CS225397B1 - Wall construction of the industrial furnace - Google Patents

Description

The invention relates to an industrial furnace wall structure suitable for ceilings and doors, which consists of a steel frame with asbestos-cement sheath and lining.

Until now, steel parts of the frame construction have been used for the steel furnace construction, where the furnace shell is formed by a steel sheet connected to the frame by screwing or welding. The steel structure thus formed served as a supporting part for the lining of dense material or for high-temperature insulation of fibrous materials. This steel structure of the furnace had to be protected against corrosion outside and inside the whole area and at the same time it was necessary to solve the coating resistant to the effects of higher temperatures, especially around burners etc. In addition, the cladding was condensation of flue gases. names when using fiber insulations that have been degraded by condensate. In this case there was also a rapid corrosion of sheet metal. sheathing, as protective coatings are generally not resistant to the resulting sulfur and sulfuric acids.

In dryers, it is used for cladding of lightweight asbestos-cement boards in steel frame structures that are firmly connected to each other to form a furnace shell. As a rule, these are composite plates where a light core of mineral or other fibers is inserted between them. These composite boards have the advantage over homogeneous cellular boards that they have better thermal insulation and lower weight. These plates are generally fixed to the substrate or to each other with staples or nails, or screws or screws, which are pierced by the plate or inserted into the drilled holes.

Their disadvantage is that they are highly porous, hygroscopic and vapor-permeable. At low temperatures on the flue gas side there is a risk of condensation of sulfur compounds. The condensate then disrupts the cement binder. In this embodiment, asbestos-cement kiln cladding panels have not been proven useful, therefore, they are mostly used as non-flammable cladding for timber structures, or are used to form flue-gas casings. The use of asbestos-cement slabs for the cladding of industrial furnaces has hitherto prevented the use of a suitable method of attachment to the steel structure, and due to the different extensibility, the slabs were cracked. The attachment of the lining to the furnace casing hitherto used is another barrier to the use of asbestos-cement boards for the furnace cladding, since they do not have sufficient strength to absorb the forces needed to stabilize the lining.

Light insulating blocks for the construction of industrial furnaces are also used, which are designed as a self-supporting monoblock, where the steel part serves as a reinforcing element and not a supporting element. Hardened slabs must be firmly connected to each other, and the blocks then form a self-supporting wall.

The disadvantage of these blocks is that they cannot be used where it is necessary to install accessories on the wall of the furnace, since the strength of the housing does not allow this.

A further drawback is that the whole block is firmly connected by bolts and steel screws, so that they are destined for use at relatively low temperatures, especially in drying kilns, as well as the above-described asbestos-cement boards associated with the same disadvantages. In particular, the screw connection of the envelope on the face side is very unsuitable, since no hard plates that would be used for the fiber insulation envelope are strong enough in the heat to hold the block together. Likewise, the rigid connection of the outer and inner sides, which ensure the self-bearing of the wall, is broken due to the shrinkage of the insulating material at higher temperatures, and thus the self-bearing of the block is broken.

These disadvantages are substantially reduced by the construction of the wall of an industrial furnace, suitable for ceilings and doors, which consists of a steel frame with asbestos-cement sheath and lining. The principle of the invention is that the asbestos-cement plates and the frame of the steel structure are displaceable relative to each other, the asbestos-cement plates being part of a lining which is fixed to the frame of the steel structure.

The advantage of the construction of the wall of an industrial furnace according to the invention is that it can be used for all kinds of industrial furnaces, both for drying furnaces and for the most demanding heating and firing furnaces.

Asbestos cement boards do not have to be protected against corrosive effects from the inside and outside, so there is no need to apply protective coatings as the asbestos cement boards are resistant to the effects of the atmosphere.

Asbestos-cement boards are protected against the possible sulfur condensate from the flue gas by the temperature on the side adjacent to the furnace insulation, which is such that condensation of the sulfur compounds cannot occur.

When sulfur compounds are contained in the flue gas to a greater extent, hard asbestos-cement boards are generally used. Lightweight asbestos-cement boards must be protected against the ingress of flue gases with a metal foil on the inside. The emission coefficient of the external surface of the asbestos-cement board is high, so that at the same thickness of the high-temperature insulation, the surface temperature is substantially reduced, eliminating the need to apply excessively thick insulation layers to meet the hygienic requirements C.

Asbestos-cement boards have a lower weight than steel sheet and have poor thermal conductivity. In addition, they are cheaper than sheet metal and have lower energy consumption during production.

The machining and cutting of asbestos-cement boards can also be carried out with woodworking tools.

The disadvantage of asbestos-cement boards is that during their processing it is necessary to ensure good exhaustion and it is necessary to use protective equipment to prevent dust drift into the respiratory organs. However, the machining is limited to a minimum with the appropriate choice of design and manufacturing formats, so that the operation that produces the most dust drift, i.e., cutting, is reduced to the minimum possible.

Summarizing these advantages, it can be stated that the use of asbestos-cement kiln cladding boards reduces steel consumption, energy consumption, steel structure weight, lining weight, eliminates corrosive effects on kiln cladding, reduces paint consumption, eliminates flue gas condensation on the furnace shell, which is particularly important for high temperature fiber insulation.

Since the connection of the asbestos-cement boards to the frame of the steel structure permits relative displacement between them, stress cannot be generated due to the unequal thermal expansion of the frame. steel structures and asbestos-cement boards. At the same time, the steel structure remains as a supporting part for holding the furnace and lining accessories so that the asbestos-cement furnace shell is not stressed by the weight of these parts.

The asbestos-cement boards are inserted into guide rails which, for example, have an L, U or I shape in the profile, by which they are attached to the steel frame.

This embodiment is particularly advantageous where asbestos-cement slabs production formats are used without the need for further modifications with possible shortening or narrowing. Mutual displacement due to different extensibility is possible along the whole length and width of asbestos-cement boards.

Asbestos-cement boards are connected to the steel frame by L-shaped steel mandrels.

This arrangement is particularly advantageous where it is necessary to mount a differently shaped plate or where it is not possible to access the plates into the guide rails. Mutual displacement is made possible by free placement of the asbestos-cement slab between the slab, the head and the steel structure.

Asbestos-cement boards are attached to the steel frame by bolts with nut and washer.

This asbestos-cement fastening system is advantageously used for a honeycomb structure of steel construction and large wall dimensions where it would be structurally difficult to fix to rails or with L-shaped head mandrels.

However, it is possible to solve the structural arrangement of the plate mounting in combination, for example on the mounting surface of the asbestos-cement boards to the steel furnace structure by bolts with nut and washer, at the edges of the plates mounting into the guide rails. Likewise, when placing asbestos-cement boards in moldings from two or three sides, the L-shaped steel mandrels can be used to attach the free side to the furnace structure.

An embodiment of the wall construction of an industrial furnace according to the invention is shown in Figures 1 to 8.

Fig. 1 shows a longitudinal section through the furnace wall showing the arrangement of the lining, asbestos-cement boards and their attachment to the steel frame by means of screws.

Fig. 2 is an exterior view of the furnace wall.

Giant. 3 shows a detail of the asbestos-cement board attachment to the steel frame by a nut bolt and washer.

Giant. 4 shows the connection of the lining and the asbestos-cement boards by means of inserted steel mandrels.

Giant. 5 shows the attachment of asbestos-cement boards to the steel frame by means of L-shaped mandrels.

FIG. 6 is a cross-sectional view of how the asbestos-cement boards are fastened with L-shaped mandrels;

Fig. 7 shows guide rails mounted on a steel structure frame into which asbestos-cement boards are inserted.

Giant. 8 shows a furnace wall structure where an asbestos-cement plate is attached to a steel frame of an L-head mandrel. Anchoring of hard refractory insulation material is made by steel holder.

The wall 1 of the industrial furnace is assembled

Claims (4)

SUBJECT Industrial furnace wall structure suitable for ceilings and doors, consisting of a steel frame with asbestos-cement jacket and lining, characterized in that the asbestos-cement boards (3) and the steel frame (2) are displaceable relative to each other, the asbestos-cement plates (3) are part of a frame 2 of steel structure, the filling of which is formed by asbestos-cement plates 3. The asbestos-cement plates 3 and the frame 2 of the steel structure are displaceable relative to each other. Asbestos-cement boards 3 are part of the lining 4 which is fixed to the frame 2 of the steel structure. Several embodiments can be used to attach the asbestos-cement boards 3 to the frame 2 of the steel structure in order to ensure their connection to each other while allowing displacement between them. For example, the asbestos-cement boards 3 can be inserted into guide rails 5 which are L-shaped in profile and are fixed to the frame 2 of the steel structure. The asbestos-cement plates 3 can be connected to the frame 2 of the steel structure with L-shaped steel mandrels 6. Furthermore, the asbestos-cement boards 3 with the frame 2 of the steel structure can be connected by bolts 7 to the nut and to the washer 8. Asbestos-cement boards 3 are part of the lining 4. A layer can be used as the lining 4 9 refractory mineral fibers and layer. The inserted steel mandrels 11 have a shank 12 of thin refractory steel wire so that it can be bent after passing through the asbestos-cement plate 3. It is also possible to slide the steel washer 13 over the shaft 12 of the inserted steel mandrel 11 and bend the end of the shaft 12 over it. A suitable binder may also be used as the assembly material for the bonding of the individual layers. In this case, inset steel mandrels 11 are used in small numbers only as locking elements. Another example of using asbestos-cement plates 3 for cladding an industrial furnace wall 1 is by using a refractory lining 4 made of hard refractory material 14. The anchoring of the lining 4 made of this material on the steel frame 2 is provided by a holder 15 which is inserted into the spacer 16 secured by the nut 17, whereby the wall 1 of the industrial furnace is stabilized. BACKGROUND OF THE INVENTION a lining (4) that is attached to a frame (2J of steel structure). Industrial furnace wall structure according to Claim 1, characterized in that the asbestos-cement boards (3) are inserted into guide rails (5) which, for example, have an L, U or I shape in the profile by which they are attached to the frame (2). steel constructions. Industrial furnace wall structure according to Claim 1, characterized in that the asbestos-cement plates (3) are connected to the steel frame (2) by steel L-shaped mandrels (6). 4. Construction of walls of the industrial furnace according to claim 1, characterized in that azbestocemen 'World ^J plate (3) on the frame (2) The steel structure fixed by screws (7) with a nut (17) and washer (8).