DE8516801U1 - Kiln with electric heating - Google Patents

Description

Karlheinz Munzert MZT 1/85 PGH

Falkenstrasse 1
8501 Schwanstetten

Kiln with electric heating

The present invention relates to a kiln according to the preamble of claim 1.

In the case of kilns of the type mentioned, there are those that contain mineral, particularly ceramic, fibers as thermal insulation. These are very effective because no masonry is required. In the case of walls made of ceramic fiber mats, these are held in place by special metal anchors. These are made of highly heat-resistant material because they must also be present in areas with very high temperatures. In addition, metal is a good heat conductor, so that the holding anchors reduce the efficiency of the kiln through heat conduction.

The object of the invention is to increase the efficiency of a kiln of the type mentioned and to use means which at least do not increase the heat storage capacity of the kiln.

This problem is solved by the features specified in the characterizing part of claim 1. This means that no expensive material is required for the

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Retaining anchors are necessary and since the heat conduction of ceramic is much worse than that of steel, heat dissipation to the outside is greatly reduced. This means that the combustion chamber can also maintain a higher temperature and this temperature can be reached more quickly under certain circumstances.

Further advantageous details of the invention are specified in the subclaims and described below based on the embodiments illustrated in the drawing. Show:

Fig. 1 a partial view of a kiln with inserted insulating supports from the front in section, Fig. 2 a view according to the section

A-B of Fig. 1, ■ Fig. 3 a corner connection according to the

Section C-D of Fig. 1 in enlarged scale,

Fig. 4 is a view of the heating coil arrangement of a kiln with insulating supports placed at the ends,
Fig. 5 a view according to the section

E-F of Fig. 4,

Fig. 6 is an enlarged view according to section G-H of Fig. 5 and Fig. 7 is a perspective view of a retaining anchor.

1 designates a part of an electrically heated kiln. This has a metal housing 2, e.g. made of sheet steel, with the side walls 3, the rear wall 4 and the cover wall 5. The heat-insulating walls 7, 8 and the heat-insulating cover 9 are preferably attached at a distance 6 from the metal housing 2. The distance is approximately 0.5 to 4 cm, in particular 2 cm, in order to avoid air circulation in this area as much as possible and thus to keep the heat emission to the metal housing 2 low. This saves energy and thus increases the efficiency of the kiln and also keeps the outside wall temperature of the metal housing 2 low.

The material used for the walls 7, 8 and the ceiling 9 is mineral fiber, especially for high temperatures ceramic fiber, especially in the form of ceramic fiber mats 10. The walls 7, 8 consist of horizontal, stacked ceramic fiber mats 10 and the ceiling 9 is formed by ceramic fiber mats 10 placed on edge.

For anchoring, i.e. for holding the walls 7, 8 and the ceiling 9, according to the invention, vertically or horizontally arranged rod-shaped supports 11 made of ceramic, which protrude through the walls 7, 8 and the ceiling 9 or at least into them, are held directly or indirectly in the metal housing 2. This fixes the ceramic fiber mats 10 in their position and there is no high heat conduction from the inside to the outside, since the ceramic supports 11 have poor thermal conductivity. The supports 11 can be used as

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Pipes or solid rods. In the former case, the heat capacity is even lower. In addition, the pipes can be stuffed with ceramic fiber wool.

According to an advantageous embodiment of the invention, the insulating supports 12 for the heating coil 13 are made of ceramic rods or tubes. Compared to the previously used channel stones in brick-lined kilns, into which the heating coil is inserted, a very significant reduction in the heat storage capacity of the kiln is achieved. This results in a shorter heating-up time and, in particular, less energy loss in the cooling phase, since there is not much residual energy stored after the kiln has been removed.

It is particularly useful to use the supports 11 at the same time as holders for the insulating supports 12. As the supports 11 are made of ceramic, their end section 14 (Fig. 5 and 6) can reach into the combustion chamber 15 if the ceramic mass used is sufficiently high temperature resistant. Otherwise, vertical ceramic columns 16 and ceramic corner columns 17 arranged in the combustion chamber 15 serve as supports. These are fixed at the top in the ceiling wall 5 and at the bottom in the floor 18 of the combustion chamber 15, which is made of refractory, in particular lightweight refractory bricks. Horizontal supports 11, e.g. ceramic rods, which can be inserted into the columns 16, 17, can also reach into the ceramic fiber mats 10 and serve to hold the corresponding wall 7, 8.

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In the ceramic columns 16, blind holes or through holes or, in the case of pipes, opposite holes 19 are provided in accordance with the distance to be maintained between the insulating supports 12. The insulating supports 12 can be inserted directly into these. To better compensate for thermal stresses due to expansion of the material and to make it easier to replace parts that require repair, ceramic pins 20 are inserted into the holes 19, which engage in the tubular insulating supports 12 or those provided with a corresponding hole. The distance between two ceramic columns 16 or 16 and 17 is expediently selected so that the insulating support 12 can be moved slightly in the longitudinal direction, so that it can possibly be removed from the other side after being moved to one side.

The bores or holes 19 of the ceramic corner columns 17 are arranged horizontally, alternating with each other, offset by 90°. This means that the insulation supports of the adjacent walls 3, 4 are offset in height from each other, but the ceramic pins 20 can be pushed all the way through the ceramic corner column 17. This ensures that they are better held.

In the embodiment shown in Fig. 4 to 6, the insulating supports 12 are placed on supports, as opposed to the version inserted into columns in Fig. 1 to 3. These supports 11 are inserted at the outside end 22 into guide bushings 21, which are attached to the metal housing 2.

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The guide bushings 21 are expediently welded to a support belt 23, e.g. an iron band about 5 to 10 cm wide and 2 to 8 mm thick. The support belt 23 is then welded or riveted or removably attached, e.g. screwed, to the inside or outside of the wall 3 of the metal housing 2. After the support belts 23 have been attached, the necessary holes are then drilled into the metal housing 2. The guide bushings 21 expediently protrude inwards into the ceramic fiber mats IQ.

In order to define the position of the supports 11 in the guide bushings 21, a ceramic sleeve 24 is applied to the end 22 of the supports 11, e.g. glued using a ceramic binder. The support 11 can then be inserted from the outside through the metal housing 2, which has a corresponding hole, up to the collar 25 formed by the ceramic sleeve 24.

To improve the fixation of the ceramic fiber mats 10 forming the wall 7 or 8, a retaining anchor, in particular a steel anchor 26 made of highly heat-resistant steel, can be attached to the guide bushings 21, e.g. by spot welding. This has claws 27 pointing upwards or, in particular, downwards. In the exemplary embodiment, as illustrated in Fig. 7, it consists of a U-shaped wire section 28, which has end pieces 29 bent perpendicular to the U-plane. The latter form the claws 27, which engage in the ceramic fiber mats to fix them in position.

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In this design, a vertical support 11 passing through the wall 7 or 8 is not absolutely necessary, which is why it is only indicated by dashed lines in Fig. 5.

In order to ensure a low heat transfer from the insulating supports 12 to the outside, the ends 30 of the supports rest on an end section 14 of a horizontal support 11. To fix the position, a hole 31 is provided at the top of the end section 14, into which a ceramic pin 20 can be inserted from above. In the area of the ends 30, the insulating supports 12 are provided with a continuous hole or, in the case of pipes, with an opening 32 on opposite sides, which are placed, for example, over the hole 31, after which the ceramic pin 20 is inserted.

In the case of horizontal supports 11 designed as a tube, which support the insulating supports 12, this also serves as a passage for the connection 33 of the heating coil. To avoid heat conduction via the enclosed air, the pipe passage of the tubular support 11 is preferably stuffed with ceramic fiber wool. This can also be done with a tubular support 11 that protrudes through the ceramic fiber wall 7, 8 or ceiling 9.

Advantageously, the walls 7, 8 and the ceiling 9 are provided with interlocking cutouts. For example, the ceramic fiber mats 10 forming the walls 7, 8 are cut narrower at the top to the height of the width of the ceramic fiber mats 10 forming the ceiling 9, so that an inner fold 34 is created. This

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serves as a support for the first layers of ceramic fiber mats 10 of the ceiling 9. This ensures the tightness of the combustion chamber 15.

Claims (1)

Karl-Heinz Munzert Falkenstrasse 1 MZT 1/85 PGH Schwanstetten Kiln with electric heating Expectations. 1. Kiln, consisting of a metal housing, a wall provided within the same with a ceiling, which consists at least partially of mineral or ceramic fiber material, in particular with electric heating with heating coils provided in the combustion chamber and held one above the other on insulating supports, characterized in that all walls or inner walls (7,8) and the ceiling (9) or inner side of the ceiling consist of ceramic fiber material and the walls (7,8) and optionally also the ceiling (9) are held by rod-shaped supports (11) made of ceramic, in that these at least partially penetrate the ceramic fiber material. 2. Kiln according to claim 1, characterized in that the supports (11) are designed as tubes. 3. Kiln according to claim 1 or 2, characterized in that the supports (11) are designed as rods . are fully gilded. 4. Kiln according to one of claims 1 to 3, characterized in that the insulating supports (12) of the heating coil (13) consist of ceramic tubes or rods. -2- -2- 5. Kiln according to one of claims 1 to 4, characterized in that at least some of the supports (11) simultaneously serve as holders for the insulating supports (12) of the heating coil (13). 6. Kiln according to one of claims 1 to 5, characterized in that the supports (11) penetrate the ceramic fiber material of the walls (7,8) vertically and/or horizontally. 7. Kiln according to one of claims 1 to 6, characterized in that the supports (11) penetrate the ceramic fiber material of the ceiling (9) horizontally. 8. Kiln according to one of claims 1 to 7, characterized in that the walls (7, 8) and the ceiling (9) consist of mats (10) of ceramic fiber material. 9. Kiln according to claim 8, characterized in that the walls (7, 8) consist of stacked ceramic fiber mats (10) and horizontal supports (11) are embedded therebetween, which are held in the metal housing (2) and/or in ceramic supports (16, 17) arranged in the combustion chamber (15). 10.Kiln according to one of claims 1 to 9, characterized in that the ceiling (9) consists of vertically arranged ceramic fiber mats (10) and the supports (11) pass through these horizontally. -3- 11. Kiln according to one of claims 1 to 10, characterized in that in the combustion chamber (15) near the wall (7,8) the ceramic rod-shaped insulating supports (12) of the heating coil (13) are held one above the other in bores (19) of vertical ceramic columns (16,17) and the ceramic columns (16,17) protrude at least through the ceiling (9) and are held directly or indirectly on one side in the ceiling of the metal housing (2) and on the other side in the floor (18) of the furnace chamber (15). 12. Kiln according to claim 11, characterized in that ceramic columns (16, 17) have continuous bores or bores or holes (19) on opposite sides, so that as a central column it can accommodate insulating supports (12) on both sides. 13. Kiln according to claim 11 or 12, characterized in that ceramic columns (17) with holes (19) arranged one above the other and alternately offset by 90° from one another are provided in the corners of the combustion chamber (15), and the holes (19) in one direction serve to hold the insulating supports (12) of one adjacent wall (7) and the holes (19) running in the other direction serve to hold the insulating supports (12) of the other wall (8), so that the insulating supports (12) of the walls (7, 8) forming the corner are offset from one another in height. -4- ■~&Lgr;- ■-:■-■ ..>■"> -&Agr;&Igr;&Agr;. Kiln according to one of claims 11 to 12, characterized in that a ceramic pin (20) can be inserted into each end of the insulating supports (12), which in turn is inserted into or through the associated holes (19) of the corresponding ceramic column (16) or ceramic corner column (17). 15. Kiln according to one of claims 1 to 10, characterized in that the supports (11) are held on one side in a metal guide bush (21) attached to the metal housing (1) and the supports (11) completely penetrate the ceramic fiber wall (7,8). 16. Kiln according to claim 15, characterized in that the supports (11) protrude with an end section (14) into the combustion chamber (15) and serve as supports for the insulating supports (12) of the heating coil (13). 17. Kiln according to claim 15 or 16, characterized in that the guide bushes (21) are fastened to a common support belt (23) corresponding to the grid of the heating coil (13) to be installed and the support belt (23) is fastened to the metal housing (2) in a removable manner if necessary. .18. Kiln according to claim 15 to 17, characterized in that the guide bushes (21) project inwards and into corresponding recesses in the ceramic fiber wall (7,8). -5- 19. Kiln according to one of claims 15 to 18, characterized in that the supports (11) have a collar (25) at the outer end (22). 20. Kiln according to claim 19, characterized in that the collar (25) consists of a ceramic sleeve (24) glued on with a ceramic binder. 21. Kiln according to one of claims 15 to 20, characterized in that a heat-resistant steel anchor (26) with upwardly and/or downwardly projecting claws (27) engaging in the ceramic fiber material is attached to the inwardly projecting guide bushes (21). 22. Kiln according to claim 21, characterized in that the steel anchors (26) consist of a U-shaped bent wire section (27), the ends of which have end pieces (29) bent perpendicular to the plane formed by the U and forming the claws (27), and a steel anchor (26) is attached to the base of the U on a guide bushing (21), in particular by spot welding. 23. Kiln according to one of claims 15 to 22, characterized in that the end sections (14) of the supports (11) are provided at the top with a hole (31) into which a ceramic pin (20) is inserted, which fixes the end (30) of an insulating support (12) in its position by means of a particularly through hole made in the latter or two opposite openings (32) in the case of the insulating support (12) designed as a tube. -6- 24. Kiln according to one of claims 1 to 23, characterized in that the supports (11) are designed as tubes and the connection (33) for at least one heating coil (13) is led through them. 25. Kiln according to one of claims 1 to 24, characterized in that tubular nozzles (11) and/or ceramic columns (11) projecting from the combustion chamber (15) to the outside are stuffed with ceramic fiber wool. 26. Kiln according to one of claims 1 to 25 , characterized in that a distance (6) of 0.5 to 4 cm, in particular 2 cm, is provided between the metal housing (2) and the walls (7, 8) and optionally also the ceiling (9). 27. Kiln according to one of claims 1 to 26, characterized in that the ceramic fiber mats (10) of the walls (7,8) are narrower at the top than the mats (10) located underneath to a height which corresponds to the width of the mats (10) forming the ceiling (9), so that an inner fold (34) is formed for the support of the ceiling mats (IQ).