DE9012119U1 - Mantle stone for multi-layer house chimneys - Google Patents

Abstract

The invention relates to a mantle block for a multiple-casing, ventilated house-chimney, having at least one round inner pipe conducting the flue gas, a cylindrical shell-shaped insulating layer surrounding the inner pipe, and a mantle block of rectangular outer periphery, which supports said insulating layer on the outside and in the corner regions of which there is arranged in each case one flow channel (4), running from the bottom upwards, for a ventilation gas led in from outside and led away to the outside. According to the invention, in at least two corner regions of the mantle block (2) there are arranged in each case one additional cutout (6), extending parallel to the axis of the chimney, for receiving reinforcing bars and/or sealing compound, the wall (8) of which cutout runs, in the direction of the flow channel, substantially concentrically or parallel to the corresponding part of the inner wall (10) of the cutout (6), the wall thickness amounting to 40% to 60% of the minimum wall thickness of the mantle block. <IMAGE>

Description

Note: Werner Münz Neufahrn, 21.8.90

Mantle stone for multi-layer house chimneys

The invention relates to a casing stone for a multi-layered house chimney according to the preamble of claim 1.

Such casing bricks for multi-layer chimneys are known (see e.g. DE-PS 3211536). It is also known to incorporate recesses for reinforcing iron and/or casting compound in such casing bricks (see DE-OS 3436536). However, the solution proposed here has the disadvantage that the flow channels arranged on both sides of the corner areas have a very unfavorable cross-section in terms of flow technology, since they are elongated and narrow at the same time. In addition, the mold for producing the casing bricks is complex due to the uneven shape and the large number of flow channels.

The invention is based on the object of designing a casing stone for multi-layer chimneys in such a way that an optimal effect of the flow channels is achieved at minimal cost and at the same time recesses for reinforcing iron and/or casting compound can be formed.

This object is achieved in a generic multi-layer chimney by the features specified in the characterizing part of claim 1.

By concentrating on just one ventilation shaft in each corner area in conjunction with a concentric design of the wall of the recess in the direction of the air shaft with a limited wall thickness in this area, a largely compact air shaft is achieved that has a relatively large cross-sectional area and at the same time a small peripheral area. The hydraulic diameter, which is important for the flow resistance as a ratio of cross-sectional area and peripheral area (Dh = 4*F/U), is therefore large. It results in small flow resistances. This is of considerable importance for ventilated chimneys, since the only driving force available for the flow is usually the buoyancy force resulting from the -small- temperature difference between the shaft and the environment. In contrast, in the solution specified in DE-OS 3436536, the actual corner area is used to support the insulation layer, which means that a considerable part of the cross-sectional area that can be used in the corner area is lost for the flow channel. In order to compensate for this at least partially, firstly two channels must be arranged in each corner area and secondly the channels must be extended very far towards the middle area of the casing stone. Due to the small depth of the channel cross-section towards the middle, the span at which the insulation layer is interrupted increases very quickly, while the cross-sectional area only increases slightly. In contrast, the casing stone according to the invention with only one flow channel in each corner area achieves a larger overall span with the same span.

cross-sectional area of the flow channels with a more favourable cross-sectional shape and a larger contact surface for the insulation layer.

The casing stone according to the invention offers the possibility of using different shapes of recesses, whereby in order not to waste unnecessary space for the flow channels, the size of the recesses is chosen to be as small as necessary for the intended purpose; usual dimensions here are in the range of 25 mm to 60 mm. They are therefore somewhat smaller than the wall thickness of usual casing stones, which is between 40 mm and 100 mm.

Limiting the wall thickness of the recess in the intended area ensures that the strength properties and the fire resistance duration of the casing blocks are not adversely affected by the recess. This applies in particular if the sum of the individual wall thicknesses is greater than or equal to 100* of the wall thickness in the adjacent areas, which can be achieved with minimal space requirements if the wall thickness on all sides is 50% of the wall thickness in the adjacent areas. However, it can also be useful to choose a wall thickness on the outside that is greater than 50% and on the side facing the flow channel that is correspondingly less than 50%. In particular, if the recesses are already cast in the manufacturing plant, e.g. when assembling several casing blocks, it can also be sufficient to form both walls with only 40% of the wall thickness in the adjacent areas, since in this case the casting compound increases the strength of the corner area.

In order to use the space in the corner area of the casing stone so that the largest possible cross-sectional area is achieved for the recess, triangular, square or oval cross-sections can be selected for the shape of the recess. Creating circular recesses is particularly easy in terms of shape, and it also has the advantage that reinforcing iron can be fixed at the same distance from the casing stone on all sides. The center of the recess is conveniently positioned on the bisector of the corner of the casing stone.

In order to achieve the best possible design of the cross-sectional area of the flow channel, as well as for manufacturing reasons, it is advantageous to round off the corner areas of the flow channel that arise between different walls, whereby the rounding may only have a small radius so that the resulting loss of cross-sectional area is acceptable. A rounding with a radius of 5 mm is particularly advantageous here.

To compensate for the area taken away from the flow channel by the recess, it is advantageous to arrange the lateral boundary surface of the flow channel essentially at an angle of 80° to 100° to the adjacent wall section, preferably perpendicular to it. In the previously common generic casing stones, the lateral boundaries were arranged parallel to the bisector of the corner, which only partially uses the available space when the opening of the flow channel is limited in width.

&mdash;&ogr;&mdash;

The insulation layer is well supported on the casing stone if the open opening to the insulation layer formed by the flow channel is smaller than or at most equal to the adjacent area of the casing stone that supports the insulation layer. If flow channels are only arranged in corner areas, as is preferably the case, the supporting area is always at least 50% of the total circumferential area. In this case, dimensionally stable shells do not necessarily have to be used for the insulation layer; pre-formed, profiled panels can also be used, which are only bent into a circular or semi-circular shape at the installation site. Even if two insulation panels are used per circumference, the supporting area is still reliably sufficient to hold both panels securely on a supporting surface.

For reasons of strength and fire safety, it is advisable to choose the minimum wall thickness in the area of the flow channel and in the rounded supporting part of the casing stone to be the same. However, particularly with small chimney clearances in the range of 12 cm to 16 cm, it can be advantageous to choose a slightly larger wall thickness in the area of the rounded wall part than in the area of the flow channel in order to increase the area for the flow channel given the unfavourable geometric conditions here. In general, it is sufficient to increase the wall thickness by 5 mm in order to obtain a sufficiently large air shaft cross-section, although an increase of 10 mm can usually still be accepted for reasons of space.

If the wall thickness of the straight wall section is continued over a limited height of the casing stone over the area of the rounded wall section as a straight wall surface, a horizontal flow channel is obtained that runs between the flow channels, through which air can be transported from one flow channel to the next flow channel, or diffused water vapor from the middle area of the casing stone to the flow channels. For the second task, a similar horizontal channel can also be formed in a casing stone in which the wall thickness in the straight wall section and at the narrowest point of the rounded wall section is the same. Such a channel does not create a continuous connection between two vertical flow channels. However, it can be used to guide diffused water vapor to the flow channel. The advantage of this definition of the channel cross-section is that the wall thickness of the casing stone in the area of the horizontal channel is not less than the wall thickness in the area of the straight wall section, so that the strength and fire resistance of the casing stone are not impaired.

Within the scope of the invention, it is assumed that each chimney flue has four flow channels arranged in corner areas. In a single-flue chimney, these corner areas are identical to the corners of the casing. If several inner pipes or additional air shafts are arranged in a casing, flow channels can also be formed in the gaps between two inner pipes or in the corner areas of an adjacent air shaft. Such corner areas

can be used for the arrangement of recesses under certain circumstances. However, it is preferable to arrange the recesses generally in the corner areas of the casing stone, even if the corner area is not bordered by a round chimney flue, but rather by an essentially rectangular air shaft, i.e. apart from the usual roundings. Such an air shaft will then have a rounding in the area of the recess that is a mirror image of the usual roundings, i.e. convex when viewed from the shaft.

With the casing stones according to the invention, large-format chimney elements can be manufactured in the factory by placing several casing stones on top of each other with mortar, inserting reinforcing iron into the recesses and casting it with casting compound, or screwing threaded rods to the ends of the shaped pieces. Such shaped pieces can be as high as a storey or as high as a house, with stability for transport and assembly being ensured by the cast reinforcement or the threaded rods subjected to tensile stress.

Such casing stones can also be used to build particularly stable chimneys on site, which are able to withstand static loads, e.g. from wind attack, over a greater height than normal house chimneys, where only the weight of the building counteracts the wind load. This is not intended for free-standing chimneys, for which the casing stones are not suitable as load-bearing components due to their limited wall thickness, which does not exceed 10 cm even with larger cross-sectional dimensions, but rather for house chimneys that are exposed to wind forces above the roof at a limited height (< 3 m).

The invention is explained in more detail below using schematic drawings of several embodiments.

It shows:

Fig. 1 is a plan view of a casing stone with four different each illustrated in a quadrant for the shape of the recesses.

Fig. 2 a plan view of a quadrant of a mantle stone in an enlarged view.

Fig. 3 a plan view of a quadrant of a casing stone with different wall thicknesses in the area of the flow channel and in the area of the curve.

Fig. 4 shows a partial section of the mantle stone of Fig. 3.

Fig. 5 a top view of a casing stone with a chimney flue and an air shaft with an almost rectangular cross-section.

All the casing stones shown are usually made of lightweight concrete with an open or closed structure with a density of approx. 1.0 to 1.8 g/cm ^3. The height of a molded piece is mostly 33 cm, but higher molded pieces up to floor height can also be made. The molded pieces are used for house chimneys with clearances of 12 cm to 0.8 m. The external dimensions have a length of approx. 30 cm to 2 m. The wall thickness of the molded pieces is 4 cm for small clearances and increases to 10 cm for large clearances.

The casing stone (2) in Fig. 1 shows four different shapes of recesses (6) in four quadrants, as well as four different shapes of flow channels (4), which result as a result of the different shapes of the recesses (6). The recess (6) is shown as a square in the upper left quadrant of Fig. 1, as a combination of a triangle and a semicircle in the upper right quadrant, as a right-angled triangle in the lower left quadrant and as a circle in the lower right quadrant. The recesses are arranged in such a way that they are each symmetrical to the bisector (36) of the adjacent corner of the casing stone (2). The inner wall surface (10) of the recess is opposite a corresponding wall part (8) on the side of the flow channel, which runs parallel to the inner wall (10) of the recess in the two left quadrants and concentrically in the two right quadrants.

The wall thickness from the recess (6) to the flow channel (4) is 505fe of the wall thickness of the casing stone in the adjacent area (12) of the flow channels (4) not penetrated by a recess (6). The flow channels (4) are formed by the wall (8) of the recess, the two walls of the straight wall section (12), the two side boundary surfaces (16), and the open opening to the insulation layer (rounding (38) shown in dashed lines). The minimum wall thickness of the casing stone in the area of the rounded wall section is slightly greater than the wall thickness in the adjacent area (12) of the flow channel (4) not penetrated by a recess.

Fig. 2 shows a quadrant of a casing stone with a circular recess on a larger scale. The ratios of the wall thicknesses of the casing stone in the various areas are shown by a general dimension, with a preferred value for dimension a for chimney clearances of 12 cm to 22 cm being 40 mm. The casing stone shown corresponds in terms of dimensions to a chimney with a clearance of 16 cm and an external dimension of 36 cm.

The wall between the recess (6) and the flow channel (4) is formed by a circular ring cutout (14). The convexly curved wall (8) of the flow channel (4) merges with a small rounding (20) into the wall section (12) with a uniform wall thickness. The transition to the adjacent lateral boundary surface (16) and to the circular boundary surface (18) of the rounded wall section (42) also occurs with a small rounding (20). The lateral boundary surface is essentially (apart from the roundings) aligned perpendicular to the surface of the wall section (12). The length of the lateral boundary surface is in the small casing stone shown

dimensions are relatively short. It can reach a considerable size with larger chimney cross-sections, since the increasing depth of the flow channels means that the width of the channel does not have to increase in the same proportion as the clear width of the chimney.

If the chimney is small, it may happen that the area of the flow channel is not large enough for the same wall thickness in the area of the straight wall section (12) and at the narrowest point of the rounded wall section (42). Increasing the open passage area (40) of the flow channel to the insulation layer beyond one eighth of the circumferential area of the casing stone does not bring about any significant improvement due to the small difference in dimensions between the rounded wall section (42) and the straight wall section (12). In this case, however, the wall thickness in the narrow area of the rounded wall section (42) can be chosen to be slightly larger than the wall thickness in the straight wall section (12), which results in a significantly larger flow channel, as shown in Fig. 3 with otherwise identical dimensions to Fig. 2. The difference in wall thickness in the rounded wall section (42) between Fig. 2 and Fig. 3 is only 5 mm in this example, and the external dimension is therefore only 1 cm larger.

Fig. 3 shows a continuous horizontal connecting channel (24) in dashed lines that connects two flow channels (4) with each other. In the area of the rounded wall section (42), the inner surface (26) is set back so that it is parallel to the adjacent outer wall and the wall thickness corresponds to that of the straight wall section (12).

Fig. 4 shows a section along the axis A-B through a casing stone with the recess for the horizontal channel (24). The horizontal channel is formed by the recess, the inwardly adjacent insulation layer and the surface of the previous casing stone.

Fig. 5 shows a casing brick for a chimney with an additional, almost rectangular air shaft (28), as used for the discharge of heating room air or for the supply of combustion air in air-exhaust systems. In addition to a circular recess (6) in the area of the chimney draft (44), a further recess (32) is arranged in the area of the air shaft (28) (top left corner of Fig. 5). The recess (32) is designed in the same way in terms of arrangement and wall thickness as the recess (6) in the area of the chimney draft (44).

The arrangement of only two recesses has the advantage that no space is lost for the flow channels and air shafts at the other two corners of the casing stone. However, recesses are often provided in all four corner areas, since with four recesses, greater forces can be transmitted by reinforcing iron and the handling of the stones is easier. In the area of the chimney flue (44), flow channels (4) are shown, two of which are arranged in the corner areas of the casing stone (right and left lower corners of Fig. 5). Two further flow channels (4) are arranged in corner areas between the round chimney flue and the adjacent almost rectangular air shaft, with a space between the chimney flue and the air shaft.

_ ₁₀ _

and the air shaft a continuous wall (30) extends. In the upper two flow channels, the lateral boundary surfaces (16) run at an angle of 135° to the adjacent wall, since in this area the cross-section of the flow channels is not reduced by recesses. It can be seen here that the additional space gained by the vertical arrangement of the lateral boundary surface, as shown in the bottom right corner of Fig. 5, largely compensates for the loss of space due to the recess with the same opening width to the insulation layer.

Claims (12)

Note: Werner Münz Neufahrn, 21.8.90 Claims 1. Casing brick for a multi-layered, ventilated house chimney with at least one round inner pipe carrying the flue gas, a cylindrical shell-shaped insulation layer surrounding the inner pipe and a casing brick supporting the latter on the outside with a rectangular outer circumference, in the corner areas of which a flow channel (4) running from bottom to top is formed for a ventilation gas supplied from the outside and discharged to the outside, which is open towards the insulation layer, characterized in that in at least two corner areas of the casing brick (2) there is an additional recess (6) running parallel to the axis of the chimney, preferably closed on the circumference, for receiving reinforcing iron and/or casting compound, the wall (8) of which runs in the direction of the flow channel essentially concentrically or parallel to the corresponding part of the inner wall (10) of the recess (6), the wall thickness in the direction of the flow channel and the smallest dimension in each case to the two adjacent outer surfaces being 40% to 60%, preferably 50% of the minimum wall thickness of the casing stone in the adjacent area (12) of the flow channels not penetrated by a recess. 2. Mantle stone according to claim 1, characterized in that the recess (6) has a circular cross-section, and the wall in the direction of the flow channel is essentially formed by a circular ring cutout (14). 3. Mantle stone according to claim 2 with at least one straight wall piece (12) adjoining the region of the recess , characterized in that the transition from the wall of the recess (8) to the straight wall piece (12) is rounded with a small radius r < 10 mm, preferably with r < 5 mm. 4. Mantle stone according to at least one of claims 1 to 3 with at least one straight wall piece (12) adjoining the region of the recess , characterized in that the wall piece (12) has on the side facing away from the recess a lateral boundary surface (16) for the flow channel, which extends essentially at an angle of 80° to 100° to the straight wall piece (12), preferably perpendicular to it. 5. Casing brick according to claim 4 with at least one rounded wall part (42) adjoining the region of the flow channels (4), the circle centre of which corresponds to the chimney axis, characterized in that the transition from the lateral boundary surface (16) of the flow channel (4) to the rounded wall part (42) is rounded with a small radius r < 10 mm, preferably r < 5 mm. 6. Mantle stone according to claim 5 , characterized in that the circumferential dimension of the open opening (38) of the flow channel formed by the mantle stone relative to the insulation layer is smaller or at most the same size as the adjacent boundary surface (18) of the rounded wall part (42) forming part of a circular arc. 7. Mantle stone according to claim 5 or 6 , characterized in that the minimum wall thickness in the region of the rounded wall part (42) is the same or up to 10 mm, preferably 5 mm, greater than that of the straight wall section (12). 8. Mantle stone according to at least one of claims 5 to 7 , characterized in that in the region of the rounded wall part (42) on at least one end surface of the mantle stone a horizontal flow channel (24) runs, which is formed in that the rounding is interrupted over part of the height of the mantle stone, and the laterally adjacent straight wall (22) of the straight wall piece (12) is continued over the region of the rounded wall part (42). 9. Casing for a multi-layer ventilated chimney with a round inner pipe carrying the flue gas, a cylindrical shell-shaped insulation layer surrounding the inner pipe and a casing with a rectangular outer circumference supporting the latter on the outside and an almost rectangular air shaft (28) arranged next to the chimney, which is separated from the chimney by a wall (30) running through the casing, wherein in the corner areas of the chimney, including the corner areas opposite the air shaft, a flow channel (4) running from bottom to top is formed in the casing for a ventilation gas supplied from outside and discharged to the outside, characterized in that in at least one corner area of the casing oriented towards the chimney and in at least one corner area of the casing oriented towards the air shaft, an additional recess (32) running parallel to the axis of the air shaft, preferably closed on the circumference, is arranged for receiving reinforcing iron and/or casting compound, the wall of which is essentially concentric in the direction of the air shaft (28). or parallel to the corresponding part of the inner wall of the recess (32), the wall thickness being in each case 40% to 60%, preferably 50% of the wall thickness of the casing stone in the adjacent area not penetrated by a recess. 10. Mantle stone according to claim 9 , characterized in that the recesses (6,32) have a circular cross-section, and the wall in the direction of the flow channel or the air shaft is essentially formed by a circular ring cutout (14,34). 11. Factory-made molded piece made of at least two casing stones according to one of claims 1 to 10 , characterized in that the casing stones are placed on top of one another with mortar, that reinforcing iron is introduced into the recesses and that the recesses are filled with casting compound. 12. Factory-made molded piece made of at least two casing stones according to one of claims 1 to 10 , characterized in that the casing stones are placed on top of one another with mortar, threaded rods are introduced into the recesses and are screwed to counter plates on the end sides of the molded pieces.