DE1872893U - FIRE-RESISTANT STONE FOR CONSTRUCTION OF FIRE-RESISTANT LINING FOR VAVE, CEILING OR DGL. - Google Patents

Description

1U417H.3.63

General Refractories Company of Philadelphia 2, Pa. (IT.S.A.)

The present innovation "relates to refractory bricks, used for the construction of refractory linings, such as vaults, Ceilings, side walls or floors of metallurgical furnaces or rotary kiln linings, be used.

The purpose of firing is to create refractory bricks or formations with increased wedge taper · Another goal is the production of a refractory brick, the has a stronger wedge taper and thus a greater locking effect than usual standard stones in building structures same dimensions

! Furthermore, the innovation aims to extend the service life of Oven stones when used in ceilings and other cladding «- Applications to lengthen that splintered parts of the stones are held in the structure. Furthermore, the service life of furnace linings are increased by the fact that the stones in the structure are supported against one another in such a way that they are not displaced can be.

According to the innovation, through particularly solid mutual Interlocking of stones vaults, ceilings, side or end walls and floors of metallurgical furnaces can be erected, which have a greater stability and strength than the previously known constructions.

Another goal of the innovation is furnace linings to be formed with a smaller thickness than was possible when using stones with previously common shapes. Furthermore should according to the innovation also in flat walls or floors more metallurgical ovens a better mutual locking effect of the stones and in rotary ovens a firmer mutual support and Locking of the stones together than before can be effected.

It has been found that all of these objects can be achieved using refractory bricks of particular shape will. Accordingly, a stone according to the innovation is essentially characterized in that it has a plurality of in the longitudinal direction of the stone has staggered, converging radial surfaces.

Further features and details of the furnace are expected the following description in which, with reference to the drawings, several embodiments of the stones according to the innovation and vaults built from such stones are explained in more detail.

Pig. 1 is a cross-section through a vault of known type. Pig. Figure 2 is a cross-section through another known type of vault "whose outer radius of curvature is smaller than the outer one Radius of curvature of the vault shown in Fig. 1, Fig. 3 shows a known wedge stone previously used in such vaults in a view against a side surface of the stone and in Fig. 4 this stone is shown in a perspective view. 5 and 6 show a first embodiment of the stone according to the hiring in a front view or in a diagrammatic representation. Fig. 7 relates to another embodiment of the stone according to the innovation in a view against an end face. Fig. 8 shows a perspective representation of a parallelepiped solid block, in the outline of which a stone according to the furnace is drawn. 9 is a diagrammatic view of a section of an arched vault constructed from stones according to the innovation illustrated. FIG. 10 shows, in an exploded perspective illustration, a part of a stone according to FIG of the innovation built arch vault in view from below. Fig. 11 illustrates a stone according to the invention for use in flat ceilings or building parts in a view against the face of the stone, Fig. 12 shows this stone in plan.

looks again and Fig. 13 shows one made of stones after the Pig. 11 and 12 made Flaehdecke in view against the face of the stones. 14 illustrates in perspective View one according to! Ig. 6 trained stone, made with oxidizable metallic outer plates is provided. The firing is of course not the same as in the drawings illustrated embodiments limited.

When building linings of metallurgical furnaces Refractory bricks will largely use the doming principle applied · A vault is a structural structure that normally, but not necessarily, is curved and is made up of individual wedge-shaped stones or formations, whose contact surfaces or joints run at a right angle to the line of curvature of the vault. In metallurgical ovens or the like. This is what the vault construction is supposed to do above all Weight of the stones or bricks forming the vault are absorbed and this construction makes it a space-enclosing one Refractory lining formed, which is a work surface. It should be noted that 'in context with the innovation under the designation "vault" both curved and flat structures, e.g. Flat ceilings, should be understood.

According to the innovation, in the case of curved vaults, the load-bearing capacity of the vault for the vertical load without Decreasing the radius of the arch curvature can be increased and

In the lalle of IPlaehdeeken, the vertical forces are divided into a diagonal acting compressive force -converted, whereby a larger span can be provided. The innovation will In addition, a very strong mutual locking connection of the stones of the vault is achieved.

The stones according to the furnace can in particular also be used for linings of rotary kilns that are used for calcining of raw materials, for the production of cement clinker or for the implementation of similar roasting or sintering processes to serve. In ovens of this type, the radius of curvature of the lining is determined by the design of the outer jacket plates and can be, for example, about 5 m. The furnace diameters are in Lately it has been dimensioned larger and larger and, as can be easily understood, the larger the furnace diameter the previously known stones of the wedge angle have become smaller and smaller. Such a reduction in the wedge angle of the stones but in many cases results in a looser mutual clamping effect or support of the stones of the lining, so that as the furnace diameter increases, there are more frequent disruptions in operation due to stones falling out of the lining know to occur. When using stones according to the innovation, e.g. for a rotary kiln lining, the radius of curvature can now the lining, which is determined by the diameter of the furnace, can be kept constant by changing the wedge angle of the stones is enlarged accordingly. This results in a firmly supported lining, as required for trouble-free operation

is desired. When using the stones according to the innovation, rotary kilns with much larger diameters can be built than when using the previously known wedge stones, because with the stones according to the invention the wedge angle remains the same The radius of curvature of the lining can be greater than that of the previously known wedge stones.

For example, a certain vertical pressure recorded by a vault of a known type can, according to the innovation formed vault are included, the curvature of which ** dius is about twice as large as. the radius of curvature of the equally heavily loaded vault made of vaulted stones of a known type. It is desirable to increase the radius of curvature of a vault and thereby the superelevation of the vault ^ e Meter span of the same in order to build a metallurgical furnace or the like with less space requirements and that To be able to reduce the weight of the vault.

The more the wedge angle of the stones is enlarged in a vault construction, the greater it becomes due to the pressure of the vault in the normal to the wedge surface caused vertical component. Since this vertical component ^ ene force that holds the stones upwards, and since the force normal to the wedge surfaces is inclined force that is ultimately exerted on the support points or abutments of the vault, it is desirable in a given ceiling that the normal forces directed to the wedge surfaces are as low as possible

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hold because the total force to be absorbed by the abutments the lower it is, the more the normal is on the flat surfaces the stone approaches the vertical. As a result, after the rise in prices, a vault can not only have a weaker curvature than previously trained, but it can also be used by the Abutments on the ceiling required force are reduced because, as can be seen, in the normal The force acting on the wedge surfaces is much closer to the vertical direction than with the previously known wedge stones.

As part of the innovation, a stone shape is used to achieve the above results, which is a special one effective "locking and support of the stones results in one another. As a result of this interlocking, broken pieces of stones are also possibly in their position in the lining held so that the function of the refractory lining is retained as a work surface. In the previously known construction, the thickness of a ceiling had to be calculated from the outset that the operation can still be maintained undisturbed even if splintered pieces of stones fall out could. The ceilings therefore had to be made much thicker than with a continuous one-piece ceiling would be required. As a result of the innovation, as a result of the plague-like behavior caused by the downsizing, it becomes splintered Stone parts in the ceiling allows the thickness of the ceiling

to be "dimensioned smaller than before" and thereby save stone material, which of course also reduces the weight of the ceiling the supporting structure of the furnace or the rotary kiln have an effect, considerably reduced.

For a more detailed explanation of the innovation, first! "Ig. 1 in cross section a vault 20 constructed in a previously known manner, in which wedge stones 21 are arranged in abutment, These wedge stones have a wedge angle 22 and the vault has a radius of curvature 23 in relation to an axis 24 of curvature. A normal force 25 must be exerted on the ends of the vault in order to produce a vertical component 28 at the end faces 27, the size of which is equal to half the weight of the arch 20 is.

In Fig. 2, a vault 30 of a known type is shown, the same span as the one in Pig. 1 has vault 20 shown, but with the wedge angle 32 of the stones larger and the The radius of curvature 33 of the vault 30 is smaller than that of the vault According to FIG. 1. This has the consequence that the formal force exerted by the abutments or other supporting components 35 acts in a direction that is closer to the vertical direction than the direction of action of the normal force 25 in Fig. 1, so that the normal force 35 compared to the normal force 25 in 1 can be scaled down and still have a vertical component 38 of the size required to support the arch 30. It can be seen from this

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that in the vault constructions belonging to the prior art when the wedge angle of the stones is increased and the radius of curvature of the vault is reduced, it is inevitably a smaller one Force occurs at the bearings.

If the radius of curvature of a vault is reduced, however, the weight of the ceiling increases because it is used to bridge the gap the longer arches require more refractory material is · This can be clearly seen from Figures 1 and 2, in which the spans of the ceilings are the same. With the same span, the ceiling constructions used up to now The smaller the radius of curvature, the greater the weight of the ceiling is chosen.

A reduction in the radius of curvature of the vault also has the consequence that, with the height of the vault ends remaining the same, the interior of the furnace covered by this vault is higher in the middle of the vault than with a larger radius of curvature, which is undesirable in many lalls and results in a large space requirement for the oven.

As can be seen from FIGS. 1 and 2, when using the previously known stones at the desired magnification of the wedge angle of the stones necessarily the radius of curvature of the vault must be reduced accordingly, and this is however undesirable in most cases for the reasons given above. The present hiring now makes it possible to enlarge the wedge angle of the stones in the desired manner without

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having to reduce the radius of curvature of the vault.

The fig. 3 "and 4 show a wedge 40 that has been used so far known type, the an outer or cold surface 42 and a Mezu has parallel inner or hot surface 43 and end or end faces 44 and 44 ·, which are also parallel to one another are. The stone 40 also has two converging radial surfaces 45 and 46 which lie opposite one another in the longitudinal direction of the stone are arranged. The stone has a wedge angle 49.

The one in fig. 5 and 6 shown stone 50 according to FIG The innovation has two longitudinal sections 51 and 51 '»an outer or cold surface 52 and an inner or hot surface 53 parallel to it · The end surfaces 54- and 54 'are parallel to one another and lie at right angles to surfaces 52 and 53 Levels.

In the longitudinal section 51 of the stone 50 closes the surface 56 preferably an angle of 90 ° with the surface 53 and The surface 55 forms an obtuse angle with the surface 53. If, for example, the circumferential width of the surface 52 of the stone 50 according to The innovation is the same size as the width of the surface 42 of the known stone 40, and the circumferential width of the inner surface 53 in the longitudinal section 5I would be the same as the width of the inner surface 43 of the known stone 40, and if further the heights of stones 40 and 50 are the same, then would be the angle 58 (fig · 5) is equal to the wedge angle 49 in the known one Stone 40 (fig. 3).

In the part 51 'of the stone 50 according to the invention, which is offset in the longitudinal direction of the stone, the surface 56' expediently forms an angle of 90 ° with the surface 53 and the surface 55 'is inclined at an obtuse angle to the surface 53. The radius of curvature for this part 51 'of the stone 50 is a function of the width of the surface 52 _$ the width of the surface 53 iffl longitudinal section 51' and the height of the stone 50, The stone longitudinal section 51 'has a wedge angle 58' The radius of curvature and the wedge angle are equal to the corresponding radius of curvature and wedge angle of the section 51 of the stone 50, which is offset in the longitudinal direction of the stone, and also of the known stone 40. The stone 50 has transverse surfaces 57 between the sections 51 and 51 '

In the case of a vault 60 ', a section of which in FIG is shown, stones 60 are arranged in mutual side-to-side contact. The stones 60 are similar to those described above Stones 50, but with the longitudinal assign dislocation of sections 61 and 61 'the dislocation of the Stone edges not like with stone 50 on the inside of the vault, but formed on its outside. With the stone the side surfaces 65 "and 65 'are the converging surfaces, while surfaces 66 and 66 'are parallel. The surfaces 65 and 65 'enclose a wedge angle with one another that corresponds to the Angle 59 of the stone 50 according to the innovation corresponds. the Longitudinal sections 61 and 61 'of the stone 60 are of the same length, see above

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that the stones can interlock tightly. It can be seen that in this vault the radius of curvature can be the same as in a vault of a known type, its Stones have a wedge angle which is equal to the wedge angle 58 or 58 'of the stone 50. When the stone according to the innovation is however, the effective wedge angle is substantially greater than the wedge angle 49 in the case of stone 40 or the angle 58 or 58 · in the case of stone 50, because the surfaces of the stone that are effective in the transmission of forces from stone to stone are surfaces 65 and 65 'and these two surfaces enclose a wedge angle which corresponds to the angle 59 of the stone 50. The surfaces 65 and 65 ' accordingly form the load-bearing wedge surfaces of the stone 60.

The stone 50 shown in FIGS. 5 and 6 according to the haying therefore has a wedge angle $ 59 that is much larger than the wedge angle 49 of the known stone 40 according to FIG. 3, but with the same radius of curvature as in a vault vault constructed from stones near Fig. 3 can be retained.

In Fig. 7 is another embodiment of the stone according to the furnace shown. This stone 70 has in the longitudinal direction offset sections 71 and 71 '' two parallel outer surfaces 72 and 73 and the end face 74 and that of this face opposite end faces are also parallel to one another and are at right angles to the faces 72 and 73 · inclined Surfaces 75 and 76 intersect surfaces 72 and 73 lengthways

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cut 71 and other inclined surfaces 76 'and 75' the surfaces 72 and 73 in the longitudinal section 71 '. Transverse surfaces 77 connect the inclined surfaces 75 and 76 'or 76 and 75' together. The surfaces 75 and 76 close to one another Wedge angle 78 and the surfaces 75 'and 76' have a wedge angle 78 ' a. The surfaces 75 'and 75 form a wedge angle with one another 79 a. The stone 70 of FIG. 7 is similar to the stone 50 of FIG. 5 with the exception that that of the Areas 76 and 73 included angles are not a right but is an acute angle. It goes without saying, however, that the converging surfaces on the longitudinally offset sections of the stone are at an arbitrary angle to the outer longitudinal surfaces of the stone can be inclined and the stone shapes shown only as embodiments of the Innovation are to be understood.

Fig. 8 shows a parallelepiped block 110 in which a stone according to Fig. 5 is drawn in dashed lines " By removing the broken-line parts 111 and the block 110 results in the stone 50 shown in FIG. In the initial parallelepiped shape of the block 110, the length, width and height dimensions can be any Ratio to be chosen.

In Fig. 10, the insertion of the keystones is illustrated in a vault that is built from below when assembly from above is not desirable or impossible

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With this type of structure, all stones 50 can be brought into their position from below with the exception of two keystones. A stone separated into two parts 80 'and 80 "is inserted at the closing point. As can be seen from FIG. 10, the stone part 80 is first placed from below against a stone 50 completely the stones 50 is similar, ^f from the side in the horizontal clearing between the stone part 80 and inserted the countertransference ¹ lying stone 50, and then the stone part 80 is inserted "is also from the side in the horizontal calibration Tung and with the stones 80 ', 89 and 50 brought into contact to clamp it and close the vault.

Pig. 14 · illustrates a further embodiment of the innovation, in which oxidizable outer plates 100 ', for example made of steel, are arranged on the surfaces 53 "and 53' of the wedge of a 50. The stone also has matching bevels 101 and 101 '. The outer plates can preferably be connected to the Stone material and in this case expediently have tongues 102 _: which are embedded in the refractory stone material when the plates 100 'are pressed together. The oxidizable metallic plates reduce the risk of stone parts splintering and increase the durability of the stones When using such panels, a basic, refractory material that is compatible with the panel material should be used.

The use of the stones according to the innovation in flat ceilings is described in the IFig. 11, 12 and 13 illustrated. In this case, the stone 90 has longitudinally offset sections 9 ^ and 91 '. The side surfaces 95 and 96 are parallel to one another and therefore do not have any convergence. The side surfaces 95 'and 96' are also parallel to one another and therefore not convergent. The surfaces 92 and 93 are also parallel to one another and do not have any convergence. Thus, neither the section 9% nor the section 91 'has a wedge angle. Otherwise the stone 90 is designed similar to the stones according to FIGS. 5 "and 7. The surfaces 96 and 96 ', which form the load-bearing surfaces of the stone 90, however, converge and these two surfaces enclose a wedge angle 99 which enables the establishment of a 13 it can be seen that in the case of a vault 100 the forces F 1 and F p acting on the abutments are directed normal to the downwardly facing surfaces of the end stones of the vault 100 is transferred to the opposite surface of the same longitudinal section of the stone and acts as a force F ^, _{which is reduced by the weight of the end stone compared to the force F 1} *, on the next stone, which is arranged further inward Ceilings with a considerable span are erected.

The above statements relate to stones according to the inflation in connection with self-supporting vaults. It is

however, it must be stated most emphatically that the innovation in the same Way also "with only partially self-supporting or completely suspended vaults with hanging or other support or support devices is applicable. learner can use the stones according to the price increase also for the construction of walls, floors and others Linings of metallurgical furnaces, vessels or the like used will. For example, they can be used wherever refractory linings are used as work surfaces used or required.

The innovation is not limited to the described and illustrated embodiments and can with regard to
constructive details can still be modified in various ways.

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Claims (9)

Α, 1ίΗ1? * - 1.3.ί Protective sayings: 1. Fireproof Steia, characterized in that it has a A plurality of converging radial pools lying opposite one another and offset in the longitudinal direction of the stone having. 2. Refractory brick according to claim 1, characterized in that it apart from the opposite, in Eängs « Direction of the stone offset, converging radial surfaces still a plurality of in the longitudinal direction of the stone has offset, parallel surfaces. 3 · Refractory brick according to claim 1 or 2, characterized in that indicates that he has an outer peripheral surface, an inner Circumferential surface, opposite end faces, one first set of radial surfaces leading to a first axis of curvature converge towards, and a second set of radial surfaces running lengthways of the stone against the radial surfaces of the first set are offset and converge towards a second axis of curvature offset from the first axis of curvature, having. 4. Refractory brick according to one of claims 1 to 3 »characterized in that it has an outer surface, an inner Face, facing end faces, a first set of parallel faces that are in a first direction, and a second set of parallel faces extending longitudinally of the stone against the parallel faces of the first The set are offset and run in a second direction different from the first direction. 5. Refractory brick according to claim 3, characterized that the converging radial surfaces of the first set are opposite one another in the longitudinal direction of the stone and the converging radial surfaces of the second set are also opposite one another in the longitudinal direction of the stone. 6. Refractory brick according to claim 5 »characterized in that that of the radial surfaces of the first and second sets of ge a surface lies in a plane which at right angles to the outer and inner peripheral surfaces of the stone's planes. 7 * Refractory brick according to claim 5 or 6, characterized in that that one of the radial surfaces of the first set is parallel to one of the radial surfaces of the second set. 8. Refractory brick according to one of claims 1 to 7 » characterized in that it has mutually opposite peripheral surfaces, mutually opposite end surfaces, and has a plurality of sets of opposing wedge surfaces offset in the longitudinal direction of the stone » *. 18 - the opposing wedge surfaces of the different Sentences converge towards different cutting lines. 9. Refractory brick according to one of claims 1 to 8, characterized in that oxidizable metallic plates on the converging radial surfaces, which are bonded to the stone material are preferably also pressed, are arranged.