible embodiment variant in a longitudinal section a grate bar. The spaces 6 of the metallic frame structure point here 4 or the ceramic elements 5 perpendicular to the grate bar surface a variable cross-section, in such a way that the ceramic elements 5 have a slightly smaller cross section directly on the surface than in a distance from the surface. This has the advantage that during stress the ceramic material is not torn out, but the metallic surface somewhat enlarged compared to the variant according to FIG. 5. The high wear and temperature resistance of this grate bar is given anyway.

According to the invention, the ceramic elements 5 consist of at least one Component of oxidic, carbidic or nitridic phases. They preferably contain Aluminum oxide, chromium oxide, silicon carbide, silicon dioxide or mixtures of these connections. The ceramic material is hydraulic or chemically bound.

The ceramic elements 5 can also be made of fiber-reinforced material (metal or ceramic fiber). Elements 5 made of monolithic are also conceivable Ceramic or porous structures. The ceramic elements 5 can before Use in the spaces 6 of the metallic frame structure 4 as sintered Body are made.

The ceramic elements 5 can be before or during the manufacture of the metallic Frame structure 4 of grate bar 2 is pressed into it, cast in, can be soldered in or fitted with a positive fit (e.g. dovetail).

The metallic frame structure 4 can either be designed as a separate component be connected to the grate bar 2, for example by Soldering, welding, screwing or fixing by positive locking or the metallic The frame structure itself is part of the grate bar 2, by making the grate bar including the frame structure as a casting becomes.

Of course, the invention is not limited to the exemplary embodiments described limited. For example, only the head of the grate bar 2 be provided with the ceramic layer according to the invention. It can be variable Thicknesses, materials and shapes for different places on the grate bar be used, so that an optimal adaptation to the respective load he follows. Similarly, a manufacturing mix is locally different Requirements within the grate bar conceivable. The basic body to be coated can also be designed with closed surfaces, so that in If the layer of the grate bar flakes off, it will continue to operate for a while can remain and thus has good emergency running properties.

Reference list

1

Row of grate bars

2nd

Grate bar

3rd

ceramic layer

4th

metallic frame structure

5

ceramic element

6

Space

Claims (10)

High-temperature resistant grate bar (2) for a combustion furnace, in particular Incinerator, its surface facing the garbage bed at least partially consists of a ceramic layer (3), characterized in that the ceramic layer (3) from a variety ceramic elements (5), which in the spaces (6) grid-like metallic frame structure (4) are embedded. High-temperature-resistant grate bar (2) according to claim 1, characterized in that that the metallic frame structure (4) is due to the manufacturing process is part of the grate bar (2). High-temperature-resistant grate bar according to claim 1, characterized in that that the metallic frame structure (4) is a separate component, which is connected to the grate bar (2). High-temperature-resistant grate bar according to claim 1, characterized in that that the cross section aligned parallel to the grate bar surface the spaces (6) of the metallic frame structure (4) or of the ceramic elements (5) is polygonal and has a degree of stretching in Longitudinal direction of the grate bar (2) between 0.1 and 20, preferably 1 to 3, and has a depth relative to the transverse direction between 0.1 and 20, preferably 1 to 3. High-temperature-resistant grate bar according to claim 4, characterized in that that the spaces (6) or ceramic elements (5) one Have a honeycomb structure. High-temperature-resistant grate bar according to claim 1, characterized in that that the cross section aligned parallel to the grate bar surface the spaces (6) of the metallic frame structure (4) or the ceramic elements (5) is circular or elliptical and one Degree of elongation in the longitudinal direction of the grate bar (2) between 0.1 and 20, preferably 1 to 3, and has a depth relative to the transverse direction between 0.1 and 20, preferably 1 to 3. High temperature resistant grate bar according to one of claims 1, 4 or 6, characterized in that the spaces (6) of the metallic Frame structure (4) or the ceramic elements (5) perpendicular to Grate bar surface have variable cross-sections. High-temperature-resistant grate bar according to claim 1, characterized in that that the ceramic elements (5) from at least one component oxidic, carbidic or nitridic phases exist. High-temperature resistant grate bar according to claim 8, characterized in that that the ceramic elements (5) aluminum oxide, chromium oxide, Silicon carbide, silicon nitride, silicon dioxide or mixtures of these compounds contain and the material is hydraulically or chemically bound is. High-temperature resistant grate bar according to claim 8, characterized in that that the ceramic elements (5) made of fiber-reinforced material consist.

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