FI57660C - BAERANORDNING FOER ISOLERING FOER UGNSVAEGG - Google Patents

Description

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Patent and registration authorities AmBkan utlagd och utUkrlfUn public · ™! 30.05.80 (32) (33) (31) Requested «Tuoikwi — Begird prloritat 01.05.73 USA (US) 356263 (71) The Babcock & Wilcox Company, 16 East U2nd Street, New York, N.Y. 10017, USA (72) William S. Brady, Western Springs, Illinois, USA (7U) Leitzinger Oy (5U) Oven wall insulation support arrangement - Bäranordning för isolering för ugnsvägg

The invention relates to an oven wall insulation support arrangement comprising a flat body plate projecting spaced apart fastening members to which are mounted support plates parallel to the body plate supporting a plurality of parallel, oppositely compressed, fibrous thermal insulation strips formed between the insulating fiber layer. and enclosing the fastening members with their support rods.

Such an insulation support arrangement is known from Swedish Publication No. 380615. The side edges of these insulating elements have higher strips of insulating material extending to the sides of the base plate, which act to seal the ends of the adjacent elements. In order to adapt the wall elements to the dimensions of the furnace wall, it has been proposed to use additional pieces of insulating material of suitable strength between the wall elements, which are fixed in place with ceramic glue, stainless steel wire or by friction alone. There are considerable difficulties involved in fabricating such an insulating wall structure. First, 2,576,60 three types of thermal insulation strips with different dimensions are needed. Second, fitting the filling insulators to the joints between the insulating wall elements requires additional work. As a result of the thermal expansion of the furnace run plate, the distance between the fastening points of the insulating wall elements varies, whereby the furnace gases can seep into the insulating wall from the joints between the insulating wall elements.

The object of the invention is to provide a support arrangement of the type mentioned at the beginning, in which there are no such difficulties in fitting the joints of the heat-insulating strip bundles, but a uniform and tight insulating wall surface is provided on the inside of the oven, all insulating strips being held in place by fastening means.

This is achieved by a support arrangement according to the invention on the basis of the features set out in the appended claim 1.

The invention will now be described in more detail with reference to the accompanying drawing, in which Figure 1 shows a partial section of a wall structure of a furnace made in accordance with the present invention.

Figure 2 shows a top view, partly in section, of a part of the wall arrangement of the furnace according to Figure 1.

Figure 3 shows a larger view of a part of the wall arrangement of the furnace of Figure 1.

Figure 4 shows a section taken along line 4-4 of Figure 3.

It will be appreciated that although the invention is particularly applicable to structures for the inner linings of pit furnaces, the structure may be used not only to form a roof but also to vertical wall portions of the furnace, the walls being fixed or movable relative to the furnace, e.g.

In the illustrated embodiment, according to Figure 1, the corner of the furnace comprises a part of the furnace roof 10 and a part of one vertical side wall 11 surrounding the furnace interior 12. The furnace lining is made of fibrous strips 13 mounted side by side and pressed into panels 14 to cover the wall or exposed surface of the oven wall. Depending on the surface area and dimensions of the 3,57660 oven to be protected, the panels may be arranged end to end. Good practice requires metal parts of the panels that, as shown below, are positioned to allow adequate expansion of the metal under the operating conditions of the furnace. This distance between the panels will be about 12.7 mm, depending on the size of the individual panels.

Preferably, as described below, in connection with the structure, the panels 14 for each furnace are mounted separately from the furnace and, after installation, are attached to the walls or ceiling, if desired, either by welding or by bolting to the furnace body.

Each panel 14 has a planar body plate 15 of metal, usually steel, and the panels are provided with angled steels 16 at their sides and ends. Strips 13 of fibrous insulating material are fitted to the panel and are held in place by passing rods or twisted bolts 21, the fibers is pressed to fit a panel having a width of, for example, 0.9 to 1.2 m in the embodiment of Figure 1. In this particular case, all the walls of the furnace to be clad, for example the roof 10, are covered with a plurality of panels of this size. As shown, the body plate 15 is provided with stainless steel angle steels 20 having flange widths of about 38 and 75 mm. These angle steels are notched, as will be explained in more detail below, and as shown, each angle steel 20 is provided with threaded bolts 21 welded to the vertical flange of the angle steel at a point about 12 mm from the edge of the flange. The second flange 24 of the angle steel 20 is welded to the body plate 15 so that when installed the angle steels are about 150 mm apart. The length of the threaded bolts is 175 mm. It is preferred that eight strips 13 of fibrous insulating material about 25.4 mm thick are pressed with threaded bolts 21 between about 150 mm, each threaded bolt being provided with a washer 25 and nut 26 as shown in Figure 4, which presses eight strips of about 25.4 mm thick. strip in a space about 150 mm wide.

In particular, according to Figures 1 and 2, the bolts 21 are arranged on the vertical flanges 22 of the angle steels 20 at intervals of about 254 mm. As shown in Figure 4, each angle steel is notched at 30 to receive the washer 25 and nut 26 of the threaded bolt 21 from the adjacent angle steel 20.

4,57660 Thanks to this structure, a layer of fibrous insulation of approximately 75 mm covers the entire metal parts of the panel. It is obvious that the pressing of the second end part of the strips 13 will allow the outer part to expand, whereby the insulating material on the oven side of the panel will uniformly protect the metal parts of the panel.

Referring to Figure 3, it should be noted that the metal body of each panel 14 is provided with a structural support 33 at each end. In the embodiment shown, the supports 33 are U-steels. One of these flanges is welded or otherwise attached to the panel body, while the other flange is bolted to a wall-supporting steel structure (not shown). This type of structure is useful for either the furnace roof or side walls.

Although, as mentioned above, the width of the panel may be about 90 cm, it is natural that strips of fibrous material slightly longer than about 120 cm allow their ends to overlap at the edge of the panel.

It will be appreciated that other embodiments may be used to join and compress these strips of fibrous insulating material.

Thus, for example, all corner steels may be provided with stainless steel bars extending to their opposite sides. Under these conditions, the length of the bar will be less than the distance between the corner steels to allow the stepped bars to overlap and to hold the strips of fibrous material in place in the panel. In addition, the frame of each angle steel may be bolted to the frame plate instead of welding, if desired, to facilitate maintenance and replacement of panel parts. In such cases, it is not necessary to notch the vertical flange of the angle steels as shown in Fig. 4. Likewise, it is not necessary to use washers and nuts to hold the fibrous strips in a compressed state.

In the embodiment of the invention shown in the drawing, the compression of the strips is about 25%, i.e. the extent of the strips initially about 20 cm in the compressed state is compressed to about 15 cm. In some cases, and at the choice of the furnace designer, the compression of the fibrous strips may be greater or less than that mentioned above in s 57660. In the conventional type of insulation described, compression allows sufficient expansion in the interior of the insulating material to protect the metal parts of the panel from the heat in the furnace.

In the embodiment of Figure 1, the present invention is illustrated to apply to both the furnace ceiling and the vertical walls.

If a vertical wall or ceiling is intended to be moved, it is desirable to provide an insulation seal at the corners of the furnace. In the embodiment shown, this sealing is carried out by means of a two-layer strip HO of insulating material fixed in place relative to the vertical wall of the furnace, while two strips of protective layer H1 and H2 of double-layer insulating material that a small amount of wear can occur in this sealing and the sealing fit can be replaced more often than the panels on the furnace walls if necessary. However, the foaming of the panels and the usual maintenance costs have been found to be very low in furnace walls constructed as described above compared to solid, refractory ceiling and wall structures. This has only been possible when the fibrous insulation has not been immediately exposed to flame impacts and corrosive effects. This disadvantage of using a fibrous insulation material is well known and acknowledged.

Claims (3)

57660 A furnace wall insulation support arrangement comprising a flat body plate (15) projecting spaced apart fixing members (16, 20) to which are attached support plates (21) parallel to the body plate supporting a plurality of parallel, oppositely compressed, fibrous thermal insulation strips. (13) forming an insulating fibrous layer between the metal body plate (15) and the furnace interior (12) and enclosing the fastening members (16, 20) with their support rods (21), characterized in that the fastening members (16, 20) consist of angles , the bottom flange (24) of which is fixed against the body plate (15) and the second flange (22) is perpendicular to the bottom flange and the body plate (15) and extends between the thermal insulation strip bundles for a part of the thickness of the thermal insulation wall formed by them, the other ends of the support bars (21) attached to perpendicular flanges (22), the other ends extending from adjacent perpendicular flanges (22) n through the through-openings or notches (30), and that the distance between the perpendicular flanges (22) is less than the uncompressed wall thickness of the bundles of thermal insulation strips therebetween, the thermal insulation strips (13) being pressed between said perpendicular flanges (22) so that 22) the non-compressed parts extending over the ends cover the ends of the perpendicular flanges (22). Insulation support arrangement according to Claim 1, characterized in that the rods (21) are threaded and that the thermal insulation strips (13) of fibrous material are pressed by means of a washer (25) and a threaded nut (26) attached to the free end of the rod (21). Insulation support arrangement according to Claim 1 or 2, characterized in that the rods (21) extend from the perpendicular flanges (22) in opposite directions.