DE2241164A1 - HIGH TEMPERATURE INSULATION CONSTRUCTION - Google Patents

Description

PATENT LAWYERS
DipUng. WERNER COHAUSZ · DipUng. W! LH ELM FLQRACK Dipl.-Ing. RUDOLF KNAUF

4 Düsseldorf, Sdiumanosfraße 97

The Carborundum Company

1625, Buffalo Avenue

Niagara Falls, NY l43o2

UNITED STATES. August 21, 1972

Highly qualified insulation construction

The invention relates to a high temperature insulating structure ^ in particular an arrangement for building and mm. Support of Yerbund walls, ceilings or panels, which form thermal insulation from selected insulation materials that are very high! Temperatures resistant up to a range of about 1575 Ms 165O ⁰ O and are suitable for direct action of the heat source ^ for example in the Form of components for Öfea, immersion pits, Yergütungsöfen, thermal expansion chambers and high temperature systems of this type. The invention relates in particular to practically applicable and effective means for combining structureless insulation or insulation of weak structure, for example bodies made of refractory fibers, and with high thermal tolerances with construction to form or support members such as steel or other suitable metal plates or sheets uswo ₈ to Verbundabsehnitte a constrained insulating and support or supporting structure, whereby complete units xirerden provided, as such for use as a ceiling, panels or panel parts for stoves and similar high temperature rooms as enumerated above are suitable.

Conventional Hocht he emp aturanlagen such as ovens, dip pits _s voltage = less units, Yergütungsöfen ¹ etc. are constructed with Vänden and / or ceiling of feuersten Steienen or blocks, for example, insulating firebricks, which are usually supported by metallic structures, or even carried by such, and which consist of substances which typically have density ranges of about 400 kg / nr

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for maximum exposure temperatures of about 875 ° C up to about 1040 kg / m for a maximum exposure temperature of about 165 ^ -0 C. Of paramount importance in the use of such conventional building means and materials are the high installation costs that exist from a relatively slow construction of the construction with bricks or similar block units using refractory mortar and the need to have this work carried out by experienced stone cutters. Furthermore, these masonry constructions are disregarded from the high construction costs and the great weight, naturally quite rigid, and therefore they tend to crack and break or bursting, etc. as a result of thermal expansion, they cause extensive action on the joints, and they are expensive to repair, apart from other pronounced disadvantages.

Working with dense refractory bodies such as bricks or blocks is often required in high temperature facilities where the refractory is exposed to abrasion or in contact with molten material Materials, for example molten glass or molten metals. However, many applications are indoors of furnaces in which only hot gases come into contact with the refractory lining, and in these cases are lining materials lower density and lower mechanical strength are useful, and they also have the advantages of lower weight and larger size Simplification in laying. The invention therefore exists in a construction process for the construction of a furnace lining system of this type and in particular in a fastening process for the attachment of linings on furnace walls and ceilings. In known constructions, the fastening devices sometimes fail prematurely because are not adequately protected against high temperatures. This leads to extensive repair downtimes for the furnaces. The invention therefore provides means for protecting the fastening devices for the insulation, which means are easy to install and maintain their effectiveness during long periods of time that the furnace is operated.

The invention consists in a high-temperature insulating construction for

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direct exposure to high temperature media, "consisting of a Support part, a body made of insulating material that extends over the support part is laid and which is connected to the support part by means of a number of spaced apart pins of metallic composition, which go through the body of the insulating material, with one end of the pin being attached to the support part, while the other is End extending through the body of the insulating material and protruding from the surface of the body, the pin having a shoulder assembly for holding the body of the insulating material, and a fire retardant protective element around the shoulder assembly and the end of the pen around for protection during exposure to high Temperatures is set.

The invention is below and hand of embodiments below Referring to the drawings explained in more detail. In the drawings are:

1 shows a section through part of a furnace wall with a lining, in which a method for fastening the liner is shown is,

Figure 2 is an end view of the mounting nut, one washer and one fireproof protective element,

Fig. 3 is a section similar to the section shown in Fig. 1, in which another type of fastening protection element is shown «,

Fig. 4 is a view of the contact surface of the refractory protective element from Fig. 3,

Fig. 5 is a section similar to the section shown in Fig. 1, in which a second variant of the fastening element for the lining is shown

Fig. 6 is a representation of the .Sheiben fastener as it is in Fig. 5 is used, and

7 shows a representation of a third variant of the fastening pin for the lining.

A t _e il a furnace wall with an insulating lining and

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a fastening element for the lining is shown in FIG. The furnace shell 10 is provided with a pin 12 which is welded or otherwise attached thereto. The pen is inside of the furnace and is long enough to go through the layer of insulating lining 20, 22 and to attach the appropriate Allow fasteners. The end of the pin is threaded to mate with the threads of a fastening nut 16. This retaining nut is pulled against a large washer 18. The pin 12, the fastening nut 16 and the washer 18 can Be made of carbon or alloy steel, depending on the temperature level at which the furnace is operated. Special steel alloys are more resistant to high temperatures, but are also more expensive. Even the toughest alloys tend to however, they tend to age after prolonged use. If they fail, you lose the lining supports it and loosens. Hot furnace gases can then penetrate the furnace shell, reducing the effectiveness of the furnace and a weakening of the jacket. The effects are even worse if the lining on the furnace roof fails, there much of the heat is concentrated in this area. Means for protecting the hot end of the pen 12 are very desirable, and they are created by the fireproof protective element 24. It has a cup-shaped shape, and it can be made by pressing or vacuum casting a fabric selected from suitable refractory fibers such as aluminum silicate with suitable binders and that the resulting shape is fired to form a strong protective refractory element 24. A hole becomes placed in the center of the refractory protective element 24, which enables it to be slipped onto the pin 12, followed by the metal disc 18 and the fastening nut 16. The fireproof protective element 24 has sufficient strength to withstand the compressive force of the fastening nut 16 to be transferred to the lining parts 20 and 22 and ensure their firm support. For reasons of illustration, the lining shown in FIG. 1 consists of a layer of mineral wool 20, which is covered by a layer of aluminum silicate fibers. The fastenings for the lining, however, are not limited to this spe-

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The specific fiber type is limited, but can be used in YerMn & ung with any type of heat resistant fiber material can be used, either in the form of felts or blankets or in more rigid constructions such as insulating plates, panels or blocks.

An end view of the refractory guard 24, washer 18, and fastening nut 16 is shown in FIG. After this connection has been made and the fastening nut has been properly tightened, the refractory protective cap is filled with a refractory mixture 28 sufficient to completely fill the cap and cover the washer 18, the fastening nut 16 and the end of the pin 12. If the stick protrudes too far, it will be cut off before the refractory mixture is applied. Any suitable castable refractory material can be used provided its coefficient of thermal expansion is such that it does not cause breakage of the protective element 24 when the joint is brought to furnace temperature. Since these temperatures are in the range of 1375 t> is 165O ⁰ G, the refractory protective beaker and the pourable refractory mixture must be stable up to the upper limit of this temperature range.

Another embodiment for protecting the pin fastener is shown in FIG. A cap 30 is provided which is cast or otherwise shaped from a suitable refractory material. The material can consist of fibers such as aluminum silicate or similar heat-resistant fibers or threads and suitable fillers and / or binders. A fastening nut 3 ² is molded into the cap 30 or otherwise fastened therein. This can either be a threaded nut or a similar wall element that is suitable for a fixed connection within the cap 30. The thread of the nut or the element interacts with the thread I4 on the pin 12. The cap 30 includes an internal cavity 34 »to accommodate. to create the end of the pin 12 when the cap 30 is against the _; Isolation body 22 is pulled. A protruding bead 36 is on the outer periphery of the

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Cap 30 is formed and it acts as a sealing aid. The inside the cap 30 is in Pig. 4 shown. It shows the hexagonal shape that the periphery of the cap has to prevent the plague facilitate. This type of fastening device has the advantage of quick assembly with the elimination of the step of sighting a pourable refractory mixture to fill in the refractory protective element and to cover the fastening nut and the washer. Assembly is made easier, especially when working in confined spaces or on the ceilings of ovens where working with castable Mixing is difficult.

A variant of the fastening pin is in Pig. 5 has shown * the pin is not threaded, rather one or more radial slots 42 are cut near its outer end. The mounting disk 44 has a central keyhole opening 46 (Fig. 6), the allows the washer 44 to be slipped over the end of the pin 12 and snapped into one of the radial slots 42 to thereby achieve the refractory protective element 24 and the lining insulation 20 and to hold in the intended position. The protruding end of the post 12 is then cut off, and the exposed end of the post and the pane 44 are covered by a second refractory protective element. Both fireproof protective elements 24 and 48 consist of the same type of refractory material, the protective element 40 being a is shaped such that it becomes an interference fit when it is inserted into the inner periphery of the refractory protective element 24.

In Pig. 7 shows a variant in the pin construction. Included the pin has several holes 52 drilled near the end or are brought in in some other way. The fireproof protective element 24 and the washers 44 are assembled as shown in FIG. 5, and they are held in place against the furnace liner by inserting a cotter pin 54 into one of the pin holes. The protruding end of the pin 12 is then cut off and the second refractory protective element 48 is attached, as shown in Pig. is shown.

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The fastening method as provided according to the invention, ensure that the metal parts of the fastening system are protected high oven temperatures to reduce the life of the fasteners to extend and allow the furnace to operate for a long time. The fireproof protective elements used increase the supporting surface from each pen so fewer pens are needed. Oven heat losses are reduced because there is less heat exchange through the metal pins are made through to the furnace walls. In many cases the fire-resistant protective elements according to the invention enable the use of cheaper fastening materials, thus reducing costs of furnace construction and maintenance costs during operation.

Patent claims

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Claims (12)

Claims 1./ High temperature insulation construction for the direct action of High-temperature media, characterized by a support part (10), a body (20,22) made of insulating material, which over the support part (10) is laid, the body (20,22) made of insulating material with the support part (10) by a number of spaced apart pins (12) made of a metallic material, which go through the body (20,22) made of insulating material and which have one end on the support part (10) are attached and extend at the other end through the body (20,22) of insulating material and from its surface protrude and have the shoulder means (14,42,52) for holding the body (20,22) made of insulating material, and a fire-resistant protective element (28,50,48) wrapped around the shoulder means (14,42,52) and the pin end for protection during exposure to high temperatures is. 2. High-temperature insulating construction according to claim 1, characterized in that that the shoulder means are formed by a metallic washer (18) and a fastening nut (16) which are matingly threaded (14) engages the other end of the pin (12) with a refractory protective element (24 »28) around the shoulder means for protection during exposure lying around in high temperatures. J. High-temperature insulating construction according to claim 1, characterized in that that the Schultenuittel through a ceramic cap (30) with a metallic threaded insert (32) firmly connected to it are formed, which is in engagement with mating thread (I4) that is at the other end of the Pin (12) is provided in such a way that the Schu * ltermittel through the Ceramic cap (30) are protected. 4. High-temperature insulating construction according to claim 1, characterized in that that the shoulder means are formed by a metallic disc (44) which has a smock opening (46) and which is in counter grooves (42) engages, which are provided at the other end of the pin (12), 26 294 Wa / Ti - 2 - 309809/0780 a fireproof protective element (24,48) around the shoulder means for Protection is lying around during exposure to high temperatures. . 5. High-temperature insulating construction according to claim 2, characterized in that that the refractory protective element (24,28) has a cup-shaped refractory element (24) which has such a shape that it fits on the pin (12) under the shoulder means and partially encloses the shoulder means. 6. The high-temperature insulating construction according to claim 2, characterized in that the refractory protective element is filled (28 _24?) With a castable refractory material (28) of the shoulder means completely "covers and protects. 7. High-temperature insulating structure according to claim 2, characterized in that the. Fire-resistant protective element is formed from a mixture is made of aluminum silicate fibers » 8. High-temperature insulating structure according to claim 3 «, characterized in that that the ceramic cap (30) is formed from a castable refractory material. 9 · High-temperature insulating construction according to claim 3 _S characterized in that the pourable refractory material is formed from a mixture containing aluminum silicate fibers. 10. High-temperature insulating structure according to claim 4s, characterized in that the fireproof protective element (24 _S 448) has a cup-shaped fireproof element (24) which is designed to fit on the pin (12) under the shoulder means (44,42) and which has a flange edge with which a second refractory disc (48) can be brought into a force = connection, which covers the shoulder means (44, 42) for protection during the action of high temperatures, 11 .. high-temperature insulating construction according to claim 4s thereby gekerm- 309809/0280. ~ ³ " shows that the other end of the pin (12) has at least one radial Hole (52) made in this end and that the .'Jtift (12) in conjunction with a split pin (54) »which is inserted into the hole (52) is) for holding the metallic disc (44) and the refractory Protective element (24, 48) in the intended position on the shoulder means cares. 12. High-temperature insulating structure according to claim 10, characterized in that that both refractory elements (24,43) are formed from a mixture which contains aluminum silicate fibers. 309809/0? 80