CZ159095A3 - Shaped brick for lining chambers of coke ovens and building process of such chambers - Google Patents

Abstract

A refractory shaped brick is disclosed for coke ovens having two vertical partitions held together in a traction resistant manner by transverse binders, forming an acute angle to each other, so that their mutual spacing varies over the whole partition length by the dimension v. The shaped brick is delimited by a lower surface (22) and by an upper surface (24) parallel thereto. Both surfaces (22, 24) are plane except for form-fitting grooves and projections. The shaped bricks are as thick as a partition and have both a plane lateral surface (18) on the coke side and a plane lateral surface (20) on the flue side. A binder area (14, 16) projects from the lateral surface (20) on the flue side. The binder area (16) has at least one projection (26) or one groove (32) on the upper surface (24) and on the lower surface (22). The projection (26) or groove (32) extends transversely to the longitudinal direction of the binder area (16), effects a form-fitting bond between stacked shaped bricks and is spaced apart from the free end of the binder area (16) by a distance which is clearly larger than the dimension v. The groove (32) or projection (26) extends in the direction of the binder over a width which is larger than v.

Description

Blocks for lining coke oven chambers

Field of the invention

The invention relates to a coke oven block, each having two vertical crossbars, the crossbars being rigidly connected to each other by transverse links, so that draft channels are formed therebetween, and are positioned at such a sharp angle to each other that the entire length of the wall varies by dimension v, the block being bounded by the bottom surface and the parallel upper surface, both surfaces being straight, except for the grooves and the protrusions for the positive connection.

BACKGROUND OF THE INVENTION

The coke ovens known from German patents 20 56 119 or 23 31 834 are composed of relatively small sized blocks. In order to be able to construct partitions running at very sharp angles to each other and transversally bound by ties, a large number of bricks of different sizes are required, whereby the individual bricks are engaged by the tongue groove together. This diversity of formats poses problems in the construction of new coke oven chambers and leads to high labor costs, but is particularly disadvantageous for repairs, since it is not possible to predict which individual bricks will need repair, so that all possible types of blocks must be maintained. . This leads to expensive inventory maintenance.

SUMMARY OF THE INVENTION

The object of the invention is to simplify the construction and, in particular, also to repair the coke oven chambers so that, while maintaining a positive connection, they can be assembled with as few block formats as possible and with as few individual blocks as possible.

The solution to this problem is based on a block of the kind described above, characterized in that the block has a cross-sectional thickness and has both a flat side surface on the coke side and a flat side surface on the draw channel side. wherein the binding portion has at least one protrusion or a protrusion on the upper surface and the lower surface. a groove that extends transversely to the longitudinal direction of the mating portion forms a positive fit when building blocks and has a distance from the free end of the mating portion that is noticeably larger than dimension (v), and that the groove or projection extends in the mating direction width that is greater than (v).

The basic idea of the invention is to utilize blocks which have both a wall forming part in contact with the coke and a binding part which forms a tensile transverse bond and separates the individual tensile channels in the longitudinal direction. The block according to the invention has a binding part which is dimensioned in length for the largest binding lengths possible. In order to assemble shorter bonds, the binding portion is shortened by cutting. This makes it possible to erect the vertical parts of the coke oven chambers from a small number of blocks. Apart from the special bricks for the upper part of the furnace, two different formats are sufficient for assembly.

The shortening of the mating portion of the block by cutting to form mats that are shorter than the longest mating results in the grooves and / or the mats. the protrusions arranged on the top side and the bottom side of the weave no longer have a constant distance from the opposite rung. The cutting is carried out either at the end of the coupling part, on which there are no protrusions or grooves, or by removing them, so that the grooves or the grooves can be removed. the protrusions, even for the shortest possible binding portion, still have a sufficient distance from the free end of the binding portion formed by cutting so that they can perform their function, i.e. to transmit tensile forces in the binding direction. In order to achieve a positive fit despite the bonds shortening from one end of the furnace to the other end, the groove and / or the protrusion are oversized. During enamelling, either the portion of the relatively wide groove that is not necessary for engagement is filled with mortar, or a too wide projection is shortened to fit the particular bond to be formed prior to assembly and enamelling. In this way, the block according to the invention is adapted to the actual geometric requirements by means of simple separating work carried out on site. This significantly reduces the stock level. In the case of new construction or repair work, a defective block can be replaced on site with just the necessary replacement block without having to be time-consuming and labor-intensive, as in the prior art.

According to the invention, each lower surface and each upper surface of the binding portion has at least one protrusion or a protrusion. the groove so that the protrusion and the groove are engaged with each other during the stacking. For example, if a single groove is provided on the upper side and a single protrusion on the lower side, they must be made wide enough to engage at all possible lengths of binding. If the projection transverse to the binding direction is narrow, this requirement may be met by a sufficient groove width in the corresponding direction. If a relatively wide protrusion is initially selected, it can be shortened by cutting or grinding so that it always engages in the groove.

Alternatively, a plurality of grooves or grooves may be provided. protrusions. These are distributed along the length of the binding portion so that at least one protrusion engages in one groove. The unnecessary protrusion is ground. In this way, it is possible to reduce the overall width of the grooves.

The invention also relates to a method of constructing coke oven chambers by means of the blocks according to the invention. In this method, the binding portions of the blocks are shortened so that any required binding length can be assembled. If appropriate, the protrusions are also shortened or partially cut off.

It has proven to be particularly advantageous to assemble the bonds exclusively from the binding portions of the blocks according to the invention (and not by means of ordinary bricks). The method according to the invention makes it possible to build coke oven chambers with very few joints. This reduces the time required for masonry on the one hand, but also reduces the number of weak points, which are typically formed by joints, on the other hand.

When selecting T-shaped blocks with two different lengths of the cross-bar T, the lateral boundaries, i.e. the crossbars, of the coke oven chambers, can be assembled from only two block formats, disregarding the special shapes at the top of the furnace. Cross joints are avoided due to the different lengths of the crossbeam T of both blocks.

Since the binding portions are longer than half the length of the longest binding that is considered, no cross joints are formed even in the binding region.

Further advantages of the invention are apparent from the other claims as well as from the following description and from the examples, which illustrate embodiments of the invention in more detail with reference numerals in the drawing. The examples are not to be construed as limiting.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is a perspective view of a wall of a coke oven chamber consisting of blocks of two different formats; FIG. 2 is a plan view of a first T-shaped block with a long crossbeam T according to the embodiment of FIG. T with short transverse beam T according to the embodiment according to FIG. 1, FIG. 4 vertical section through the coupling part in the embodiment according to FIG. 1, FIG. 5 shows a sectional view similar to FIG. 4 but for blocks with two protrusions on one Fig. 6 shows a representation corresponding to Fig. 4, but for blocks with two protrusions on one side and with two grooves on the other side, Fig. 7 shows a representation corresponding to Fig. 4, but for blocks with originally too wide a protrusion on one side and a groove on the other side, wherein the protrusion has been removed in the dashed part.

DETAILED DESCRIPTION OF THE INVENTION

The wall of the coke oven according to the exemplary embodiments shown in FIGS. 1 to 4 is made of prefabricates of two different shapes. Both shapes, namely the blocks 10, 12, it ^has a T-shape (when viewed from above), the block 10 has a longer traverse T than the block 12. The two blocks 10, 12 are also each link part 14 and 16, wherein in the indicated Example In the embodiment, the binding portion 14 of the block 10 is significantly shorter than half the length of the binding, and the binding portion 16 of the block 12 is significantly longer than half the length of the binding. The different lengths of the crossbeam T and the different lengths of the binding portions 14, 16 prevent the formation of cross joints, as shown in FIG. 1.

As shown in FIG. 1, the crossbars are formed by transverse beams T. Accordingly, the crossbars T have a wall thickness corresponding to the crossbar thickness. The crossbeams T of the blocks 10, 12 each have a flat side surface 18 on the coke side and a flat side wall 20 on the side of the draft channel. The side wall 20 is interrupted by a coupling portion 14, 16 projecting in the center thereof.

In addition, the blocks 10, 12 each have one flat lower surface 22 and one parallel top surface 24 which are at right angles to said side surfaces 18, 20. These surfaces 22, 24 are interrupted by grooves and protrusions which in the following they will be mentioned.

The protrusions 25 extend in the region of the crossbar T on the lower surfaces 22, and have a substantially semicircular cross-section. These protrusions 25 are also located on one end face of the crossbeam T, that is to say on the left side of FIG. 1 on the side facing the viewer and on the right side of FIG. 1 on the opposite side. In addition, the bottom surface 22 of the block 12 has a protrusion 26 in the binding portion 16 that extends transversely to the binding direction. In the following, it will be further described, since it is essential to the invention. Furthermore, protrusions 28 extend transversely to the protrusions 25 from the lower surfaces of the blocks 10 in the region of the crossbeams T, which extend transversely to the projections 25 and cross them, and have a distance from the front surface corresponding to a quarter of the beam length difference. The corresponding grooves 30 are formed on the upper surface of a block 10 with a longer transverse beam T at the same location. In the erection of one another, the protrusions 28 extend into the grooves 30 as shown in FIG. 1. Further, grooves 31, which also have a semicircular profile and act together with the aforementioned, are also provided on the upper surface 24 and the second face of each block 10, 12. Furthermore, a groove 32 having a relatively wide width in the direction of binding is formed on the upper surface 24 of the block 10 with the longitudinal transverse beam T. It works together with the protrusion 26, with which it will be particularly mentioned.

The two bond portions 14, 16 are formed together so long that, in blunt deposition, including the mortar gap, they give the greatest bond length between the bars. The shorter bonds are trimmed to shorten the binding portion 14 of the block 10 and / or the binding portion 16 of the block 12. In the embodiment of FIG. 3, the binding portion 16 is shortened, as indicated by the dotted line 34.

. If the spacing between the two rungs of FIG. 1 spans their entire length, for example, v = 85 mm, the longest occurring bond, when subtracted by several millimeters, is approximately the same dimension longer than the shortest occurring bond. Thus, in the illustrated embodiment, the binding portion 16 must be shortened by a corresponding length, for example 80 mm, so that the shortest possible binding can be assembled. The corresponding calculation applies to the width (measured in the binding direction) of the groove 32. Its total width is the sum of the reduced dimension v, i.e. in the example of about 80 mm, the width of the protrusion 26 and the width of two mortar joints. This results in a typical overall groove width of about 120 mm.

In the illustrated embodiment, the groove 32 begins at a distance from the free face of the binding portion 16, which is significantly longer than the v dimension. This ensures that the groove 32 remains intact while shortening the binding portion 16, Sufficient material to engage positively and to retain the protrusion 26.

Giant. 4 shows the situation between two blocks 12 at the shortest possible binding, the assignment of the block 12 at the longest possible binding is indicated by dashed lines. As shown in FIG. 4, the protrusion 26 is at a distance from the left end of the groove 32 that just corresponds to the mortar joint width. Similarly, for the longest possible bond, the protrusion 26 is so close to the right end of the groove 32 that there is room just on the mortar joint. At all binding lengths within these limits, the protrusion 26 is in a position that lies between the two extreme positions shown.

It is also possible to shorten the binding portion 16. To build bonds that are shorter than the longest binding, both binding portions 14, 16 can also be shortened, however, at a higher cost.

Giant. 5 illustrates an embodiment to eliminate the need for relatively wide grooves. Instead of one protrusion 26, two identical protrusions 26 are provided to which two grooves 32 are assigned. FIG. 5 shows the position of two blocks 12 in the case of a bond whose length lies exactly midway between the longest and the shortest bond. As can be seen from the figure, in this case the left protrusion 26 lies at the right end of the left joint 32, separated from it by the mortar joint, and similarly, the right protrusion 26, again separated by the mortar joint, near the left end of the right groove 32. with longer lengths than shown in FIG. 5, the right protrusion 26 is ground off. For constraints with shorter overall lengths, the left tab 26 is removed.

Also in the embodiment of FIG. 6, two protrusions 26 are provided, but they are assigned a single gap 32. Again, a case with a medium length coupling is shown. If a shorter mate than shown is to be assembled, the left protrusion 26 is removed. Similarly, the right protrusion 26 is removed when a longer mate than shown is to be built.

Giant. 7 finally illustrates the case where the original extended protrusion 26 is each adjusted to the desired binding length by cutting. The illustrated embodiment is the shortest possible bond. In this case, the right, dashed-out portion of the protrusion 26 is removed. The situation with the longest possible bond looks mirrored, only the left portion of the protrusion 26 is removed here. For all lengths within these limits, the protrusion 26 must be cut from both left and right.

The blocks 10, 12 are made of silicate, are hydraulically connected, are neutral and thus have virtually no thermal expansion.

Claims (12)

PATENTOVÉ 1. Refractory block for coke ovens, each having two vertical partitions, the partitions being rigidly connected to each other by transverse ties and standing at such an acute angle to each other that their spacing changes along the length of the wall by (v) wherein the block is bounded by a lower surface (22) and a parallel upper surface (24), the two surfaces (22,24) being straight, except for the grooves and the protrusion for the shape connection, characterized in that the block has a crossbar thickness and has both a side surface (18) on the coke side as well as a straight side surface (20) on the side of the draft channel that a coupling portion (14, 16) protrudes from the side surface (20) on the draft channel side that the coupling portion (16) a top surface (24) and a bottom surface (22) of at least one protrusion (26) or a top surface (24); a groove (32) that extends transversely to the longitudinal direction of the link portion (16) forms a positive fit when building blocks and has a distance from the free end of the link portion (16) that is noticeably larger than dimension (v), and the groove (32) or the protrusion (26) extends in a width direction greater than (v). A block according to claim 1, characterized in that the binding part (16) is longer than half the length of the longest binding, preferably it is at least 5 cm longer, so that the binding consists exclusively of the binding parts (14, 16) of the blocks. A block according to claim 1, characterized in that or 2 is T-shaped, wherein the pillar 6 forms the coupling part (14, 16) and the crossbeam T is inserted into the crossbar. A block according to claim 3, characterized in that one block is a transverse beam T and one block is a transverse beam T, provided with the same length of the column from n and c provided with T. longer short A block according to one of Claims 1 to 4, characterized in that the surfaces (22,24) of the coupling part (16) are each provided with one protrusion (26) and one groove (32), and that the groove (32) has in the binding direction, the width, which is given by the sum of the width of the protrusion (26), the dimension (v) and the two mortar thickness additions. A block according to one of Claims 1 to 4, characterized in that the surfaces (22, 24) of the coupling part (16) each have a plurality of protrusions (26) and a plurality of grooves (32) and their spatial arrangement or arrangement. the width is selected such that at least one protrusion (26) still extends into the groove (32) in the region of all possible binding lengths, leaving at least a width in the direction of the binding between the protrusions (26) and the groove (32) mortar joints. Block according to one of Claims 1 to 4, characterized in that the surfaces (22,24) of the coupling part (16) are each provided with one groove (32) and one protrusion (26), and that the protrusion (26) is in the binding direction, it extends over a width that corresponds to the smallest width of the protrusion (26) plus the dimension (v). A block according to one of the claims. 1 to 4, characterized in that it is provided with n grooves (32) and protrusions (26), and that the protrusions (26) and the grooves (32) are divided such that at least one part of the protrusion (26) engages at all lengths the possible bonds in the groove (32). Block block according to one of Claims 1 to 8, characterized in that it is made of a material with the lowest possible thermal expansion, preferably a silicate. A block according to one of claims 1 to 9, characterized in that it has a height of at least 25 cm, preferably at least 40 cm. Method for constructing a coke oven chamber by means of blocks according to one of Claims 1 to 10, characterized in that, in order to form a bond which is shorter than the longest possible bond, the bond portion (14 or 16) is shortened transversely to the longitudinal direction. a distance that is less than dimension (v) and increases to the shortest constraint. Method according to claim 11 for a block according to claims 7 to 10, characterized in that the protuberance is shortened depending on the use of the block to form the bond.