CS224500B1 - Furnace lining,particularly for furnace roofs and doors - Google Patents

Description

The invention relates to furnace linings, in particular for furnace ceilings and doors.

Until now, refractory materials, ramming plastics, hard and lightweight materials have been used as linings.

The disadvantages of these materials are that they have a high weight, large thermal accumulation and are highly thermal conductive.

Suspended ceilings made of lightweight insulating materials were created by a series of slabs joined together by sealant.

The disadvantage of these arrangements was that the dependent elements had to be inserted into each row of plates and had to be made of heat-resistant chrome-nickel material because they were exposed to relatively high temperatures. The dilatation of the boards was so that at certain distances the rows were not cemented and the joints thus formed were covered with insulating material, which was imperfect and was a source of heat leakage.

If the sealant layer on the sides of the plates has been broken, heat has also penetrated from the working area to the striking space.

Recently, the same fibrous insulating material has been used, but its use is limited as it can only be used up to 1100 ° C.

These drawbacks are substantially reduced by furnace lining suitable for furnace ceilings and doors, which consists of blocks consisting of beams formed by gluing panels of cellular wood.

224 500

224900 insulating material. The essence of the invention is that the plates in the shape of an inverted letter 3! They are arranged in subbeams, which can be stacked in such a way that between each of the two supporting beams, provided they are provided with dependent elements, there is an interposed beam formed of I-shaped plates, whereas the plates and inverted T-plates are offset at least by one eighth of its thickness, the inverted T-plates being made of a lightweight insulating material that has an outgoing bulk density and strength than the T-plate material.

The furnace lining according to the invention eliminates the disadvantages of lining from hard refractory materials 1 disadvantages of fibrous materials and combines their advantages, low weight and can be used for operating conditions up to 1400 ° C, ie for all types of heat treatment furnaces 1 for heating furnaces .

I. Insufficient lateral bonding of the load-bearing beams and intermediate beams does not result in heat leakage, as this is prevented by offset plates.

A further advantage is that damping is achieved, that the dependent elements do not have to be made of alloyed materials, but carbon steel of usual quality can be used.

An example of an embodiment of a furnace ceiling with a lining according to the invention is shown in Figures 1 to 6.

In Fig. 1, the inverted flame plate T is provided with a recess and an opening.

Fig. 2 shows a T-shaped plate.

FIG. 3 shows an inverted flame plate T in vertical section, from which it can be seen that the offset is arranged over the entire surface of the plate.

Figures 4 and 5 show a side view of an offset which is provided by opposing protrusions and grooves.

Figure 6 is a cross-sectional view of a block made up of support beams and intermediate beams.

No Fig. 7 is a sectional view of a suspended rod of a suspended ceiling.

Fig. 8 is a plan view of an atrop composed of blocks.

The furnace lining, made of a lightweight insulating material suitable for the ceiling, is composed of blocks 6. The block X is formed of supporting beams X formed by inverted T-shaped plates X, which are glued together with mastic £. An intermediate beam X is formed between each of the two beams χ, which is formed by gluing the T-shaped plates 6 together.

The inverted T-shaped plates X and the plates 6 are offset by at least one-eighth and a-l of the thickness when stacked into the support beams X and the intermediate beams χ. A block 1 is formed by supporting beams χ and intermediate beams X, which are connected by the sealant £.

Along the length of the support beam X, an opening 8 is provided in the narrow upper part X of the inverted T-shaped plates X in which the support rod 8 is received. By means of the support rod 8 and the hinge element XX, which is arranged in the recesses XX arranged in the support beam χ, the block X is rolled onto the steel structure 12 of a furnace not shown.

The inverted flame-shaped plates χ are made of a lightweight insulating material having poured bulk density e strength than the breed-shaped plates T *.

The offset for the inverted breed plates χ and the T-shaped plates 6 can be arranged over the entire surface. It is also possible to carry out the offset by opposing protrusions, i. and the grooves 14 provided with the side walls of the inverted T-shaped plates 2 and the T-shaped plates 6. The protrusions 13 and the grooves 14 may, for example, be angular or rounded.

For large ceilings and doors, the lining consists of two or more U joints! on the faces of the carrier beams g. ^e £ interleaved beams ^is performed by sticking spacers JJ, and semi-plates of ceramic fibers.

In the same way, i.e. by gluing the dilatation inserts 15 between the support beams 2 and the inserted beam 6, the connection on the sides of the blocks 2 is also made.

This ensures longitudinal and transverse dilatation of large ceilings, doors and other parts.

Expansion may also be accomplished by settling dry instead of gluing the expansion inserts 15.

Claims (1)

Furnace linings, in particular for ceilings and oven doors; consisting of blocks consisting of beams formed by gluing sheets of expanded insulating material, characterized in that the inverted T-shaped plates (3) are arranged in supporting beams (2) disposed in the block (1), that between each of the two support beams (2) provided with the suspension elements (10) there is an intermediate beam (5) consisting of T-shaped plates (6), which plate (6) and inverted plate (3) The T-plates are offset by at least one eighth of their thickness, the inverted T-plates (3) being made of a lightweight insulating material having a higher bulk density and strength than the T-plate (6) material.